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 INTEGRATED CIRCUITS
87LPC768 Low power, low price, low pin count (20 pin) microcontroller with 4 kB OTP 8-bit A/D,and Pulse Width Modulator
Preliminary data Supersedes data of 2000 May 02 2001 Aug 06
Philips Semiconductors
Philips Semiconductors
Preliminary data
Low power, low price, low pin count (20 pin) microcontroller with 4 kB OTP 8-bit A/D, Pulse Width Modulator
87LPC768
GENERAL DESCRIPTION . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . FEATURES . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . ORDERING INFORMATION . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . PIN CONFIGURATION, 20-PIN DIP AND SO PACKAGES . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . LOGIC SYMBOL . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . BLOCK DIAGRAM . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . PIN DESCRIPTIONS . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . FUNCTIONAL DESCRIPTION . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Enhanced CPU . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Analog Functions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Analog to Digital Converter . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . A/D Timing . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . The A/D in Power Down and Idle Modes . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Code Examples for the A/D . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Analog Comparators . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . I2C Serial Interface . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Interrupts . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . I/O Ports . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Keyboard Interrupt (KBI) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Oscillator . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Power Monitoring Functions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Power Reduction Modes . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Reset . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Timer/Counters . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . UART . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Watchdog Timer . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Additional Features . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . EPROM Characteristics . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . ABSOLUTE MAXIMUM RATINGS . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . DC ELECTRICAL CHARACTERISTICS . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . COMPARATOR ELECTRICAL CHARACTERISTICS . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . A/D CONVERTER DC ELECTRICAL CHARACTERISTICS . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . AC ELECTRICAL CHARACTERISTICS . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
1 1 2 2 2 3 5 9 9 9 9 10 11 12 13 20 24 26 28 30 32 33 35 36 39 49 51 52 53 54 55 55 57
2001 Aug 06
i
Philips Semiconductors
Preliminary data
Low power, low price, low pin count (20 pin) microcontroller with 4 kB OTP 8-bit A/D, Pulse Width Modulator
87LPC768
* I2C communication port. * Eight keypad interrupt inputs, plus two additional external interrupt
inputs.
* Four interrupt priority levels. * Watchdog timer with separate on-chip oscillator, requiring no
external components. The watchdog timeout time is selectable from 8 values.
* Active low reset. On-chip power-on reset allows operation with no
GENERAL DESCRIPTION
The 87LPC768 is a 20-pin single-chip microcontroller designed for low pin count applications demanding high-integration, low cost solutions over a wide range of performance requirements. A member of the Philips low pin count family, the 87LPC768 offers programmable oscillator configurations for high and low speed crystals or RC operation, wide operating voltage range, programmable port output configurations, selectable Schmitt trigger inputs, LED drive outputs, and a built-in watchdog timer. The 87LPC768 is based on an accelerated 80C51 processor architecture that executes instructions at twice the rate of standard 80C51 devices. external reset components.
* Low voltage reset. One of two preset low voltage levels may be
selected to allow a graceful system shutdown when power fails. May optionally be configured as an interrupt.
* Oscillator Fail Detect. The watchdog timer has a separate fully
on-chip oscillator, allowing it to perform an oscillator fail detect function.
* Configurable on-chip oscillator with frequency range and RC
oscillator options (selected by user programmed EPROM bits). The RC oscillator option allows operation with no external oscillator components.
* Programmable port output configuration options:
FEATURES
quasi-bidirectional, open drain, push-pull, input-only.
* An accelerated 80C51 CPU provides instruction cycle times of
300-600 ns for all instructions except multiply and divide when executing at 20 MHz. Execution at up to 20 MHz when VDD = 4.5 V to 6.0 V, 10 MHz when VDD = 2.7 V to 6.0 V.
* Selectable Schmitt trigger port inputs. * LED drive capability (20 mA) on all port pins. * Controlled slew rate port outputs to reduce EMI. Outputs have
approximately 10 ns minimum ramp times.
* Four-channel 10-bit Pulse Width Modulator * Four-channel multiplexed 8-bit A/D converter. Conversion time of * 2.7 V to 6.0 V operating range for digital functions. * 4 kbytes EPROM code memory. * 128 byte RAM data memory. * 32-byte customer code EPROM allows serialization of devices,
storage of setup parameters, etc. 9.3S at fosc = 20 MHz.
* 15 I/O pins minimum. Up to 18 I/O pins using on-chip oscillator
and reset options.
* Only power and ground connections are required to operate the
87LPC768 when fully on-chip oscillator and reset options are selected.
* Serial EPROM programming allows simple in-circuit production
coding. Two EPROM security bits prevent reading of sensitive application programs.
* Two 16-bit counter/timers. Each timer may be configured to toggle
a port output upon timer overflow.
* Idle and Power Down reduced power modes. Improved wakeup
from Power Down mode (a low interrupt input starts execution). Typical Power Down current is 1 A.
* Two analog comparators. * Full duplex UART.
* 20-pin DIP and SO packages.
2001 Aug 06
1
Philips Semiconductors
Preliminary data
Low power, low price, low pin count (20 pin) microcontroller with 4 kB OTP 8-bit A/D, Pulse Width Modulator
87LPC768
ORDERING INFORMATION
Part Number P87LPC768BN P87LPC768BD P87LPC768FN P87LPC768FD Temperature Range C and Package 0 to +70, Plastic Dual In-Line Package 0 to +70, Plastic Small Outline Package -45 to +85, Plastic Dual In-Line Package -45 to +85, Plastic Small Outline Package Frequency 20 MHz (5 V), 10 MHz (3 V) 20 MHz (5 V), 10 MHz (3 V) 20 MHz (5 V), 10 MHz (3 V) 20 MHz (5 V), 10 MHz (3 V) Drawing Number SOT146-1 SOT163-1 SOT146-1 SOT163-1
PIN CONFIGURATION, 20-PIN DIP AND SO PACKAGES
PWM3/CMP2/P0.0 PWM2/P1.7 PWM1/P1.6 RST/P1.5 VSS X1/P2.1 X2/CLKOUT/P2.0 INT1/P1.4 SDA/INT0/P1.3 1 2 3 4 5 6 7 8 9 20 P0.1/CIN2B/PWM0 19 P0.2/CIN2A/BRAKE 18 P0.3/CIN1B/AD0 17 P0.4/CIN1A/AD1 16 P0.5/CMPREF/AD2 15 VDD 14 P0.6/CMP1/AD3 13 P0.7/T1 12 P1.0/TxD 11 P1.1/RxD
SCL/T0/P1.2 10
SU01361
LOGIC SYMBOL
VDD VSS
PWM3 PWM0 BRAKE AD0 AD1 AD2 AD3
CMP2 CIN2B CIN2A CIN1B CIN1A CMPREF CMP1 T1 CLKOUT/X2 X1 PORT 2 PORT 0 PORT 1
TxD RxD T0 INT0 INT1 RST PWM1 PWM2
SCL SDA
SU01362
2001 Aug 06
2
Philips Semiconductors
Preliminary data
Low power, low price, low pin count (20 pin) microcontroller with 4 kB OTP 8-bit A/D, Pulse Width Modulator
87LPC768
BLOCK DIAGRAM
ACCELERATED 80C51 CPU
INTERNAL BUS UART 4K BYTE CODE EPROM
I2C 128 BYTE DATA RAM
TIMER 0, 1 PORT 2 CONFIGURABLE I/OS
PORT 1 CONFIGURABLE I/OS
WATCHDOG TIMER AND OSCILLATOR
PORT 0 CONFIGURABLE I/OS
ANALOG COMPARATORS
KEYPAD INTERRUPT
A/D CONVERTER
PULSE WIDTH MODULATOR
CRYSTAL OR RESONATOR
CONFIGURABLE OSCILLATOR
ON-CHIP R/C OSCILLATOR
POWER MONITOR (POWER-ON RESET, BROWNOUT RESET)
SU01363
2001 Aug 06
3
Philips Semiconductors
Preliminary data
Low power, low price, low pin count (20 pin) microcontroller with 4 kB OTP 8-bit A/D, Pulse Width Modulator
87LPC768
FFFFh UNUSED SPACE UNUSED CODE MEMORY SPACE FCFFh 32-BYTE CUSTOMER CODE SPACE (ACCESSIBLE VIA MOVC) FCE0h SPECIAL FUNCTION REGISTERS (ONLY DIRECTLY ADDRESSABLE) 1000h 0FFFh 4 K BYTES ON-CHIP CODE MEMORY UNUSED SPACE 128 BYTES ON-CHIP DATA MEMORY (DIRECTLY AND INDIRECTLY ADDRESSABLE) 16-BIT ADDRESSABLE BYTES INTERRUPT VECTORS 0000h ON-CHIP CODE MEMORY SPACE * ON-CHIP DATA MEMORY SPACE 00h EXTERNAL DATA MEMORY SPACE* 80h 7Fh FFh
FFFFh
FD01h CONFIGURATION BYTES UCFG1, UCFG2 (ACCESSIBLE VIA MOVX) FD00h
UNUSED CODE MEMORY SPACE
0000h
The 87LPC768 does not support access to external data memory. However, the User Configuration Bytes are accessed via the MOVX instruction as if they were in external data memory. Figure 1. 87LPC768 Program and Data Memory Map
SU01386
2001 Aug 06
4
Philips Semiconductors
Preliminary data
Low power, low price, low pin count (20 pin) microcontroller with 4 kB OTP 8-bit A/D, Pulse Width Modulator
87LPC768
PIN DESCRIPTIONS
MNEMONIC P0.0-P0.7 PIN NO. 1, 13, 14, 16-20 TYPE I/O NAME AND FUNCTION Port 0: Port 0 is an 8-bit I/O port with a user-configurable output type. Port 0 latches are configured in the quasi-bidirectional mode and have either ones or zeros written to them during reset, as determined by the PRHI bit in the UCFG1 configuration byte. The operation of port 0 pins as inputs and outputs depends upon the port configuration selected. Each port pin is configured independently. Refer to the section on I/O port configuration and the DC Electrical Characteristics for details. The Keyboard Interrupt feature operates with port 0 pins. Port 0 also provides various special functions as described below. P0.0 CMP2 PWM3 P0.1 CIN2B PWM0 P0.2 CIN2A BRAKE P0.3 CIN1B AD0 P0.4 CIN1A AD1 P0.5 CMPREF AD2 P0.6 CMP1 AD3 P0.7 T1 Comparator 2 output. Pulse Width Modulator 3 output. Comparator 2 positive input B. Pulse Width Modulator 0 output. Comparator 2 positive input A. PWM brake input. Comparator 1 positive input B. A/D channel 0 input. Comparator 1 positive input A. A/D channel 1 input. Comparator reference (negative) input. A/D channel 2 input. Comparator 1 output. A/D channel 3 input. Timer/counter 1 external count input or overflow output.
1
O O
20
I O
19
I I
18
I I
17
I I
16
I I
14
O I
13 P1.0-P1.7 2-4, 8-12
I/O I/O
Port 1: Port 1 is an 8-bit I/O port with a user-configurable output type, except for three pins as noted below. Port 1 latches are configured in the quasi-bidirectional mode and have either ones or zeros written to them during reset, as determined by the PRHI bit in the UCFG1 configuration byte. The operation of the configurable port 1 pins as inputs and outputs depends upon the port configuration selected. Each of the configurable port pins are programmed independently. Refer to the section on I/O port configuration and the DC Electrical Characteristics for details. Port 1 also provides various special functions as described below. P1.0 P1.1 P1.2 TxD RxD T0 SCL INT0 SDA INT1 RST Transmitter output for the serial port. Receiver input for the serial port. Timer/counter 0 external count input or overflow output. I2C serial clock input/output. When configured as an output, P1.2 is open drain, in order to conform to I2C specifications. External interrupt 0 input. I2C serial data input/output. When configured as an output, P1.3 is open drain, in order to conform to I2C specifications. External interrupt 1 input. External Reset input (if selected via EPROM configuration). A low on this pin resets the microcontroller, causing I/O ports and peripherals to take on their default states, and the processor begins execution at address 0. When used as a port pin, P1.5 is a Schmitt trigger input only. Pulse Width Modulator 1 output Pulse Width Modulator 2 output
12 11 10
O I I/O I/O I I/O I I
9
P1.3
8 4
P1.4 P1.5
3 2
O O
P1.6 P1.7
PWM1 PWM2
2001 Aug 06
5
Philips Semiconductors
Preliminary data
Low power, low price, low pin count (20 pin) microcontroller with 4 kB OTP 8-bit A/D, Pulse Width Modulator
87LPC768
MNEMONIC P2.0-P2.1
PIN NO. 6, 7
TYPE I/O
NAME AND FUNCTION Port 2: Port 2 is a 2-bit I/O port with a user-configurable output type. Port 2 latches are configured in the quasi-bidirectional mode and have either ones or zeros written to them during reset, as determined by the PRHI bit in the UCFG1 configuration byte. The operation of port 2 pins as inputs and outputs depends upon the port configuration selected. Each port pin is configured independently. Refer to the section on I/O port configuration and the DC Electrical Characteristics for details. Port 2 also provides various special functions as described below. P2.0 X2 CLKOUT Output from the oscillator amplifier (when a crystal oscillator option is selected via the EPROM configuration). CPU clock divided by 6 clock output when enabled via SFR bit and in conjunction with internal RC oscillator or external clock input. Input to the oscillator circuit and internal clock generator circuits (when selected via the EPROM configuration).
7
O
6 VSS VDD 5 15
I I I
P2.1
X1
Ground: 0V reference. Power Supply: This is the power supply voltage for normal operation as well as Idle and Power Down modes.
2001 Aug 06
6
Philips Semiconductors
Preliminary data
Low power, low price, low pin count (20 pin) microcontroller with 4 kB OTP 8-bit A/D, Pulse Width Modulator
87LPC768
Table 1. Special Function Registers
Name Description SFR Address E0h C7 ADCON#* A/D Control AUXR1# B* CMP1# CMP2# CNSW0 CNSW1 CPSW0 CPSW1 CPSW2 CPSW3 CPSW4 DAC0# DIVM# DPTR: DPH DPL I2CFG#* Auxiliary Function Register B register Comparator 1 control register Comparator 2 control register PWM Counter Shadow Register 0 PWM Counter Shadow Register 1 PWM Compare Shadow Register 0 PWM Compare Shadow Register 1 PWM Compare Shadow Register 2 PWM Compare Shadow Register 3 PWM Compare Shadow Register 4 A/D Result CPU clock divide-by-M control Data pointer (2 bytes) Data pointer high byte Data pointer low byte I2C configuration register 83h 82h CF C8h/RD C8h/WR I2CON#* I2DAT# I2C control register I2C data register D8h/RD D8h/WR D9h/RD D9h/WR IEN0* IEN1#* IP0* IP0H# IP1* IP1H# Interrupt enable 0 Interrupt enable 1 Interrupt priority 0 Interrupt priority 0 high byte Interrupt priority 1 Interrupt priority 1 high byte A8h E8h B8h B7h F8h F7h
SLAVEN SLAVEN
Bit Functions and Addresses MSB E7 E6 C6 - BOD F6 E5 C5 - BOI F5 E4 C4 ADCI LPEP F4 E3 C3 ADCS SRST F3 E2 C2 RCCLK 0 F2 E1 C1 AADR1 - F1 LSB E0
Reset Value 00h
ACC*
Accumulator
C0 AADR0 DPS F0 00h 00h 02h1
C0h A2h F0h ACh ADh D1h D2h D3h D4h D5h D6h D7h C5h 95h
ENADC KBF F7
- - CNSW7 - CPSW07 CPSW17 CPSW27 CPSW37 CPSW39
- - CNSW6 - CPSW06 CPSW16 CPSW26 CPSW36 CPSW38
CE1 CE2 CNSW5 - CPSW05 CPSW15 CPSW25 CPSW35 CPSW29
CP1 CP2 CNSW4 - CPSW04 CPSW14 CPSW24 CPSW34 CPSW28
CN1 CN2 CNSW3 - CPSW03 CPSW13 CPSW23 CPSW33 CPSW19
OE1 OE2 CNSW2 - CPSW02 CPSW12 CPSW22 CPSW32 CPSW18
CO1 CO2 CNSW1 CNSW9 CPSW01 CPSW11 CPSW21 CPSW31 CPSW09
CMF1 CMF2 CNSW0 CNSW8 CPSW00 CPSW10 CPSW20 CPSW30 CPSW08
00h1 00h1 FFh FFh 00h 00h 00h 00h 00h 00h 00h
00h 00h CE
MASTRQ MASTRQ
CD 0 CLRTI DD DRDY CDR 0 x AD EBO ED EC1 BD PBO PBOH FD PC1 PC1H
CC TIRUN TIRUN DC ARL CARL 0 x AC ES EC EAD BC PS PSH FC PAD PADH
CB - - DB STR CSTR 0 x AB ET1 EB - BB PT1 PT1H FB - -
CA - - DA STP CSTP 0 x AA EX1 EA EC2 BA PX1 PX1H FA PC2 PC2H
C9 CT1 CT1 D9
MASTER
C8 CT0 CT0 D8 - XSTP 0 x A8 EX0 E8 EI2 B8 PX0 PX0H F8 PI2 PI2H 00h1 00h1 00h1 00h1 00h1 00h 80h 80h1 00h1
DF RDAT CXA RDAT XDAT AF EA EF ETI BF - - FF PTI PTIH
DE ATN IDLE 0 x AE EWD EE - BE PWD PWDH FE - -
XSTR 0 x A9 ET0 E9 EKB B9 PT0 PT0H F9 PKB PKBH
2001 Aug 06
7
Philips Semiconductors
Preliminary data
Low power, low price, low pin count (20 pin) microcontroller with 4 kB OTP 8-bit A/D, Pulse Width Modulator
87LPC768
Name KBI# P0* P1* P2* P0M1# P0M2# P1M1# P1M2# P2M1# P2M2# PCON PSW* PT0AD#
Description Keyboard Interrupt Port 0 Port 1 Port 2 Port 0 output mode 1 Port 0 output mode 2 Port 1 output mode 1 Port 1 output mode 2 Port 2 output mode 1 Port 2 output mode 2 Power control register Program status word Port 0 digital input disable
SFR Address 86h
Bit Functions and Addresses MSB 87 86 CMP1 96 (P1.6) A6 -
(P0M1.6) (P0M2.6) (P1M1.6) (P1M2.6)
LSB 85
CMPREF
Reset Value 00h
84 CIN1A 94 INT1 A4 -
(P0M1.4) (P0M2.4) (P1M1.4) (P1M2.4)
83 CIN1B 93 INT0 A3 -
(P0M1.3) (P0M2.3)
82 CIN2A 92 T0 A2 -
(P0M1.2) (P0M2.2)
81 CIN2B 91 RxD A1 X1
(P0M1.1) (P0M2.1) (P1M1.1) (P1M2.1) (P2M1.1) (P2M2.1)
80 CMP2 90 TxD A0 X2
(P0M1.0) (P0M2.0) (P1M1.0) (P1M2.0) (P2M1.0) (P2M2.0)
80h 90h A0h 84h 85h 91h 92h A4h A5h 87h D0h F6h
T1 97 (P1.7) A7 -
(P0M1.7) (P0M2.7) (P1M1.7) (P1M2.7)
Note 2 Note 2 Note 2 00h 00H 00h1 00h1 00h 00h1 Note 3 00h 00h
95 RST A5 -
(P0M1.5) (P0M2.5)
- - P0S - BOF D5 F0
- - T1OE - GF1 D3 RS0
- - T0OE - GF0 D2 OV
P2S - SMOD1 D7 CY
P1S - SMOD0 D6 AC
ENCLK - POF D4 RS1
PD D1 F1
IDL D0 P
9F PWMCON0 PWMCON1 SCON* SBUF SADDR# SADEN# SP PWM Control Register 0 PWM Control Register 1 Serial port control Serial port data buffer register Serial port address register Serial port address enable Stack pointer DAh DBh 98h 99h A9h B9h 81h 8F TCON* TH0 TH1 TL0 TL1 TMOD WDCON# WDRST# Timer 0 and 1 control Timer 0 high byte Timer 1 high byte Timer 0 low byte Timer 1 low byte Timer 0 and 1 mode Watchdog control register Watchdog reset register 88h 8Ch 8Dh 8Ah 8Bh 89h A7h A6h GATE - TF1 RUN BKCH SM0
9E XFER BKPS SM1
9D PWM3I BPEN SM2
9C PWM2I BKEN REN -
9B PWM3B TB8
9A PWM1I PWM2B RB8
99 PWM0I PWM1B TI -
98 00h 00h 00h xxh 00h 00h 07h RI PWM0B
8E TR1
8D TF0
8C TR0
8B IE1
8A IT1
89 IE0
88 IT0 00h 00h 00h 00h 00h
C/T -
M1
WDOVF
M0
WDRUN
GATE
WDCLK
C/T WDS2
M1 WDS1
M0 WDS0
00h Note 4 xxh
NOTES: * SFRs are bit addressable. # SFRs are modified from or added to the 80C51 SFRs. 1. Unimplemented bits in SFRs are X (unknown) at all times. Ones should not be written to these bits since they may be used for other purposes in future derivatives. The reset value shown in the table for these bits is 0. 2. I/O port values at reset are determined by the PRHI bit in the UCFG1 configuration byte. 3. The PCON reset value is x x BOF POF-0 0 0 0b. The BOF and POF flags are not affected by reset. The POF flag is set by hardware upon power up. The BOF flag is set by the occurrence of a brownout reset/interrupt and upon power up. 4. The WDCON reset value is xx11 0000b for a Watchdog reset, xx01 0000b for all other reset causes if the watchdog is enabled, and xx00 0000b for all other reset causes if the watchdog is disabled.
2001 Aug 06
8
Philips Semiconductors
Preliminary data
Low power, low price, low pin count (20 pin) microcontroller with 4 kB OTP 8-bit A/D, Pulse Width Modulator
87LPC768
FUNCTIONAL DESCRIPTION
Details of 87LPC768 functions will be described in the following sections.
device has a very limited number of pins, the A/D power supply and references are shared with the processor power pins, VDD and VSS. The A/D converter operates down to a VDD supply of 3.0V. The A/D converter circuitry consists of a 4-input analog multiplexer and an 8-bit successive approximation ADC. The A/D employs a ratiometric potentiometer which guarantees DAC monotonicity. The A/D converter is controlled by the special function register ADCON. Details of ADCON are shown in Figure 2. The A/D must be enabled by setting the ENADC bit at least 10 microseconds before a conversion is started, to allow time for the A/D to stabilize. Prior to the beginning of an A/D conversion, one analog input pin must be selected for conversion via the AADR1 and AADR0 bits. These bits cannot be changed while the A/D is performing a conversion. An A/D conversion is started by setting the ADCS bit, which remains set while the conversion is in progress. When the conversion is complete, the ADCS bit is cleared and the ADCI bit is set. When ADCI is set, it will generate an interrupt if the interrupt system is enabled, the A/D interrupt is enabled (via the EAD bit in the IE1 register), and the A/D interrupt is the highest priority pending interrupt. When a conversion is complete, the result is contained in the register DAC0. This value will not change until another conversion is started. Before another A/D conversion may be started, the ADCI bit must be cleared by software. The A/D channel selection may be changed by the same instruction that sets ADCS to start a new conversion, but not by the same instruction that clears ADCI. The connections of the A/D converter are shown in Figure 3. The ideal A/D result may be calculated as follows:
256 Result + (V IN-V SS) x (round result to the nearest integer) V DD-V SS
Enhanced CPU
The 87LPC768 uses an enhanced 80C51 CPU which runs at twice the speed of standard 80C51 devices. This means that the performance of the 87LPC768 running at 5 MHz is exactly the same as that of a standard 80C51 running at 10 MHz. A machine cycle consists of 6 oscillator cycles, and most instructions execute in 6 or 12 clocks. A user configurable option allows restoring standard 80C51 execution timing. In that case, a machine cycle becomes 12 oscillator cycles. In the following sections, the term "CPU clock" is used to refer to the clock that controls internal instruction execution. This may sometimes be different from the externally applied clock, as in the case where the part is configured for standard 80C51 timing by means of the CLKR configuration bit or in the case where the clock is divided down via the setting of the DIVM register. These features are described in the Oscillator section.
Analog Functions
The 87LPC768 incorporates analog peripheral functions: an Analog to Digital Converter and two Analog Comparators. In order to give the best analog function performance and to minimize power consumption, pins that are being used for analog functions must have the digital outputs and inputs disabled. Digital outputs are disabled by putting the port output into the Input Only (high impedance) mode as described in the I/O Ports section. Digital inputs on port 0 may be disabled through the use of the PT0AD register. Each bit in this register corresponds to one pin of Port 0. Setting the corresponding bit in PT0AD disables that pin's digital input. Port bits that have their digital inputs disabled will be read as 0 by any instruction that accesses the port.
Analog to Digital Converter
The 87LPC768 incorporates a four channel, 8-bit A/D converter. The A/D inputs are alternate functions on four port 0 pins. Because the
2001 Aug 06
9
Philips Semiconductors
Preliminary data
Low power, low price, low pin count (20 pin) microcontroller with 4 kB OTP 8-bit A/D, Pulse Width Modulator
87LPC768
ADCON
Address: C0h
7 ENADC
6 -
5 -
4 ADCI
3 ADCS
2 RCCLK
1 AADR1
0 AADR0
Bit addressable Reset Value: 00h BIT ADCON.7 SYMBOL ENADC
FUNCTION When ENADC = 1, the A/D is enabled and conversions may take place. Must be set 10 microseconds before a conversion is started. ENADC cannot be cleared while ADCS or ADCI are 1. Reserved for future use. Should not be set to 1 by user programs. Reserved for future use. Should not be set to 1 by user programs. A/D conversion complete/interrupt flag. This flag is set when an A/D conversion is completed. This bit will cause a hardware interrupt if enabled and of sufficient priority. Must be cleared by software. A/D start. Setting this bit by software starts the conversion of the selected A/D input. ADCS remains set while the A/D conversion is in progress and is cleared automatically upon completion. While ADCS or ADCI are one, new start commands are ignored. A/D Status A/D not busy, a conversion can be started. A/D busy, the start of a new conversion is blocked. An A/D conversion is complete. ADCI must be cleared prior to starting a new conversion. An A/D conversion is complete. ADCI must be cleared prior to starting a new conversion. This state exists for one machine cycle as an A/D conversion is completed. When RCCLK = 0, the CPU clock is used as the A/D clock. When RCCLK = 1, the internal RC oscillator is used as the A/D clock. This bit is writable while ADCS and ADCI are 0. Along with AADR0, selects the A/D channel to be converted. These bits can only be written while ADCS and ADCI are 0. A/D Input Selected AD0 (P0.3). AD1 (P0.4). AD2 (P0.5). AD3 (P0.6).
SU01354
ADCON.6 ADCON.5 ADCON.4
ADCI
ADCON.3
ADCS
ADCI, ADCS 00 01 10 11 ADCON.2 ADCON.1, 0 RCCLK AADR1,0 AADR1, AADR0 00 01 10 11
Figure 2. A/D Control Register (ADCON)
A/D Timing
The A/D may be clocked in one of two ways. The default is to use the CPU clock as the A/D clock source. When used in this manner, the A/D completes a conversion in 31 machine cycles. The A/D may be operated up to the maximum CPU clock rate of 20 MHz, giving a conversion time of 9.3 s. The formula for calculating A/D conversion time when the CPU clock runs the A/D is: 186 s / CPU clock rate (in MHZ). To obtain accurate A/D conversion results, the CPU clock must be at least 1 MHz. The A/D may also be clocked by the on-chip RC oscillator, even if the RC oscillator is not used as the CPU clock. This is accomplished by setting the RCCLK bit in ADCON. This arrangement has several advantages. First, the A/D conversion time is faster at lower CPU clock rates. Also, the CPU may be run at speeds below 1 MHz without affecting A/D accuracy. Finally, the Power Down mode may be used to completely shut down the CPU and its oscillator, along
with other peripheral functions, in order to obtain the best possible A/D accuracy. This should not be used if the MCU uses an external clock source greater than 4 MHz. When the A/D is operated from the RCCLK while the CPU is running from another clock source, 3 or 4 machine cycles are used to synchronize A/D operation. The time can range from a minimum of 3 machine cycles (at the CPU clock rate) + 108 RC clocks to a maximum of 4 machine cycles (at the CPU clock rate) + 112 RC clocks. Example A/D conversion times at various CPU clock rates are shown in Table 2. In Table 2, maximum times for RCCLK = 1 use an RC clock frequency of 4.5 MHz (6 MHz - 25%). Minimum times for RCCLK = 1 use an RC clock frequency of 7.5 MHz (6 MHz + 25%). Nominal time assume an ideal RC clock frequency of 6 MHz and an average of 3.5 machine cycles at the CPU clock rate.
2001 Aug 06
10
Philips Semiconductors
Preliminary data
Low power, low price, low pin count (20 pin) microcontroller with 4 kB OTP 8-bit A/D, Pulse Width Modulator
87LPC768
Table 2. Example A/D Conversion Times
CPU Clock Rate 32 kHz 1 MHz 4 MHz 11.0592 MHz 12 MHz 16 MHz 20 MHz RCCLK = 0 NA 186 s 46.5 s 16.8 s 15.5 s 11.6 s 9.3 s minimum 563.4 s 32.4 s 18.9 s 16 s RCCLK = 1 nominal 659 s 39.3 s 23.6 s 20.2 s maximum 757 s 48.9 s 30.1 s 27.1 s
Note: Do not clock ADC from the RC oscillator when MCU clock is greater than 4 MHz.
AD0 (P0.3) AD1 (P0.4) AD2 (P0.5) AD3 (P0.6)
VREF+ = VDD 00 01 10 11 AADR1 AADR0 ADCON
DAC0
A/D Converter
VREF- = VSS
(A/D result)
SU01356
Figure 3. A/D Converter Connections
The A/D in Power Down and Idle Modes
While using the CPU clock as the A/D clock source, the Idle mode may be used to conserve power and/or to minimize system noise during the conversion. CPU operation will resume and Idle mode terminate automatically when a conversion is complete if the A/D interrupt is active. In Idle mode, noise from the CPU itself is eliminated, but noise from the oscillator and any other on-chip peripherals that are running will remain. The CPU may be put into Power Down mode when the A/D is clocked by the on-chip RC oscillator (RCCLK=1). This mode gives the best possible A/D accuracy by eliminating most on-chip noise sources. If the Power Down mode is entered while the A/D is running from the CPU clock (RCCLK=0), the A/D will abort operation and will not wake up the CPU. The contents of DAC0 will be invalid when operation does resume.
When an A/D conversion is started, Power Down or Idle mode must be activated within two machine cycles in order to have the most accurate A/D result. These two machine cycles are counted at the CPU clock rate. When using the A/D with either Power Down or Idle mode, care must be taken to insure that the CPU is not restarted by another interrupt until the A/D conversion is complete. The possible causes of wakeup are different in Power Down and Idle modes. A/D accuracy is also affected by noise generated elsewhere in the application, power supply noise, and power supply regulation. Since the 87LPC768 power pins are also used as the A/D reference and supply, the power supply has a very direct affect on the accuracy of A/D readings. Using the A/D without Power Down mode while the clock is divided through the use of CLKR or DIVM has an adverse effect on A/D accuracy.
2001 Aug 06
11
Philips Semiconductors
Preliminary data
Low power, low price, low pin count (20 pin) microcontroller with 4 kB OTP 8-bit A/D, Pulse Width Modulator
87LPC768
Code Examples for the A/D
The first piece of sample code shows an example of port configuration for use with the A/D. This example sets up the pins so that all four A/D channels may be used. Port configuration for analog functions is described in the section Analog Functions. ; Set up port pins for A/D conversion, without affecting other pins. mov PT0AD,#78h ; Disable digital inputs on A/D input pins. anl P0M2,#87h ; Disable digital outputs on A/D input pins. orl P0M1,#78h ; Disable digital outputs on A/D input pins. Following is an example of using the A/D with interrupts. The routine ADStart begins an A/D conversion using the A/D channel number supplied in the accumulator. The channel number is not checked for validity. The A/D must previously have been enabled with sufficient time to allow for stabilization. The interrupt handler routine reads the conversion value and returns it in memory address ADResult. The interrupt should be enabled prior to starting the conversion. ; Start A/D conversion. ADStart: orl ADCON,A setb ADCS ; orl PCON,#01h ; orl PCON,#02h ret ; A/D interrupt handler. ADInt: push ACC mov A,DAC0 mov ADResult,A clr ADCI anl ADCON,#0fch pop ACC reti
; ; ; ;
Add in the new channel number. Start an A/D conversion. The CPU could be put into Idle mode here. The CPU could be put into Power Down mode here if RCCLK = 1.
; ; ; ; ; ;
Save accumulator. Get A/D result, and save it in memory. Clear the A/D completion flag. Clear the A/D channel number. Restore accumulator.
Following is an example of using the A/D with polling. An A/D conversion is started using the channel number supplied in the accumulator. The channel number is not checked for validity. The A/D must previously have been enabled with sufficient time to allow for stabilization. The conversion result is returned in the accumulator. ADRead: orl setb ADChk: jnb mov clr anl ret
ADCON,A ADCS ADCI,ADChk A,DAC0 ADCI ADCON,#0fch
; Add in the new channel number. ; Start A/D conversion. ; ; ; ; Wait for ADCI to be set. Get A/D result. Clear the A/D completion flag. Clear the A/D channel number.
2001 Aug 06
12
Philips Semiconductors
Preliminary data
Low power, low price, low pin count (20 pin) microcontroller with 4 kB OTP 8-bit A/D, Pulse Width Modulator
87LPC768
Analog Comparators
Two analog comparators are provided on the 87LPC768. Input and output options allow use of the comparators in a number of different configurations. Comparator operation is such that the output is a logical one (which may be read in a register and/or routed to a pin) when the positive input (one of two selectable pins) is greater than the negative input (selectable from a pin or an internal reference voltage). Otherwise the output is a zero. Each comparator may be configured to cause an interrupt when the output value changes. Comparator Configuration Each comparator has a control register, CMP1 for comparator 1 and CMP2 for comparator 2. The control registers are identical and are shown in Figure 4.
The overall connections to both comparators are shown in Figure 5. There are eight possible configurations for each comparator, as determined by the control bits in the corresponding CMPn register: CPn, CNn, and OEn. These configurations are shown in Figure 6. The comparators function down to a VDD of 3.0V. When each comparator is first enabled, the comparator output and interrupt flag are not guaranteed to be stable for 10 microseconds. The corresponding comparator interrupt should not be enabled during that time, and the comparator interrupt flag must be cleared before the interrupt is enabled in order to prevent an immediate interrupt service.
CMPn
Address: ACh for CMP1, ADh for CMP2 Not Bit Addressable 7 -- 6 -- 5 CEn 4 CPn 3 CNn 2 OEn 1 COn 0 CMFn
Reset Value: 00h
BIT CMPn.7, 6 CMPn.5 CMPn.4 CMPn.3
SYMBOL -- CEn CPn CNn
FUNCTION Reserved for future use. Should not be set to 1 by user programs. Comparator enable. When set by software, the corresponding comparator function is enabled. Comparator output is stable 10 microseconds after CEn is first set. Comparator positive input select. When 0, CINnA is selected as the positive comparator input. When 1, CINnB is selected as the positive comparator input. Comparator negative input select. When 0, the comparator reference pin CMPREF is selected as the negative comparator input. When 1, the internal comparator reference Vref is selected as the negative comparator input. Output enable. When 1, the comparator output is connected to the CMPn pin if the comparator is enabled (CEn = 1). This output is asynchronous to the CPU clock. Comparator output, synchronized to the CPU clock to allow reading by software. Cleared when the comparator is disabled (CEn = 0). Comparator interrupt flag. This bit is set by hardware whenever the comparator output COn changes state. This bit will cause a hardware interrupt if enabled and of sufficient priority. Cleared by software and when the comparator is disabled (CEn = 0).
SU01152
CMPn.2 CMPn.1 CMPn.0
OEn COn CMFn
Figure 4. Comparator Control Registers (CMP1 and CMP2)
2001 Aug 06
13
Philips Semiconductors
Preliminary data
Low power, low price, low pin count (20 pin) microcontroller with 4 kB OTP 8-bit A/D, Pulse Width Modulator
87LPC768
CP1 (P0.4) CIN1A (P0.3) CIN1B (P0.5) CMPREF Vref CN1
COMPARATOR 1
+
CO1 CMP1 (P0.6)
-
OE1
CHANGE DETECT CMF1 INTERRUPT
CP2 (P0.2) CIN2A (P0.1) CIN2B
COMPARATOR 2
+
CO2 CMP2 (P0.0)
-
CN2
OE2
CHANGE DETECT CMF2 INTERRUPT
SU01153
Figure 5. Comparator Input and Output Connections
CPn, CNn, OEn = 0 0 0
CPn, CNn, OEn = 0 0 1
CINnA CMPREF
+
COn
CINnA CMPREF
+ -
COn
-
CMPn
CPn, CNn, OEn = 0 1 0
CPn, CNn, OEn = 0 1 1
CINnA Vref (1.23V)
+
COn
CINnA Vref (1.23V)
+ -
COn
CMPn
-
CPn, CNn, OEn = 1 0 0
CPn, CNn, OEn = 1 0 1
CINnB CMPREF
+
COn
CINnB CMPREF
+ -
COn
CMPn
-
CPn, CNn, OEn = 1 1 0
CPn, CNn, OEn = 1 1 1
CINnB Vref (1.23V)
+
COn
CINnB Vref (1.23V)
+ -
COn
CMPn
-
SU01154
Figure 6. Comparator Configurations
2001 Aug 06
14
Philips Semiconductors
Preliminary data
Low power, low price, low pin count (20 pin) microcontroller with 4 kB OTP 8-bit A/D, Pulse Width Modulator
87LPC768
Internal Reference Voltage An internal reference voltage generator may supply a default reference when a single comparator input pin is used. The value of the internal reference voltage, referred to as Vref, is 1.28 V 10%. Comparator Interrupt Each comparator has an interrupt flag CMFn contained in its configuration register. This flag is set whenever the comparator output changes state. The flag may be polled by software or may be used to generate an interrupt. The interrupt will be generated when the corresponding enable bit ECn in the IEN1 register is set and the interrupt system is enabled via the EA bit in the IEN0 register. Comparators and Power Reduction Modes Either or both comparators may remain enabled when Power Down or Idle mode is activated. The comparators will continue to function in the power reduction mode. If a comparator interrupt is enabled, a change of the comparator output state will generate an interrupt and
wake up the processor. If the comparator output to a pin is enabled, the pin should be configured in the push-pull mode in order to obtain fast switching times while in power down mode. The reason is that with the oscillator stopped, the temporary strong pull-up that normally occurs during switching on a quasi-bidirectional port pin does not take place. Comparators consume power in Power Down and Idle modes, as well as in the normal operating mode. This fact should be taken into account when system power consumption is an issue. Comparator Configuration Example The code shown in Figure 7 is an example of initializing one comparator. Comparator 1 is configured to use the CIN1A and CMPREF inputs, outputs the comparator result to the CMP1 pin, and generates an interrupt when the comparator output changes. The interrupt routine used for the comparator must clear the interrupt flag (CMF1 in this case) before returning.
CmpInit: mov anl orl mov
PT0AD,#30h P0M2,#0cfh P0M1,#30h CMP1,#24h
call anl setb setb ret
delay10us CMP1,#0feh EC1 EA
; ; ; ; ; ; ; ; ; ; ; ; ; ; ;
Disable digital inputs on pins that are used for analog functions: CIN1A, CMPREF. Disable digital outputs on pins that are used for analog functions: CIN1A, CMPREF. Turn on comparator 1 and set up for: - Positive input on CIN1A. - Negative input from CMPREF pin. - Output to CMP1 pin enabled. The comparator has to start up for at least 10 microseconds before use. Clear comparator 1 interrupt flag. Enable the comparator 1 interrupt. The priority is left at the current value. Enable the interrupt system (if needed). Return to caller.
SU01189
Figure 7. Pulse Width Modulator The 87LPC768 contains four Pulse Width Modulated (PWM) channels which generate pulses of programmable length and interval. The output for PWM0 is on P0.1, PWM1 on P1.6, PWM2 on P1.7 and PWM3 on P0.1. After chip reset the internal output of the each PWM channel is a "1." Note that the state of the pin will not reflect this if UCFG1.5, PRHI, is set to a zero. In this case before the pin will reflect the state of the internal PWM output a "1" must be written to each port bit that serves as a PWM output. A block diagram is shown in Figure 8. The interval between successive outputs is controlled by a 10-bit down counter which uses the internal microcontroller clock as its input. When bit 3 in the UCFG1 register is a "1" the microcontroller clock, and therefore the PWM counter clock, has the same frequency as the clock source defined by the FOSC bits in UCFG1. When bit 3 in the UCFG1 register is a "0" the microcontroller and PWM counter clocks operate at half the frequency of clock source defined by the FOSC bits in UCFG1. When the counter reaches underflow it is reloaded with a user selectable value. This mechanism allows the user to set the PWM frequency at any integer sub-multiple of the microcontroller clock frequency. The repetition frequency of the PWM is given by: fPWM = FC / (CNSW+1) where CNSW is contained in CNSW0 and CNSW1 as described in the following tables.
2001 Aug 06
15
Philips Semiconductors
Preliminary data
Low power, low price, low pin count (20 pin) microcontroller with 4 kB OTP 8-bit A/D, Pulse Width Modulator
87LPC768
CNSW0: Counter Shadow register 0 Addr: 0D1H Reset Value: FFH 7 6 CNSW7 CNSW6 CNSW1: Counter Shadow register 1 Addr: 0D2H Reset Value: FFH 7 6 Unused Unused
5 CNSW5
4 CNSW4
3 CNSW3
2 CNSW2
1 CNSW1
0 CNSW0
5 Unused
4 Unused
3 Unused
2 Unused
1 CNSW9
0 CNSW8
The word "Shadow" in the above refers to the fact that writes are not into the register that controls the counter; rather they are into a holding register. As described below the transfer of data from this
holding register, into the register which contains the actual reload value, is controlled by the user's program.
INTERNAL BUS
10 BIT SHADOW REGISTER
10 BIT SHADOW REGISTER
10 BIT SHADOW REGISTER
10 BIT SHADOW REGISTER
10 BIT SHADOW REGISTER
10 BIT COUNTER REGISTER
10 BIT COMPARE REGISTER
10 BIT COMPARE REGISTER
10 BIT COMPARE REGISTER
10 BIT COMPARE REGISTER
10 BIT COUNTER A B A B A B A B
A>B
A>B
A>B
A>B
RUN
XFER PWM3I PWM2I PWM1I PWM0I
BRAKE
BKCH
BKPS
BPEN
BKEN
PWM3B
PWM2B
PWM1B
PWM0B
2:1 MUX BRAKE CONTROL LOGIC
2:1 MUX
2:1 MUX
2:1 MUX
PWM3
PWM2
PWM1
PWM0
SU01364
Figure 8. PWM Block Diagram
2001 Aug 06
16
Philips Semiconductors
Preliminary data
Low power, low price, low pin count (20 pin) microcontroller with 4 kB OTP 8-bit A/D, Pulse Width Modulator
87LPC768
The width of each PWM output pulse is determined by the value in the appropriate compare shadow registers, CPSW0 through CPSW4, CPSW0-3 for bits 0-7 and CPSW4 for bits 7 and 8. When the counter described above reaches underflow the PWM output is forced high. It remains high until the compare value is reached at which point it goes low until the next underflow. The number of microcontroller clock pulses that the PWMn output is high is given by: tHI = (CNSW - CPSWn+1) A compare value greater than the counter reload value results in the PWM output being permanently high. In addition there are two CPSW0: Compare Shadow register 0 Addr: 0D3H Reset Value: 00H 7 6 CPSW07 CPSW06 CPSW1: Compare Shadow register 1 Addr: 0D4H Reset Value: 00H 7 6 CPSW17 CPSW16 CPSW2: Compare Shadow register 2 Addr: 0D5H Reset Value: 00H 7 6 CPSW27 CPSW26 CPSW3: Compare Shadow register 3 Addr: 0D6H Reset Value: 00H 7 6 CPSW37 CPSW36 CPSW4: Compare Shadow register 4 Addr: 0D7H Reset Value: 00H 7 6 CPSW39 CPSW38
special cases. A compare value of all zeroes, 000, causes the output to remain permanently high. A compare value of all ones, 3FF, results in the PWM output remaining permanently low. Again the compare value is loaded into a shadow register. The transfer from this holding register to the actual compare register is under program control. The register assignments are shown below where the number immediately following "CPSW" identifies the PWM output. Thus CPSW0 controls the width of PWM0, CPSW1 the width of PWM1 etc. In the case of two digits following "CPSW," e.g. CPSW00, the second digit refers to the bit of the compare value. Thus CPSW00 represents the value loaded into bit 0 of the PWM0 compare register
5 CPSW05
4 CPSW04
3 CPSW03
2 CPSW02
1 CPSW01
0 CPSW00
5 CPSW15
4 CPSW14
3 CPSW13
2 CPSW12
1 CPSW11
0 CPSW10
5 CPSW25
4 CPSW24
3 CPSW23
2 CPSW22
1 CPSW21
0 CPSW20
5 CPSW35
4 CPSW34
3 CPSW33
2 CPSW32
1 CPSW31
0 CPSW30
5 CPSW29
4 CPSW28
3 CPSW19
2 CPSW18
1 CPSW09
0 CPSW08
The overall functioning of the PWM module is controlled by the contents of the PWMCON0 register. The operation of most of the control bits is straightforward. For example there is an invert bit for each output which causes results in the output to have the opposite value compared to its non-inverted output. The transfer of the data from the shadow registers to the control registers is controlled by the PWMCON0.6 while PWMCON0.7 allows the PWM to be either in the run or idle state. The user can monitor when underflow causes the transfer to occur by monitoring the Transfer bit, PWCON0.6. When the transfer takes place the PWM logic automatically resets this bit. The fact that the transfer from the shadow to the working registers only occurs when there is an underflow in the counter results in the need for the user's program to observe the following precautions. If
PWMCON1 is written with Transfer set without Run being enabled the transfer will never take place. Thus if a subsequent write sets Run without Transfer the compare and counter values will not be those expected. If Transfer and Run are set, and prior to underflow there is a subsequent load of PWMCON0 which sets Run but not Transfer, the transfer will never take place. Again the compare and counter values that existed prior to the update attempt will be used. As outlined above the Transfer bit can be polled to determine when the transfer occurs. Unless there is a compelling reason to do otherwise, it is recommended that both Run, PWMCON0.7, and Transfer, PWMCON0.7, be set when PWMCON0 is written. When the Run bit, PWMCON0.7, is cleared the PWM outputs take on the state they had just prior to the bit being cleared. In general this state is not known. In order to place the outputs in a known
2001 Aug 06
17
Philips Semiconductors
Preliminary data
Low power, low price, low pin count (20 pin) microcontroller with 4 kB OTP 8-bit A/D, Pulse Width Modulator
87LPC768
state when Run is cleared the Compare registers can be written to either the "always 1" or "always 0" so the output will have the output desired when the counter is halted. After this PWMCON0 should be written with the Transfer and Run bits are enabled. After this is done PWMCON0 to is polled to find that the Transfer has taken place. Once the transfer has occurred the Run bit in PWMCON0 can be cleared. The outputs will retain the state they had just prior to the Run being cleared. If the Brake pin (see discussion below in
section concerning the operation of PWMCON1) is not used to control the brake function, the "Brake when not running" function can be used to cause the outputs to have a given state when the PWM is halted. This approach should be used only in time critical situations when there is not sufficient time to use the approach outlined above since going from the Brake state to run without causing an undefined state on the outputs is not straightforward. A discussion on this topic is included in the section on PWMCON1.
PWMCON0: PWM Control register 0 Addr: 0DAH Reset Value: 00H BIT PWMCON0.7 SYMBOL RUN 7 RUN FUNCTION 0= Counter Halted & Preset Value loaded. If Brake is asserted, PWMx output will be equal to the value of the corresponding PWMxB bit (PWMCON1[3:0]). If Brake is not asserted, PWMx output will be equal to the Value after compare 1= Counter run PWMCON0.6 XFER 0= Counter & Compare shadow registers are not connected to the active registers 1= Shadow register contents transferred to active registers, at the next Counter underflow This bit is auto-cleared by hardware after the data transfer from shadow to active registers PWMCON0.5 PWM3I 0= PWM3 output is non-inverted. Output is a `1' from the start of the cycle until compare; '0' thereafter. 1= PWM3 output is inverted. Output is a `0' from the start of the cycle until compare; '0' thereafter. PWMCON0.4 PWM2I 0= PWM2 output is non-inverted. Output is a `1' from the start of the cycle until compare; '0' thereafter. 1= PWM2 output is inverted. Output is `0' from the start of the cycle until compare; '1' thereafter. PWMCON0.2 PWM1I 0= PWM1 output is non-inverted. Output is a `1' from the start of the cycle until compare; '0' thereafter. 1= PWM1 output is inverted. Output is `0' from the start of the cycle until compare; '1' thereafter. PWMCON0.1 PWM0I 0= PWM0 output is non-inverted. Output is a `1' from the start of the cycle until compare; '0' thereafter. 1= PWM0 output is inverted. Output is `0' from the start of the cycle until compare; '1' thereafter. 6 XFER 5 PWM3I 4 PWM2I 3 - 2 PWM1I 1 PWM0I 0 -
SU01387
The Brake function, which is controlled by the contents of the PWMCON1 register, is somewhat unique. In general when Brake is asserted the four PWM outputs are forced to a user selected state, namely the state selected by PWMCON1 bits 0 to 3. As shown in the description of the operation of the PWMCON1 register if PWMCON1.4 is a "1" brake is asserted under the control PWMCON1.7, BKCH, and PWMCON1.5, BPEN. As shown if both are a "0" Brake is asserted. If PWMCON1.7 is a "1" brake is asserted when the run bit, PWMCON0.7, is a "0." If PWMCON1.6 is a "1" brake is asserted when the Brake Pin, P0.2, has the same polarity as PWMCON1.6. When brake is asserted in response to this pin the RUN bit, PWMCON0.7, is automatically cleared. The combination of both PWMCON1.7 and PWMCON1.5 being a "1" is not allowed. Since the Brake Pin being asserted will automatically clear the Run bit, PWMCON0.7, the user program can poll this bit to determine when the Brake Pin causes a brake to occur. The other method for detecting a brake caused by the Brake Pin would be to tie the Brake Pin to one of the external interrupt pins. This latter approach is
needed if the Brake signal can be of insufficient length to ensure that it can be captured by a polling routine. When, after being asserted, the condition causing the brake is removed, the PWM outputs go to whatever state that had immediately prior to the brake. This means that in order to go from brake being asserted to having the PWM run without going through an indeterminate state care must be taken. If the Brake Pin causes brake to be asserted the following prototype code will allow the PWM to go from brake to run smoothly.
* Rewrite PWMCON1 to change from Brake Pin enabled to S/W
Brake brake pattern
* Write CPSW.(0:4) to always "1", 11 h, or always "0" 00 h, to give * Set PWMCON0 to enable Run and Transfer. * Poll Brake Pin until it is no longer active. When no longer active:
2001 Aug 06
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Philips Semiconductors
Preliminary data
Low power, low price, low pin count (20 pin) microcontroller with 4 kB OTP 8-bit A/D, Pulse Width Modulator
87LPC768
* Poll PWMCON0 to find that Transfer Bit PWMCON0.6 is "0".
When "0":
* Write CNSW.(0:1) and CPSW.(0:4) for desired pulse widths and
counter reload values
Note that if a narrow pulse on the Brake Pin causes brake to be asserted, it may not be possible to go through the above code before the end of the pulse. In this case, in addition to the code shown, an external latch on the Brake Pin may be required to ensure that there is a smooth transition in going from brake to run. The details for PWMCON1 are shown in the following table.
* Set PWMCON0 to Run and Transfer
PWMCON1: PWM Control register 1 Addr: 0DBH Reset Value: 00H BIT PWMCON1.7 PWMCON1.6 SYMBOL BKCH BKPS 7 BKCH FUNCTION See table below 6 BKPS 5 BPEN
4 BKEN
3 PWM3B
2 PWM2B
1 PWM1B
0 PWM0B
0= "Brake" is asserted if P0.2(Brake Pin) is low. 1= "Brake" is asserted if P0.2(Brake Pin) is high.
PWMCON1.5 PWMCON1.4
BPEN BKEN
See table below. 0= "Brake" is never asserted. 1= "Brake" is enabled per table below.
PWMCON1.3
PWM3B
0= PWM3 is low, when Brake is asserted. 1= PWM3 is high, when Brake is asserted.
PWMCON1.2
PWM2B
0= PWM2 is low, when Brake is asserted. 1= PWM2 is high, when Brake is asserted.
PWMCON1.1
PWM1B
0= PWM1 is low, when Brake is asserted. 1= PWM1 is high, when Brake is asserted.
PWMCON1.0
PWM0B
0= PWM0 is low, when Brake is asserted. 1= PWM0 is high, when Brake is asserted.
BPEN 0 0 1 1
BKCH 0 1 0 1
BRAKE CONDITION Always On, (Software Brake) On when PWM not running (Brake Pin has no effect) On when Brake Pin asserted (PWM run has no effect) Not Allowed
SU01388
2001 Aug 06
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Philips Semiconductors
Preliminary data
Low power, low price, low pin count (20 pin) microcontroller with 4 kB OTP 8-bit A/D, Pulse Width Modulator
87LPC768
I2C Serial Interface
The I2C bus uses two wires (SDA and SCL) to transfer information between devices connected to the bus. The main features of the bus are: problems. SCL "stuck low" indicates a faulty master or slave. SCL "stuck high" may mean a faulty device, or that noise induced onto the I2C bus caused all masters to withdraw from I2C arbitration. The first five of these times are 4.7 ms (see I2C specification) and are covered by the low order three bits of timer I. Timer I is clocked by the 87LPC768 CPU clock. Timer I can be pre-loaded with one of four values to optimize timing for different oscillator frequencies. At lower frequencies, software response time is increased and will degrade maximum performance of the I2C bus. See special function register I2CFG description for prescale values (CT0, CT1). The MAXIMUM SCL CHANGE time is important, but its exact span is not critical. The complete 10 bits of timer I are used to count out the maximum time. When I2C operation is enabled, this counter is cleared by transitions on the SCL pin. The timer does not run between I2C frames (i.e., whenever reset or stop occurred more recently than the last start). When this counter is running, it will carry out after 1020 to 1023 machine cycles have elapsed since a change on SCL. A carry out causes a hardware reset of the I2C interface and generates an interrupt if the Timer I interrupt is enabled. In cases where the bus hang-up is due to a lack of software response by this device, the reset releases SCL and allows I2C operation among other devices to continue. Timer I is enabled to run, and will reset the I2C interface upon overflow, if the TIRUN bit in the I2CFG register is set. The Timer I interrupt may be enabled via the ETI bit in IEN1, and its priority set by the PTIH and PTI bits in the Ip1H and IP1 registers respectively. I2C Interrupts If I2C interrupts are enabled (EA and EI2 are both set to 1), an I2C interrupt will occur whenever the ATN flag is set by a start, stop, arbitration loss, or data ready condition (refer to the description of ATN following). In practice, it is not efficient to operate the I2C interface in this fashion because the I2C interrupt service routine would somehow have to distinguish between hundreds of possible conditions. Also, since I2C can operate at a fairly high rate, the software may execute faster if the code simply waits for the I2C interface. Typically, the I2C interrupt should only be used to indicate a start condition at an idle slave device, or a stop condition at an idle master device (if it is waiting to use the I2C bus). This is accomplished by enabling the I2C interrupt only during the aforementioned conditions. Reading I2CON RDAT The data from SDA is captured into "Receive DATa" whenever a rising edge occurs on SCL. RDAT is also available (with seven low-order zeros) in the I2DAT register. The difference between reading it here and there is that reading I2DAT clears DRDY, allowing the I2C to proceed on to another bit. Typically, the first seven bits of a received byte are read from I2DAT, while the 8th is read here. Then I2DAT can be written to send the Acknowledge bit and clear DRDY. ATN "ATteNtion" is 1 when one or more of DRDY, ARL, STR, or STP is 1. Thus, ATN comprises a single bit that can be tested to release the I2C service routine from a "wait loop." "Data ReaDY" (and thus ATN) is set when a rising edge occurs on SCL, except at idle slave. DRDY is cleared by writing CDR = 1, or by writing or reading the I2DAT register. The following low period on SCL is stretched until the program responds by clearing DRDY.
* Bidirectional data transfer between masters and slaves. * Serial addressing of slaves (no added wiring). * Acknowledgment after each transferred byte. * Multimaster bus. * Arbitration between simultaneously transmitting masters without
corruption of serial data on bus. I2C
The subsystem includes hardware to simplify the software required to drive the I2C bus. The hardware is a single bit interface which in addition to including the necessary arbitration and framing error checks, includes clock stretching and a bus timeout timer. The interface is synchronized to software either through polled loops or interrupts. Refer to the application note AN422, entitled "Using the 8XC751 Microcontroller as an I2C Bus Master" for additional discussion of the 8xC76x I2C interface and sample driver routines. The 87LPC768 I2C implementation duplicates that of the 87C751 and 87C752 except for the following details: Timer I interrupt.
* The interrupt vector addresses for both the I2C interrupt and the * The I2C SFR addresses (I2CON, !2CFG, I2DAT). * The location of the I2C interrupt enable bit and the name of the
SFR it is located within (EI2 is Bit 0 in IEN1).
* The location of the Timer I interrupt enable bit and the name of the
SFR it is located within (ETI is Bit 7 in IEN1).
* The I2C and Timer I interrupts have a settable priority.
Timer I is used to both control the timing of the I2C bus and also to detect a "bus locked" condition, by causing an interrupt when nothing happens on the I2C bus for an inordinately long period of time while a transmission is in progress. If this interrupt occurs, the program has the opportunity to attempt to correct the fault and resume I2C operation.
* The MINIMUM HIGH time for SCL when this device is the master. * The MINIMUM LOW time for SCL when this device is a master.
This is not very important for a single-bit hardware interface like this one, because the SCL low time is stretched until the software responds to the I2C flags. The software response time normally meets or exceeds the MIN LO time. In cases where the software responds within MIN HI + MIN LO) time, timer I will ensure that the minimum time is met.
Six time spans are important in I2C operation and are insured by timer I:
* The MINIMUM SCL HIGH TO SDA HIGH time in a stop condition. * The MINIMUM SDA HIGH TO SDA LOW time between I2C stop
and start conditions (4.7ms, see I2C specification).
* The MINIMUM SDA LOW TO SCL LOW time in a start condition. * The MAXIMUM SCL CHANGE time while an I2C frame is in
progress. A frame is in progress between a start condition and the following stop condition. This time span serves to detect a lack of software response on this device as well as external I2C 2001 Aug 06 20
DRDY
Philips Semiconductors
Preliminary data
Low power, low price, low pin count (20 pin) microcontroller with 4 kB OTP 8-bit A/D, Pulse Width Modulator
87LPC768
I2CON
Address: D8h Bit Addressable* 7 READ WRITE RDAT CXA 6 ATN IDLE 5 DRDY CDR 4 ARL CARL 3 STR CSTR 2 STP CSTP 1 MASTER XSTR 0 -- XSTP
Reset Value: 81h
BIT I2CON.7 " I2CON.6 " I2CON.5 " I2CON.4 " I2CON.3 " I2CON.2 " I2CON.1 " I2CON.0 "
SYMBOL RDAT CXA ATN IDLE DRDY CDR ARL CARL STR CSTR STP CSTP MASTER XSTR -- XSTP
FUNCTION Read: the most recently received data bit. Write: clears the transmit active flag. Read: ATN = 1 if any of the flags DRDY, ARL, STP, or STP = 1. Write: in the I2C slave mode, writing a 1 to this bit causes the I2C hardware to ignore the bus until it is needed again. Read: Data Ready flag, set when there is a rising edge on SCL. Write: writing a 1 to this bit clears the DRDY flag. Read: Arbitration Loss flag, set when arbitration is lost while in the transmit mode. Write: writing a 1 to this bit clears the CARL flag. Read: Start flag, set when a start condition is detected at a master or non-idle slave. Write: writing a 1 to this bit clears the STR flag. Read: Stop flag, set when a stop condition is detected at a master or non-idle slave. Write: writing a 1 to this bit clears the STP flag. Read: indicates whether this device is currently as bus master. Write: writing a 1 to this bit causes a repeated start condition to be generated. Read: undefined. Write: writing a 1 to this bit causes a stop condition to be generated.
* Due to the manner in which bit addressing is implemented in the 80C51 family, the I2CON register should never be altered by use of the SETB, CLR, CPL, MOV (bit), or JBC instructions. This is due to the fact that read and write functions of this register are different. Testing of I2CON bits via the JB and JNB instructions is supported.
SU01155
Figure 9. I2C Control Register (I2CON)
I2DAT
Address: D9h Not Bit Addressable 7 READ WRITE RDAT XDAT 6 -- -- 5 -- -- 4 -- -- 3 -- -- 2 -- -- 1 -- -- 0 -- --
Reset Value: xxh
BIT I2DAT.7 " I2DAT.6-0
SYMBOL RDAT XDAT -
FUNCTION Read: the most recently received data bit, captured from SDA at every rising edge of SCL. Reading I2DAT also clears DRDY and the Transmit Active state. Write: sets the data for the next transmitted bit. Writing I2DAT also clears DRDY and sets the Transmit Active state. Unused.
SU01156
Figure 10.
I2 C
Data Register
(I2DAT)
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Philips Semiconductors
Preliminary data
Low power, low price, low pin count (20 pin) microcontroller with 4 kB OTP 8-bit A/D, Pulse Width Modulator
87LPC768
Checking ATN and DRDY When a program detects ATN = 1, it should next check DRDY. If DRDY = 1, then if it receives the last bit, it should capture the data from RDAT (in I2DAT or I2CON). Next, if the next bit is to be sent, it should be written to I2DAT. One way or another, it should clear DRDY and then return to monitoring ATN. Note that if any of ARL, STR, or STP is set, clearing DRDY will not release SCL to high, so that the I2C will not go on to the next bit. If a program detects ATN = 1, and DRDY = 0, it should go on to examine ARL, STR, and STP. ARL "Arbitration Loss" is 1 when transmit Active was set, but this device lost arbitration to another transmitter. Transmit Active is cleared when ARL is 1. There are four separate cases in which ARL is set. 1. If the program sent a 1 or repeated start, but another device sent a 0, or a stop, so that SDA is 0 at the rising edge of SCL. (If the other device sent a stop, the setting of ARL will be followed shortly by STP being set.) 2. If the program sent a 1, but another device sent a repeated start, and it drove SDA low before SCL could be driven low. (This type of ARL is always accompanied by STR = 1.) 3. In master mode, if the program sent a repeated start, but another device sent a 1, and it drove SCL low before this device could drive SDA low. 4. In master mode, if the program sent stop, but it could not be sent because another device sent a 0. STR "STaRt" is set to a 1 when an I2C start condition is detected at a non-idle slave or at a master. (STR is not set when an idle slave becomes active due to a start bit; the slave has nothing useful to do until the rising edge of SCL sets DRDY.) "SToP" is set to 1 when an I2C stop condition is detected at a non-idle slave or at a master. (STP is not set for a stop condition at an idle slave.) "MASTER" is 1 if this device is currently a master on the I2C. MASTER is set when MASTRQ is 1 and the bus is not busy (i.e., if a start bit hasn't been received since reset or a "Timer I" time-out, or if a stop has been received since the last start). MASTER is cleared when ARL is set, or after the software writes MASTRQ = 0 and then XSTP = 1.
bit position in the message, it may then write I2CON with one or more of the following bits, or it may read or write the I2DAT register. CXA Writing a 1 to "Clear Xmit Active" clears the Transmit Active state. (Reading the I2DAT register also does this.)
Regarding Transmit Active Transmit Active is set by writing the I2DAT register, or by writing I2CON with XSTR = 1 or XSTP = 1. The I2C interface will only drive the SDA line low when Transmit Active is set, and the ARL bit will only be set to 1 when Transmit Active is set. Transmit Active is cleared by reading the I2DAT register, or by writing I2CON with CXA = 1. Transmit Active is automatically cleared when ARL is 1. IDLE Writing 1 to "IDLE" causes a slave's I2C hardware to ignore the I2C until the next start condition (but if MASTRQ is 1, then a stop condition will cause this device to become a master). Writing a 1 to "Clear Data Ready" clears DRDY. (Reading or writing the I2DAT register also does this.) Writing a 1 to "Clear Arbitration Loss" clears the ARL bit. Writing a 1 to "Clear STaRt" clears the STR bit. Writing a 1 to "Clear SToP" clears the STP bit. Note that if one or more of DRDY, ARL, STR, or STP is 1, the low time of SCL is stretched until the service routine responds by clearing them. Writing 1s to "Xmit repeated STaRt" and CDR tells the I2C hardware to send a repeated start condition. This should only be at a master. Note that XSTR need not and should not be used to send an "initial" (non-repeated) start; it is sent automatically by the I2C hardware. Writing XSTR = 1 includes the effect of writing I2DAT with XDAT = 1; it sets Transmit Active and releases SDA to high during the SCL low time. After SCL goes high, the I2C hardware waits for the suitable minimum time and then drives SDA low to make the start condition. Writing 1s to "Xmit SToP" and CDR tells the I2C hardware to send a stop condition. This should only be done at a master. If there are no more messages to initiate, the service routine should clear the MASTRQ bit in I2CFG to 0 before writing XSTP with 1. Writing XSTP = 1 includes the effect of writing I2DAT with XDAT = 0; it sets Transmit Active and drives SDA low during the SCL low time. After SCL goes high, the I2C hardware waits for the suitable minimum time and then releases SDA to high to make the stop condition.
CDR CARL CSTR CSTP
XSTR
STP
MASTER
XSTP
Writing I2CON Typically, for each bit in an I2C message, a service routine waits for ATN = 1. Based on DRDY, ARL, STR, and STP, and on the current
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Philips Semiconductors
Preliminary data
Low power, low price, low pin count (20 pin) microcontroller with 4 kB OTP 8-bit A/D, Pulse Width Modulator
87LPC768
I2CFG
Address: C8h Not Bit Addressable 7 SLAVEN 6 MASTRQ 5 CLRTI 4 TIRUN 3 -- 2 -- 1 CT1 0 CT0
Reset Value: 00h
BIT I2CFG.7
SYMBOL SLAVEN
FUNCTION Slave Enable. Writing a 1 this bit enables the slave functions of the I2C subsystem. If SLAVEN and MASTRQ are 0, the I2C hardware is disabled. This bit is cleared to 0 by reset and by an I2C time-out. Master Request. Writing a 1 to this bit requests mastership of the I2C bus. If a transmission is in progress when this bit is changed from 0 to 1, action is delayed until a stop condition is detected. A start condition is sent and DRDY is set (thus making ATN = 1 and generating an I2C interrupt). When a master wishes to release mastership status of the I2C, it writes a 1 to XSTP in I2CON. MASTRQ is cleared by an I2C time-out. Writing a 1 to this bit clears the Timer I overflow flag. This bit position always reads as a 0. Writing a 1 to this bit lets Timer I run; a zero stops and clears it. Together with SLAVEN, MASTRQ, and MASTER, this bit determines operational modes as shown in Table 1. Reserved for future use. Should not be set to 1 by user programs. These two bits are programmed as a function of the CPU clock rate, to optimize the MIN HI and LO time of SCL when this device is a master on the I2C. The time value determined by these bits controls both of these parameters, and also the timing for stop and start conditions.
SU01157
I2CFG.6
MASTRQ
I2CFG.5 I2CFG.4 I2CFG.2, 3
CLRTI TIRUN --
I2CFG.1, 0 CT1, CT0
Figure 11. I2C Configuration Register (I2CFG) Regarding Software Response Time Because the 87LPC768 can run at 20 MHz, and because the I2C interface is optimized for high-speed operation, it is quite likely that an I2C service routine will sometimes respond to DRDY (which is set at a rising edge of SCL) and write I2DAT before SCL has gone low again. If XDAT were applied directly to SDA, this situation would produce an I2C protocol violation. The programmer need not worry about this possibility because XDAT is applied to SDA only when SCL is low. Conversely, a program that includes an I2C service routine may take a long time to respond to DRDY. Typically, an I2C routine operates on a flag-polling basis during a message, with interrupts from other peripheral functions enabled. If an interrupt occurs, it will delay the response of the I2C service routine. The programmer need not worry about this very much either, because the I2C hardware stretches the SCL low time until the service routine responds. The only constraint on the response is that it must not exceed the Timer I time-out. Values to be used in the CT1 and CT0 bits are shown in Table 2. To allow the I2C bus to run at the maximum rate for a particular oscillator frequency, compare the actual oscillator rate to the f OSC max column in the table. The value for CT1 and CT0 is found in the first line of the table where CPU clock max is greater than or equal to the actual frequency. Table 2 also shows the machine cycle count for various settings of CT1/CT0. This allows calculation of the actual minimum high and low times for SCL as follows: SCL min high low time (in microseconds) + 6 * Min Time Count CPU clock (in MHz)
For instance, at an 8 MHz frequency, with CT1/CT0 set to 1 0, the minimum SCL high and low times will be 5.25 s. Table 2 also shows the Timer I timeout period (given in machine cycles) for each CT1/CT0 combination. The timeout period varies because of the way in which minimum SCL high and low times are measured. When the I2C interface is operating, Timer I is pre-loaded at every SCL transition with a value dependent upon CT1/CT0. The pre-load value is chosen such that a minimum SCL high or low time has elapsed when Timer I reaches a count of 008 (the actual value pre-loaded into Timer I is 8 minus the machine cycle count).
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Philips Semiconductors
Preliminary data
Low power, low price, low pin count (20 pin) microcontroller with 4 kB OTP 8-bit A/D, Pulse Width Modulator
87LPC768
Table 3. Interaction of TIRUN with SLAVEN, MASTRQ, and MASTER
SLAVEN, MASTRQ, MASTER All 0 All 0 Any or all 1 Any or all 1 TIRUN 0 1 0 1 OPERATING MODE The I2C interface is disabled. Timer I is cleared and does not run. This is the state assumed after a reset. If an I2C application wants to ignore the I2C at certain times, it should write SLAVEN, MASTRQ, and TIRUN all to zero. The I2C interface is disabled. The I2C interface is enabled. The 3 low-order bits of Timer I run for min-time generation, but the hi-order bits do not, so that there is no checking for I2C being "hung." This configuration can be used for very slow I2C operation. The I2C interface is enabled. Timer I runs during frames on the I2C, and is cleared by transitions on SCL, and by Start and Stop conditions. This is the normal state for I2C operation.
Table 4. CT1, CT0 Values
CT1, CT0 10 01 00 11 Min Time Count (Machine Cycles) 7 6 5 4 CPU Clock Max (for 100 kHz I2C) 8.4 MHz 7.2 MHz 6.0 MHz 4.8 MHz Timeout Period (Machine Cycles) 1023 1022 1021 1020
Interrupts
The 87LPC768 uses a four priority level interrupt structure. This allows great flexibility in controlling the handling of the 87LPC768's many interrupt sources. The 87LPC768 supports up to 13 interrupt sources. Each interrupt source can be individually enabled or disabled by setting or clearing a bit in registers IEN0 or IEN1. The IEN0 register also contains a global disable bit, EA, which disables all interrupts at once. Each interrupt source can be individually programmed to one of four priority levels by setting or clearing bits in the IP0, IP0H, IP1, and IP1H registers. An interrupt service routine in progress can be interrupted by a higher priority interrupt, but not by another interrupt
of the same or lower priority. The highest priority interrupt service cannot be interrupted by any other interrupt source. So, if two requests of different priority levels are received simultaneously, the request of higher priority level is serviced. If requests of the same priority level are received simultaneously, an internal polling sequence determines which request is serviced. This is called the arbitration ranking. Note that the arbitration ranking is only used to resolve simultaneous requests of the same priority level. Table 3 summarizes the interrupt sources, flag bits, vector addresses, enable bits, priority bits, arbitration ranking, and whether each interrupt may wake up the CPU from Power Down mode.
Table 5. Summary of Interrupts
Description External Interrupt 0 Timer 0 Interrupt External Interrupt 1 Timer 1 Interrupt Serial Port Tx and Rx Brownout Detect I2C Interrupt KBI Interrupt Comparator 2 interrupt Watchdog Timer A/D Converter Comparator 1 interrupt Timer 1 interrupt Interrupt Flag Bit(s) IE0 TF0 IE1 TF1 TI & RI BOD ATN KBF CMF2 WDOVF ADCI CMF1 - Vector Address 0003h 000Bh 0013h 001Bh 0023h 002Bh 0033h 003Bh 0043h 0053h 005Bh 0063h 0073h Interrupt Enable Bit(s) EX0 (IEN0.0) ET0 (IEN0.1) EX1 (IEN0.2) ET1 (IEN0.3) ES (IEN0.4) EBO (IEN0.5) EI2 (IEN1.0) EKB (IEN1.1) EC2 (IEN1.2) EWD (IEN0.6) EAD (IEN1.4) EC1 (IEN1.5) ETI (IEN 1.7) Interrupt Priority IP0H.0, IP0.0 IP0H.1, IP0.1 IP0H.2, IP0.2 IP0H.3, IP0.3 IP0H.4, IP0.4 IP0H.5, IP0.5 IP1H.0, IP1.0 IP1H.1, IP1.1 IP1H.2, IP1.2 IP0H.6, IP0.6 IP1H.4, IP1.4 IP1H.5, IP1.5 Ip1H.7, IP1.7 Arbitration Ranking 1 (highest) 4 7 10 12 2 5 8 11 3 6 9 13 (lowest) Power Down Wakeup Yes No Yes No No Yes No Yes Yes Yes Yes Yes No
2001 Aug 06
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Philips Semiconductors
Preliminary data
Low power, low price, low pin count (20 pin) microcontroller with 4 kB OTP 8-bit A/D, Pulse Width Modulator
87LPC768
External Interrupt Inputs The 87LPC768 has two individual interrupt inputs as well as the Keyboard Interrupt function. The latter is described separately elsewhere in this section. The two interrupt inputs are identical to those present on the standard 80C51 microcontroller. The external sources can be programmed to be level-activated or transition-activated by setting or clearing bit IT1 or IT0 in Register TCON. If ITn = 0, external interrupt n is triggered by a detected low at the INTn pin. If ITn = 1, external interrupt n is edge triggered. In this mode if successive samples of the INTn pin show a high in one cycle and a low in the next cycle, interrupt request flag IEn in TCON is set, causing an interrupt request. Since the external interrupt pins are sampled once each machine cycle, an input high or low should hold for at least 6 CPU Clocks to ensure proper sampling. If the external interrupt is
transition-activated, the external source has to hold the request pin high for at least one machine cycle, and then hold it low for at least one machine cycle. This is to ensure that the transition is seen and that interrupt request flag IEn is set. IEn is automatically cleared by the CPU when the service routine is called. If the external interrupt is level-activated, the external source must hold the request active until the requested interrupt is actually generated. If the external interrupt is still asserted when the interrupt service routine is completed another interrupt will be generated. It is not necessary to clear the interrupt flag IEn when the interrupt is level sensitive, it simply tracks the input pin level. If an external interrupt is enabled when the 87LPC768 is put into Power Down or Idle mode, the interrupt will cause the processor to wake up and resume operation. Refer to the section on Power Reduction Modes for details.
IE0 EX0
IE1 EX1 WAKEUP (IF IN POWER DOWN)
BOD EBO EA (FROM IEN0 REGISTER)
KBF EKB TF0 ET0
INTERRUPT TO CPU
CM2 EC2
WDT EWD
TF1 ET1
ADC EAD CM1 EC1
RI + TI ES
ATN EI2
SU01353
Figure 12. Interrupt Sources, Interrupt Enables, and Power Down Wakeup Sources
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Philips Semiconductors
Preliminary data
Low power, low price, low pin count (20 pin) microcontroller with 4 kB OTP 8-bit A/D, Pulse Width Modulator
87LPC768
I/O Ports
The 87LPC768 has 3 I/O ports, port 0, port 1, and port 2. The exact number of I/O pins available depend upon the oscillator and reset options chosen. At least 15 pins of the 87LPC768 may be used as I/Os when a two-pin external oscillator and an external reset circuit are used. Up to 18 pins may be available if fully on-chip oscillator and reset configurations are chosen. All but three I/O port pins on the 87LPC768 may be software configured to one of four types on a bit-by-bit basis, as shown in Table 4. These are: quasi-bidirectional (standard 80C51 port outputs), push-pull, open drain, and input only. Two configuration registers for each port choose the output type for each port pin.
input and output without the need to reconfigure the port. This is possible because when the port outputs a logic high, it is weakly driven, allowing an external device to pull the pin low. When the pin is pulled low, it is driven strongly and able to sink a fairly large current. These features are somewhat similar to an open drain output except that there are three pull-up transistors in the quasi-bidirectional output that serve different purposes. One of these pull-ups, called the "very weak" pull-up, is turned on whenever the port latch for the pin contains a logic 1. The very weak pull-up sources a very small current that will pull the pin high if it is left floating. A second pull-up, called the "weak" pull-up, is turned on when the port latch for the pin contains a logic 1 and the pin itself is also at a logic 1 level. This pull-up provides the primary source current for a quasi-bidirectional pin that is outputting a 1. If a pin that has a logic 1 on it is pulled low by an external device, the weak pull-up turns off, and only the very weak pull-up remains on. In order to pull the pin low under these conditions, the external device has to sink enough current to overpower the weak pull-up and take the voltage on the port pin below its input threshold. The third pull-up is referred to as the "strong" pull-up. This pull-up is used to speed up low-to-high transitions on a quasi-bidirectional port pin when the port latch changes from a logic 0 to a logic 1. When this occurs, the strong pull-up turns on for a brief time, two CPU clocks, in order to pull the port pin high quickly. Then it turns off again. The quasi-bidirectional port configuration is shown in Figure 13.
Table 6. Port Output Configuration Settings
PxM1.y 0 0 1 1 PxM2.y 0 1 0 1 Port Output Mode Quasi-bidirectional Push-Pull Input Only (High Impedance) Open Drain
Quasi-Bidirectional Output Configuration The default port output configuration for standard 87LPC768 I/O ports is the quasi-bidirectional output that is common on the 80C51 and most of its derivatives. This output type can be used as both an
VDD
2 CPU CLOCK DELAY
P
STRONG
P
VERY WEAK
P
WEAK
PORT PIN PORT LATCH DATA N
INPUT DATA
SU01159
Figure 13. Quasi-Bidirectional Output
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Philips Semiconductors
Preliminary data
Low power, low price, low pin count (20 pin) microcontroller with 4 kB OTP 8-bit A/D, Pulse Width Modulator
87LPC768
Open Drain Output Configuration The open drain output configuration turns off all pull-ups and only drives the pull-down transistor of the port driver when the port latch contains a logic 0. To be used as a logic output, a port configured in this manner must have an external pull-up, typically a resistor tied to VDD. The pull-down for this mode is the same as for the quasi-bidirectional mode. The open drain port configuration is shown in Figure 14. Push-Pull Output Configuration The push-pull output configuration has the same pull-down structure as both the open drain and the quasi-bidirectional output modes, but provides a continuous strong pull-up when the port latch contains a logic 1. The push-pull mode may be used when more source current is needed from a port output. The push-pull port configuration is shown in Figure 15. The three port pins that cannot be configured are P1.2, P1.3, and P1.5. The port pins P1.2 and P1.3 are permanently configured as open drain outputs. They may be used as inputs by writing ones to their respective port latches. P1.5 may be used as a Schmitt trigger input if the 87LPC768 has been configured for an internal reset and is not using the external reset input function RST. Additionally, port pins P2.0 and P2.1 are disabled for both input and output if one of the crystal oscillator options is chosen. Those options are described in the Oscillator section.
The value of port pins at reset is determined by the PRHI bit in the UCFG1 register. Ports may be configured to reset high or low as needed for the application. When port pins are driven high at reset, they are in quasi-bidirectional mode and therefore do not source large amounts of current. Every output on the 87LPC768 may potentially be used as a 20 mA sink LED drive output. However, there is a maximum total output current for all ports which must not be exceeded. All ports pins of the 87LPC768 have slew rate controlled outputs. This is to limit noise generated by quickly switching output signals. The slew rate is factory set to approximately 10 ns rise and fall times. The bits in the P2M1 register that are not used to control configuration of P2.1 and P2.0 are used for other purposes. These bits can enable Schmitt trigger inputs on each I/O port, enable toggle outputs from Timer 0 and Timer 1, and enable a clock output if either the internal RC oscillator or external clock input is being used. The last two functions are described in the Timer/Counters and Oscillator sections respectively. The enable bits for all of these functions are shown in Figure 16. Each I/O port of the 87LPC768 may be selected to use TTL level inputs or Schmitt inputs with hysteresis. A single configuration bit determines this selection for the entire port. Port pins P1.2, P1.3, and P1.5 always have a Schmitt trigger input.
PORT PIN PORT LATCH DATA N
INPUT DATA
SU01160
Figure 14. Open Drain Output
VDD
P
PORT PIN PORT LATCH DATA N
INPUT DATA
SU01161
Figure 15. Push-Pull Output
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Philips Semiconductors
Preliminary data
Low power, low price, low pin count (20 pin) microcontroller with 4 kB OTP 8-bit A/D, Pulse Width Modulator
87LPC768
P2M1
Address: A4h Not Bit Addressable 7 P2S 6 P1S 5 P0S 4 ENCLK 3 ENT1 2 ENT0 1 (P2M1.1) 0 (P2M1.0)
Reset Value: 00h
BIT P2M1.7 P2M1.6 P2M1.5 P2M1.4 P2M1.3 P2M1.2
SYMBOL P2S P1S P0S ENCLK ENT1 ENT0 --
FUNCTION When P2S = 1, this bit enables Schmitt trigger inputs on Port 2. When P1S = 1, this bit enables Schmitt trigger inputs on Port 1. When P0S = 1, this bit enables Schmitt trigger inputs on Port 0. When ENCLK is set and the 87LPC764 is configured to use the on-chip RC oscillator, a clock output is enabled on the X2 pin (P2.0). Refer to the Oscillator section for details. When set, the P.7 pin is toggled whenever Timer 1 overflows. The output frequency is therefore one half of the Timer 1 overflow rate. Refer to the Timer/Counters section for details. When set, the P1.2 pin is toggled whenever Timer 0 overflows. The output frequency is therefore one half of the Timer 0 overflow rate. Refer to the Timer/Counterssection for details. These bits, along with the matching bits in the P2M2 register, control the output configuration of P2.1 and P2.0 respectively, as shown in Table 4.
SU01162
P2M1.1, P2M1.0
Figure 16. Port 2 Mode Register 1 (P2M1)
Keyboard Interrupt (KBI)
The Keyboard Interrupt function is intended primarily to allow a single interrupt to be generated when any key is pressed on a keyboard or keypad connected to specific pins of the 87LPC768, as shown in Figure 17. This interrupt may be used to wake up the CPU from Idle or Power Down modes. This feature is particularly useful in handheld, battery powered systems that need to carefully manage power consumption yet also need to be convenient to use. The 87LPC768 allows any or all pins of port 0 to be enabled to cause this interrupt. Port pins are enabled by the setting of bits in
the KBI register, as shown in Figure 18. The Keyboard Interrupt Flag (KBF) in the AUXR1 register is set when any enabled pin is pulled low while the KBI interrupt function is active. An interrupt will generated if it has been enabled. Note that the KBF bit must be cleared by software. Due to human time scales and the mechanical delay associated with keyswitch closures, the KBI feature will typically allow the interrupt service routine to poll port 0 in order to determine which key was pressed, even if the processor has to wake up from Power Down mode. Refer to the section on Power Reduction Modes for details.
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Philips Semiconductors
Preliminary data
Low power, low price, low pin count (20 pin) microcontroller with 4 kB OTP 8-bit A/D, Pulse Width Modulator
87LPC768
P0.7 KBI.7
P0.6 KBI.6
P0.5 KBI.5
P0.4 KBI.4 KBF (KBI INTERRUPT)
P0.3 KBI.3 EKB (FROM IEN1 REGISTER)
P0.2 KBI.2
P0.1 KBI.1
P0.0 KBI.0
SU01163
Figure 17. Keyboard Interrupt
KBI
Address: 86h Not Bit Addressable 7 KBI.7 6 KBI.6 5 KBI.5 4 KBI.4 3 KBI.3 2 KBI.2 1 KBI.1 0 KBI.0
Reset Value: 00h
BIT KBI.7 KBI.6 KBI.5 KBI.4 KBI.3 KBI.2 KBI.1 KBI.0
SYMBOL -- -- -- -- -- -- -- --
FUNCTION When set, enables P0.7 as a cause of a Keyboard Interrupt. When set, enables P0.6 as a cause of a Keyboard Interrupt. When set, enables P0.5 as a cause of a Keyboard Interrupt. When set, enables P0.4 as a cause of a Keyboard Interrupt. When set, enables P0.3 as a cause of a Keyboard Interrupt. When set, enables P0.2 as a cause of a Keyboard Interrupt. When set, enables P0.1 as a cause of a Keyboard Interrupt. When set, enables P0.0 as a cause of a Keyboard Interrupt.
Note: the Keyboard Interrupt must be enabled in order for the settings of the KBI register to be effective. The interrupt flag (KBF) is located at bit 7 of AUXR1.
SU01164
Figure 18. Keyboard Interrupt Register (KBI)
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Philips Semiconductors
Preliminary data
Low power, low price, low pin count (20 pin) microcontroller with 4 kB OTP 8-bit A/D, Pulse Width Modulator
87LPC768
Oscillator
The 87LPC768 provides several user selectable oscillator options, allowing optimization for a range of needs from high precision to lowest possible cost. These are configured when the EPROM is Low Frequency Oscillator Option This option supports an external crystal in the range of 20 kHz to 100 kHz. Table 7 shows capacitor values that may be used with a quartz crystal in this mode. programmed. Basic oscillator types that are supported include: low, medium, and high speed crystals, covering a range from 20 kHz to 20 MHz; ceramic resonators; and on-chip RC oscillator.
Table 7. Recommended oscillator capacitors for use with the low frequency oscillator option
Oscillator Frequency 20 kHz 32 kHz 100 kHz VDD = 2.7 to 4.5 V Lower Limit 15 pF 15 pF 15 pF Optimal Value 15 pF 15 pF 15 pF Upper Limit 33 pF 33 pF 33 pF Lower Limit 33 pF 33 pF 15 pF VDD = 4.5 to 6.0 V Optimal Value 33 pF 33 pF 15 pF Upper Limit 47 pF 47 pF 33 pF
Medium Frequency Oscillator Option This option supports an external crystal in the range of 100 kHz to 4 MHz. Ceramic resonators are also supported in this configuration. Table 8 shows capacitor values that may be used with a quartz crystal in this mode.
Table 8. Recommended oscillator capacitors for use with the medium frequency oscillator option
Oscillator Freq ency Frequency 100 kHz 1 MHz 4 MHz VDD = 2.7 to 4.5 V Lower Limit 33 pF 15 pF 15 pF Optimal Value 33 pF 15 pF 15 pF Upper Limit 47 pF 33 pF 33 pF
High Frequency Oscillator Option This option supports an external crystal in the range of 4 to 20 MHz. Ceramic resonators are also supported in this configuration. Table 9 shows capacitor values that may be used with a quartz crystal in this mode.
Table 9. Recommended oscillator capacitors for use with the high frequency oscillator option
Oscillator Frequency 4 MHz 8 MHz 16 MHz 20 MHz VDD = 2.7 to 4.5 V Lower Limit 15 pF 15 pF - - Optimal Value 33 pF 15 pF - - Upper Limit 47 pF 33 pF - - Lower Limit 15 pF 15 pF 15 pF 15 pF VDD = 4.5 to 6.0 V Optimal Value 33 pF 33 pF 15 pF 15 pF Upper Limit 68 pF 47 pF 33 pF 33 pF
On-Chip RC Oscillator Option The on-chip RC oscillator option has a typical frequency of 6 MHz and can be divided down for slower operation through the use of the DIVM register. Note that the on-chip oscillator has a 25% frequency tolerance and for that reason may not be suitable for use in some applications. A clock output on the X2/P2.0 pin may be enabled when the on-chip RC oscillator is used. External Clock Input Option In this configuration, the processor clock is input from an external source driving the X1/P2.1 pin. The rate may be from 0 Hz up to 20 MHz when VDD is above 4.5 V and up to 10 MHz when VDD is below 4.5 V. When the external clock input mode is used, the X2/P2.0
pin may be used as a standard port pin. A clock output on the X2/P2.0 pin may be enabled when the external clock input is used. Clock Output The 87LPC768 supports a clock output function when either the on-chip RC oscillator or external clock input options are selected. This allows external devices to synchronize to the 87LPC768. When enabled, via the ENCLK bit in the P2M1 register, the clock output appears on the X2/CLKOUT pin whenever the on-chip oscillator is running, including in Idle mode. The frequency of the clock output is 1/6 of the CPU clock rate. If the clock output is not needed in Idle mode, it may be turned off prior to entering Idle, saving additional power. The clock output may also be enabled when the external clock input option is selected.
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Philips Semiconductors
Preliminary data
Low power, low price, low pin count (20 pin) microcontroller with 4 kB OTP 8-bit A/D, Pulse Width Modulator
87LPC768
THE OSCILLATOR MUST BE CONFIGURED IN ONE OF THE FOLLOWING MODES: - LOW FREQUENCY CRYSTAL - MEDIUM FREQUENCY CRYSTAL - HIGH FREQUENCY CRYSTAL
QUARTZ CRYSTAL OR CERAMIC RESONATOR 87LPC768
X1
CAPACITOR VALUES MAY BE OPTIMIZED FOR DIFFERENT OSCILLATOR FREQUENCIES (SEE TEXT) * X2
A SERIES RESISTOR MAY BE REQUIRED IN ORDER TO LIMIT CRYSTAL DRIVE LEVELS. THIS IS PARTICULARLY IMPORTANT FOR LOW FREQUENCY CRYSTALS (SEE TEXT).
SU01389
Figure 19. Using the Crystal Oscillator
87LPC768
CMOS COMPATIBLE EXTERNAL OSCILLATOR SIGNAL
X1
THE OSCILLATOR MUST BE CONFIGURED IN THE EXTERNAL CLOCK INPUT MODE. A CLOCK OUTPUT MAY BE OBTAINED ON THE X2 PIN BY SETTING THE ENCLK BIT IN THE P2M1 REGISTER.
X2
SU01390
Figure 20. Using an External Clock Input
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Philips Semiconductors
Preliminary data
Low power, low price, low pin count (20 pin) microcontroller with 4 kB OTP 8-bit A/D, Pulse Width Modulator
87LPC768
FOSC2 (UCFG1.2) FOSC1 (UCFG1.1) FOSC0 (UCFG1.0)
CLOCK SELECT
EXTERNAL CLOCK INPUT
XTAL SELECT OSCILLATOR STARTUP TIMER
INTERNAL RC OSCILLATOR CLOCK OUT CRYSTAL: LOW FREQUENCY CLOCK SOURCES RESET COUNT CRYSTAL: MEDIUM FREQUENCY COUNT 1024 10-BIT RIPPLE COUNTER COUNT 256
CRYSTAL: HIGH FREQUENCY DIVIDE-BY-M (DIVM REGISTER) AND CLKR SELECT POWER MONITOR RESET /1//2
CPU CLOCK
POWER DOWN CLKR (UCFG1.3)
SU01167
Figure 21. Block Diagram of Oscillator Control CPU Clock Modification: CLKR and DIVM For backward compatibility, the CLKR configuration bit allows setting the 87LPC768 instruction and peripheral timing to match standard 80C51 timing by dividing the CPU clock by two. Default timing for the 87LPC768 is 6 CPU clocks per machine cycle while standard 80C51 timing is 12 clocks per machine cycle. This division also applies to peripheral timing, allowing 80C51 code that is oscillator frequency and/or timer rate dependent. The CLKR bit is located in the EPROM configuration register UCFG1, described under EPROM Characteristics In addition to this, the CPU clock may be divided down from the oscillator rate by a programmable divider, under program control. This function is controlled by the DIVM register. If the DIVM register is set to zero (the default value), the CPU will be clocked by either the unmodified oscillator rate, or that rate divided by two, as determined by the previously described CLKR function. When the DIVM register is set to some value N (between 1 and 255), the CPU clock is divided by 2 * (N + 1). Clock division values from 4 through 512 are thus possible. This feature makes it possible to temporarily run the CPU at a lower rate, reducing power consumption, in a manner similar to Idle mode. By dividing the clock, the CPU can retain the ability to respond to events other than those that can cause interrupts (i.e. events that allow exiting the Idle mode) by executing its normal program at a lower rate. This can allow bypassing the oscillator startup time in cases where Power Down mode would otherwise be used. The value of DIVM may be changed by the program at any time without interrupting code execution.
Power Monitoring Functions
The 87LPC768 incorporates power monitoring functions designed to prevent incorrect operation during initial power up and power loss or reduction during operation. This is accomplished with two hardware functions: Power-On Detect and Brownout Detect. Brownout Detection The Brownout Detect function allows preventing the processor from failing in an unpredictable manner if the power supply voltage drops below a certain level. The default operation is for a brownout detection to cause a processor reset, however it may alternatively be configured to generate an interrupt by setting the BOI bit in the AUXR1 register (AUXR1.5). The 87LPC768 allows selection of two Brownout levels: 2.5 V or 3.8 V. When VDD drops below the selected voltage, the brownout detector triggers and remains active until VDD is returns to a level above the Brownout Detect voltage. When Brownout Detect causes a processor reset, that reset remains active as long as VDD remains below the Brownout Detect voltage. When Brownout Detect generates an interrupt, that interrupt occurs once as VDD crosses from above to below the Brownout Detect voltage. For the interrupt to be processed, the interrupt system and the BOI interrupt must both be enabled (via the EA and EBO bits in IEN0). When Brownout Detect is activated, the BOF flag in the PCON register is set so that the cause of processor reset may be determined by software. This flag will remain set until cleared by software.
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Philips Semiconductors
Preliminary data
Low power, low price, low pin count (20 pin) microcontroller with 4 kB OTP 8-bit A/D, Pulse Width Modulator
87LPC768
For correct activation of Brownout Detect, the VDD fall time must be no faster than 50 mV/s. When VDD is restored, is should not rise faster than 2 mV/s in order to insure a proper reset. The brownout voltage (2.5 V or 3.8 V) is selected via the BOV bit in the EPROM configuration register UCFG1. When unprogrammed (BOV = 1), the brownout detect voltage is 2.5 V. When programmed (BOV = 0), the brownout detect voltage is 3.8 V. If the Brownout Detect function is not required in an application, it may be disabled, thus saving power. Brownout Detect is disabled by setting the control bit BOD in the AUXR1 register (AUXR1.6). Power On Detection The Power On Detect has a function similar to the Brownout Detect, but is designed to work as power comes up initially, before the power supply voltage reaches a level where Brownout Detect can work. When this feature is activated, the POF flag in the PCON register is set to indicate an initial power up condition. The POF flag will remain set until cleared by software.
The processor can be made to exit Power Down mode via Reset or one of the interrupt sources shown in Table 5. This will occur if the interrupt is enabled and its priority is higher than any interrupt currently in progress. In Power Down mode, the power supply voltage may be reduced to the RAM keep-alive voltage VRAM. This retains the RAM contents at the point where Power Down mode was entered. SFR contents are not guaranteed after VDD has been lowered to VRAM, therefore it is recommended to wake up the processor via Reset in this case. VDD must be raised to within the operating range before the Power Down mode is exited. Since the watchdog timer has a separate oscillator, it may reset the processor upon overflow if it is running during Power Down. Note that if the Brownout Detect reset is enabled, the processor will be put into reset as soon as VDD drops below the brownout voltage. If Brownout Detect is configured as an interrupt and is enabled, it will wake up the processor from Power Down mode when VDD drops below the brownout voltage. When the processor wakes up from Power Down mode, it will start the oscillator immediately and begin execution when the oscillator is stable. Oscillator stability is determined by counting 1024 CPU clocks after start-up when one of the crystal oscillator configurations is used, or 256 clocks after start-up for the internal RC or external clock input configurations. Some chip functions continue to operate and draw power during Power Down mode, increasing the total power used during Power Down. These include the Brownout Detect, Watchdog Timer, Comparators, and A/D converter.
Power Reduction Modes
The 87LPC768 supports Idle and Power Down modes of power reduction. Idle Mode The Idle mode leaves peripherals running in order to allow them to activate the processor when an interrupt is generated. Any enabled interrupt source or Reset may terminate Idle mode. Idle mode is entered by setting the IDL bit in the PCON register (see Figure 22). Power Down Mode The Power Down mode stops the oscillator in order to absolutely minimize power consumption. Power Down mode is entered by setting the PD bit in the PCON register (see Figure 22).
PCON
Address: 87h Not Bit Addressable 7 SMOD1 6 SMOD0 5 BOF 4 POF 3 GF1 2 GF0
Reset Value:
S 30h for a Power On reset S 20h for a Brownout reset S 00h for other reset sources 0 IDL
1 PD
BIT PCON.7 PCON.6 PCON.5
SYMBOL SMOD1 SMOD0 BOF
FUNCTION When set, this bit doubles the UART baud rate for modes 1, 2, and 3. This bit selects the function of bit 7 of the SCON SFR. When 0, SCON.7 is the SM0 bit. When 1, SCON.7 is the FE (Framing Error) flag. See Figure 26 for additional information. Brown Out Flag. Set automatically when a brownout reset or interrupt has occurred. Also set at power on. Cleared by software. Refer to the Power Monitoring Functions section for additional information. Power On Flag. Set automatically when a power-on reset has occurred. Cleared by software. Refer to the Power Monitoring Functions section for additional information. General purpose flag 1. May be read or written by user software, but has no effect on operation. General purpose flag 0. May be read or written by user software, but has no effect on operation. Power Down control bit. Setting this bit activates Power Down mode operation. Cleared when the Power Down mode is terminated (see text). Idle mode control bit. Setting this bit activates Idle mode operation. Cleared when the Idle mode is terminated (see text). Figure 22. Power Control Register (PCON)
PCON.4 PCON.3 PCON.2 PCON.1 PCON.0
POF GF1 GF0 PD IDL
SU01168
2001 Aug 06
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Philips Semiconductors
Preliminary data
Low power, low price, low pin count (20 pin) microcontroller with 4 kB OTP 8-bit A/D, Pulse Width Modulator
87LPC768
Table 10. Sources of Wakeup from Power Down Mode
Wakeup Source External Interrupt 0 or 1 Keyboard Interrupt Comparator 1 or 2 Watchdog Timer Reset Watchdog Timer Interrupt Brownout Detect Reset Brownout Detect Interrupt Reset Input A/D converter Conditions The corresponding interrupt must be enabled. The keyboard interrupt feature must be enabled and properly set up. The corresponding interrupt must be enabled. The comparator(s) must be enabled and properly set up. The corresponding interrupt must be enabled. The watchdog timer must be enabled via the WDTE bit in the UCFG1 EPROM configuration byte. The WDTE bit in the UCFG1 EPROM configuration byte must not be set. The corresponding interrupt must be enabled. The BOD bit in AUXR1 must not be set (brownout detect not disabled). The BOI bit in AUXR1 must not be set (brownout interrupt disabled). The BOD bit in AUXR1 must not be set (brownout detect not disabled). The BOI bit in AUXR1 must be set (brownout interrupt enabled). The corresponding interrupt must be enabled. The external reset input must be enabled. Must use internal RC clock (RCCLK = 1) for A/D converter to work in Power Down mode. The A/D must be enabled and properly set up. The corresponding interrupt must be enabled.
2001 Aug 06
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Philips Semiconductors
Preliminary data
Low power, low price, low pin count (20 pin) microcontroller with 4 kB OTP 8-bit A/D, Pulse Width Modulator
87LPC768
Low Voltage EPROM Operation The EPROM array contains some analog circuits that are not required when VDD is less than 4 V, but are required for a VDD greater than 4 V. The LPEP bit (AUXR.4), when set by software, will power down these analog circuits resulting in a reduced supply current. LPEP is cleared only by power-on reset, so it may be set ONLY for applications that always operate with VDD less than 4 V.
Reset
The 87LPC768 has an active low reset input when configured for an external reset. A fully internal reset may also be configured which provides a reset when power is initially applied to the device. The watchdog timer can act as an oscillator fail detect because it uses an independent, fully on-chip oscillator. The external reset input is disabled, and fully internal reset generation enabled, by programming the RPD bit in the EPROM configuration register UCFG1 to 0. EPROM configuration is described in the section EPROM Characteristics
87LPC768
VDD
87LPC768
8.2 kW RST 2.2 mF 10 mF
RST
SU01391
Figure 23. Typical External Reset Circuits
RPD (UCFG1.6)
RST/VPP PIN
WDTE (UCFG1.7) S WDT MODULE R Q CHIP RESET
SOFTWARE RESET SRST (AUXR1.3) RESET TIMING
POWER MONITOR RESET
CPU CLOCK
SU01170
Figure 24. Block Diagram Showing Reset Sources
2001 Aug 06
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Philips Semiconductors
Preliminary data
Low power, low price, low pin count (20 pin) microcontroller with 4 kB OTP 8-bit A/D, Pulse Width Modulator
87LPC768
Timer/Counters
The 87LPC768 has two general purpose counter/timers which are upward compatible with the standard 80C51 Timer 0 and Timer 1. Both can be configured to operate either as timers or event counters (see Figure 25). An option to automatically toggle the T0 and/or T1 pins upon timer overflow has been added. In the "Timer" function, the register is incremented every machine cycle. Thus, one can think of it as counting machine cycles. Since a machine cycle consists of 6 CPU clock periods, the count rate is 1/6 of the CPU clock frequency. Refer to the section Enhanced CPU for a description of the CPU clock. In the "Counter" function, the register is incremented in response to a 1-to-0 transition at its corresponding external input pin, T0 or T1. In this function, the external input is sampled once during every
machine cycle. When the samples of the pin state show a high in one cycle and a low in the next cycle, the count is incremented. The new count value appears in the register during the cycle following the one in which the transition was detected. Since it takes 2 machine cycles (12 CPU clocks) to recognize a 1-to-0 transition, the maximum count rate is 1/6 of the CPU clock frequency. There are no restrictions on the duty cycle of the external input signal, but to ensure that a given level is sampled at least once before it changes, it should be held for at least one full machine cycle. The "Timer" or "Counter" function is selected by control bits C/T in the Special Function Register TMOD. In addition to the "Timer" or "Counter" selection, Timer 0 and Timer 1 have four operating modes, which are selected by bit-pairs (M1, M0) in TMOD. Modes 0, 1, and 2 are the same for both Timers/Counters. Mode 3 is different. The four operating modes are described in the following text.
TMOD
Address: 89h Not Bit Addressable 7 GATE 6 C/T 5 M1 4 M0 3 GATE 2 C/T 1 M1 0 M0
Reset Value: 00h
BIT TMOD.7 TMOD.6 TMOD.5, 4 TMOD.3 TMOD.2 TMOD.1, 0
SYMBOL GATE C/T M1, M0 GATE C/T M1, M0 M1, M0 00 01 10 11
FUNCTION Gating control for Timer 1. When set, Timer/Counter is enabled only while the INT1 pin is high and the TR1 control pin is set. When cleared, Timer 1 is enabled when the TR1 control bit is set. Timer or Counter Selector for Timer 1. Cleared for Timer operation (input from internal system clock.) Set for Counter operation (input from T1 input pin). Mode Select for Timer 1 (see table below). Gating control for Timer 0. When set, Timer/Counter is enabled only while the INT0 pin is high and the TR0 control pin is set. When cleared, Timer 0 is enabled when the TR0 control bit is set. Timer or Counter Selector for Timer 0. Cleared for Timer operation (input from internal system clock.) Set for Counter operation (input from T0 input pin). Mode Select for Timer 0 (see table below). Timer Mode 8048 Timer "TLn" serves as 5-bit prescaler. 16-bit Timer/Counter "THn" and "TLn" are cascaded; there is no prescaler. 8-bit auto-reload Timer/Counter. THn holds a value which is loaded into TLn when it overflows. Timer 0 is a dual 8-bit Timer/Counter in this mode. TL0 is an 8-bit Timer/Counter controlled by the standard Timer 0 control bits. TH0 is an 8-bit timer only, controlled by the Timer 1 control bits (see text). Timer 1 in this mode is stopped.
SU01171
Figure 25. Timer/Counter Mode Control Register (TMOD)
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Philips Semiconductors
Preliminary data
Low power, low price, low pin count (20 pin) microcontroller with 4 kB OTP 8-bit A/D, Pulse Width Modulator
87LPC768
Mode 0 Putting either Timer into Mode 0 makes it look like an 8048 Timer, which is an 8-bit Counter with a divide-by-32 prescaler. Figure 27 shows Mode 0 operation. In this mode, the Timer register is configured as a 13-bit register. As the count rolls over from all 1s to all 0s, it sets the Timer interrupt flag TFn. The count input is enabled to the Timer when TRn = 1 and either GATE = 0 or INTn = 1. (Setting GATE = 1 allows the Timer to be controlled by external input INTn, to facilitate pulse width
measurements). TRn is a control bit in the Special Function Register TCON (Figure 26). The GATE bit is in the TMOD register. The 13-bit register consists of all 8 bits of THn and the lower 5 bits of TLn. The upper 3 bits of TLn are indeterminate and should be ignored. Setting the run flag (TRn) does not clear the registers. Mode 0 operation is the same for Timer 0 and Timer 1. See Figure 27. There are two different GATE bits, one for Timer 1 (TMOD.7) and one for Timer 0 (TMOD.3).
TCON
Address: 88h Bit Addressable 7 TF1 6 TR1 5 TF0 4 TR0 3 IE1 2 IT1 1 IE0 0 IT0
Reset Value: 00h
BIT TCON.7 TCON.6 TCON.5 TCON.4 TCON.3 TCON.2 TCON.1 TCON.0
SYMBOL TF1 TR1 TF0 TR0 IE1 IT1 IE0 IT0
FUNCTION Timer 1 overflow flag. Set by hardware on Timer/Counter overflow. Cleared by hardware when the interrupt is processed, or by software. Timer 1 Run control bit. Set/cleared by software to turn Timer/Counter 1 on/off. Timer 0 overflow flag. Set by hardware on Timer/Counter overflow. Cleared by hardware when the processor vectors to the interrupt routine, or by software. Timer 0 Run control bit. Set/cleared by software to turn Timer/Counter 0 on/off. Interrupt 1 Edge flag. Set by hardware when external interrupt 1 edge is detected. Cleared by hardware when the interrupt is processed, or by software. Interrupt 1 Type control bit. Set/cleared by software to specify falling edge/low level triggered external interrupts. Interrupt 0 Edge flag. Set by hardware when external interrupt 0 edge is detected. Cleared by hardware when the interrupt is processed, or by software. Interrupt 0 Type control bit. Set/cleared by software to specify falling edge/low level triggered external interrupts. Figure 26. Timer/Counter Control Register (TCON)
OVERFLOW
SU01172
OSC/6 OR OSC/12 Tn PIN
C/T = 0 TLN (5-BITS) C/T = 1 CONTROL THN (8-BITS) TFn INTERRUPT
TRn GATE INTn PIN
TOGGLE Tn PIN
TnOE
SU01173
Figure 27. Timer/Counter 0 or 1 in Mode 0 (13-Bit Counter)
2001 Aug 06
37
Philips Semiconductors
Preliminary data
Low power, low price, low pin count (20 pin) microcontroller with 4 kB OTP 8-bit A/D, Pulse Width Modulator
87LPC768
Mode 1 Mode 1 is the same as Mode 0, except that all 16 bits of the timer register (THn and TLn) are used. See Figure 28 Mode 2 Mode 2 configures the Timer register as an 8-bit Counter (TL1) with automatic reload, as shown in Figure 29. Overflow from TLn not only sets TFn, but also reloads TLn with the contents of THn, which must be preset by software. The reload leaves THn unchanged. Mode 2 operation is the same for Timer 0 and Timer 1. Mode 3 When Timer 1 is in Mode 3 it is stopped. The effect is the same as setting TR1 = 0.
Timer 0 in Mode 3 establishes TL0 and TH0 as two separate 8-bit counters. The logic for Mode 3 on Timer 0 is shown in Figure 30. TL0 uses the Timer 0 control bits: C/T, GATE, TR0, INT0, and TF0. TH0 is locked into a timer function (counting machine cycles) and takes over the use of TR1 and TF1 from Timer 1. Thus, TH0 now controls the "Timer 1" interrupt. Mode 3 is provided for applications that require an extra 8-bit timer. With Timer 0 in Mode 3, an 87LPC768 can look like it has three Timer/Counters. When Timer 0 is in Mode 3, Timer 1 can be turned on and off by switching it into and out of its own Mode 3. It can still be used by the serial port as a baud rate generator, or in any application not requiring an interrupt.
OVERFLOW OSC/6 OR OSC/12 Tn PIN C/T = 0 TLN (8-BITS) C/T = 1 CONTROL THN (8-BITS) TFn INTERRUPT
TRn GATE INTn PIN
TOGGLE Tn PIN
TnOE
SU01174
Figure 28. Timer/Counter 0 or 1 in Mode 1 (16-Bit Counter)
OSC/6 OR OSC/12 Tn PIN
C/T = 0 TLN (8-BITS) C/T = 1 CONTROL OVERFLOW TFn INTERRUPT
RELOAD TRn GATE INTn PIN THN (8-BITS) TnOE TOGGLE Tn PIN
SU01175
Figure 29. Timer/Counter 0 or 1 in Mode 2 (8-Bit Auto-Reload)
2001 Aug 06
38
Philips Semiconductors
Preliminary data
Low power, low price, low pin count (20 pin) microcontroller with 4 kB OTP 8-bit A/D, Pulse Width Modulator
87LPC768
OSC/6 OR OSC/12 T0 PIN
C/T = 0 TL0 (8-BITS) C/T = 1 CONTROL OVERFLOW TF0 INTERRUPT
TR0 GATE INT0 PIN
TOGGLE T0 PIN
T0OE
OSC/6 OR OSC/12 CONTROL
TH0 (8-BITS)
OVERFLOW
TF1
INTERRUPT
TOGGLE TR1 T1 PIN
T1OE
SU01176
Figure 30. Timer/Counter 0 Mode 3 (Two 8-Bit Counters) Timer Overflow Toggle Output Timers 0 and 1 can be configured to automatically toggle a port output whenever a timer overflow occurs. The same device pins that are used for the T0 and T1 count inputs are also used for the timer toggle outputs. This function is enabled by control bits T0OE and T1OE in the P2M1 register, and apply to Timer 0 and Timer 1 respectively. The port outputs will be a logic 1 prior to the first timer overflow when this mode is turned on. Mode 1 10 bits are transmitted (through TxD) or received (through RxD): a start bit (logical 0), 8 data bits (LSB first), and a stop bit (logical 1). When data is received, the stop bit is stored in RB8 in Special Function Register SCON. The baud rate is variable and is determined by the Timer 1 overflow rate. Mode 2 11 bits are transmitted (through TxD) or received (through RxD): start bit (logical 0), 8 data bits (LSB first), a programmable 9th data bit, and a stop bit (logical 1). When data is transmitted, the 9th data bit (TB8 in SCON) can be assigned the value of 0 or 1. Or, for example, the parity bit (P, in the PSW) could be moved into TB8. When data is received, the 9th data bit goes into RB8 in Special Function Register SCON, while the stop bit is ignored. The baud rate is programmable to either 1/16 or 1/32 of the CPU clock frequency, as determined by the SMOD1 bit in PCON. Mode 3 11 bits are transmitted (through TxD) or received (through RxD): a start bit (logical 0), 8 data bits (LSB first), a programmable 9th data bit, and a stop bit (logical 1). In fact, Mode 3 is the same as Mode 2 in all respects except baud rate. The baud rate in Mode 3 is variable and is determined by the Timer 1 overflow rate. In all four modes, transmission is initiated by any instruction that uses SBUF as a destination register. Reception is initiated in Mode 0 by the condition RI = 0 and REN = 1. Reception is initiated in the other modes by the incoming start bit if REN = 1.
UART
The 87LPC768 includes an enhanced 80C51 UART. The baud rate source for the UART is timer 1 for modes 1 and 3, while the rate is fixed in modes 0 and 2. Because CPU clocking is different on the 87LPC768 than on the standard 80C51, baud rate calculation is somewhat different. Enhancements over the standard 80C51 UART include Framing Error detection and automatic address recognition. The serial port is full duplex, meaning it can transmit and receive simultaneously. It is also receive-buffered, meaning it can commence reception of a second byte before a previously received byte has been read from the SBUF register. However, if the first byte still hasn't been read by the time reception of the second byte is complete, the first byte will be lost. The serial port receive and transmit registers are both accessed through Special Function Register SBUF. Writing to SBUF loads the transmit register, and reading SBUF accesses a physically separate receive register. The serial port can be operated in 4 modes: Mode 0 Serial data enters and exits through RxD. TxD outputs the shift clock. 8 bits are transmitted or received, LSB first. The baud rate is fixed at 1/6 of the CPU clock frequency.
2001 Aug 06
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Philips Semiconductors
Preliminary data
Low power, low price, low pin count (20 pin) microcontroller with 4 kB OTP 8-bit A/D, Pulse Width Modulator
87LPC768
Serial Port Control Register (SCON) The serial port control and status register is the Special Function Register SCON, shown in Figure 31. This register contains not only the mode selection bits, but also the 9th data bit for transmit and receive (TB8 and RB8), and the serial port interrupt bits (TI and RI). The Framing Error bit (FE) allows detection of missing stop bits in the received data stream. The FE bit shares the bit position SCON.7
with the SM0 bit. Which bit appears in SCON at any particular time is determined by the SMOD0 bit in the PCON register. If SMOD0 = 0, SCON.7 is the SM0 bit. If SMOD0 = 1, SCON.7 is the FE bit. Once set, the FE bit remains set until it is cleared by software. This allows detection of framing errors for a group of characters without the need for monitoring it for every character individually.
SCON
Address: 98h Bit Addressable 7 SM0/FE 6 SM1 5 SM2 4 REN 3 TB8 2 RB8 1 TI 0 RI
Reset Value: 00h
BIT SCON.7
SYMBOL FE
FUNCTION Framing Error. This bit is set by the UART receiver when an invalid stop bit is detected. Must be cleared by software. The SMOD0 bit in the PCON register must be 1 for this bit to be accessible. See SM0 bit below. With SM1, defines the serial port mode. The SMOD0 bit in the PCON register must be 0 for this bit to be accessible. See FE bit above. With SM0, defines the serial port mode (see table below). UART Mode 0: shift register 1: 8-bit UART 2: 9-bit UART 3: 9-bit UART Baud Rate CPU clock/6 Variable (see text) CPU clock/32 or CPU clock/16 Variable (see text)
SCON.7 SCON. 6
SM0 SM1 SM0, SM1 00 01 10 11
SCON.5
SM2
Enables the multiprocessor communication feature in Modes 2 and 3. In Mode 2 or 3, if SM2 is set to 1, then Rl will not be activated if the received 9th data bit (RB8) is 0. In Mode 1, if SM2=1 then RI will not be activated if a valid stop bit was not received. In Mode 0, SM2 should be 0. Enables serial reception. Set by software to enable reception. Clear by software to disable reception. The 9th data bit that will be transmitted in Modes 2 and 3. Set or clear by software as desired. In Modes 2 and 3, is the 9th data bit that was received. In Mode 1, it SM2=0, RB8 is the stop bit that was received. In Mode 0, RB8 is not used. Transmit interrupt flag. Set by hardware at the end of the 8th bit time in Mode 0, or at the beginning of the stop bit in the other modes, in any serial transmission. Must be cleared by software. Receive interrupt flag. Set by hardware at the end of the 8th bit time in Mode 0, or halfway through the stop bit time in the other modes, in any serial reception (except see SM2). Must be cleared by software.
SU01157
SCON.4 SCON.3 SCON.2 SCON.1 SCON.0
REN TB8 RB8 TI RI
Figure 31. Serial Port Control Register (SCON)
2001 Aug 06
40
Philips Semiconductors
Preliminary data
Low power, low price, low pin count (20 pin) microcontroller with 4 kB OTP 8-bit A/D, Pulse Width Modulator
87LPC768
Baud Rates The baud rate in Mode 0 is fixed: Mode 0 Baud Rate = CPU clock/6. The baud rate in Mode 2 depends on the value of bit SMOD1 in Special Function Register PCON. If SMOD1 = 0 (which is the value on reset), the baud rate is 1/32 of the CPU clock frequency. If SMOD1 = 1, the baud rate is 1/16 of the CPU clock frequency. Mode 2 Baud Rate + 1 ) SMOD1 32 CPU clock frequency
application. The Timer itself can be configured for either "timer" or "counter" operation, and in any of its 3 running modes. In the most typical applications, it is configured for "timer" operation, in the auto-reload mode (high nibble of TMOD = 0010b). In that case the baud rate is given by the formula: CPU clock frequency 192 (or 96 if SMOD1 + 1) 256 * (TH1)
Mode 1, 3 Baud Rate +
Using Timer 1 to Generate Baud Rates When Timer 1 is used as the baud rate generator, the baud rates in Modes 1 and 3 are determined by the Timer 1 overflow rate and the value of SMOD1. The Timer 1 interrupt should be disabled in this
Tables 6 and 7 list various commonly used baud rates and how they can be obtained using Timer 1 as the baud rate generator.
Table 11. Baud Rates, Timer Values, and CPU Clock Frequencies for SMOD1 = 0
Timer Co nt Count -1 -2 -3 -4 -5 -6 -7 -8 -9 -10 Baud Rate 2400 0.4608 0.9216 1.3824 * 1.8432 2.3040 2.7648 3.2256 * 3.6864 4.1472 4.6080 4800 0.9216 1.8432 2.7648 * 3.6864 4.6080 5.5296 6.4512 * 7.3728 8.2944 9.2160 9600 * 1.8432 * 3.6864 5.5296 * 7.3728 9.2160 * 11.0592 12.9024 * 14.7456 16.5888 * 18.4320 19.2k * 3.6864 * 7.3728 * 11.0592 * 14.7456 * 18.4320 - - - - - 38.4k * 7.3728 * 14.7456 - - - - - - - - - - - - - - - - 57.6k * 11.0592
2001 Aug 06
41
Philips Semiconductors
Preliminary data
Low power, low price, low pin count (20 pin) microcontroller with 4 kB OTP 8-bit A/D, Pulse Width Modulator
87LPC768
Table 12. Baud Rates, Timer Values, and CPU Clock Frequencies for SMOD1 = 1
Timer Co nt Count -1 -2 -3 -4 -5 -6 -7 -8 -9 -10 -11 -12 -13 -14 -15 -16 -17 -18 -19 -20 -21 Baud Rate 2400 0.2304 0.4608 0.6912 0.9216 1.1520 1.3824 1.6128 * 1.8432 2.0736 2.3040 2.5344 2.7648 2.9952 3.2256 3.4560 * 3.6864 3.9168 4.1472 4.3776 4.6080 4.8384 4800 0.4608 0.9216 1.3824 * 1.8432 2.3040 2.7648 3.2256 * 3.6864 4.1472 4.6080 5.0688 5.5296 5.9904 6.4512 6.9120 * 7.3728 7.8336 8.2944 8.7552 9.2160 9.6768 9600 0.9216 * 1.8432 2.7648 * 3.6864 4.6080 5.5296 6.4512 * 7.3728 8.2944 9.2160 10.1376 * 11.0592 11.9808 12.9024 13.8240 * 14.7456 15.6672 16.5888 17.5104 * 18.4320 19.3536 19.2k * 1.8432 * 3.6864 5.5296 * 7.3728 9.2160 * 11.0592 12.9024 * 14.7456 16.5888 * 18.4320 - - - - - - - - - - - 38.4k * 3.6864 * 7.3728 * 11.0592 * 14.7456 * 18.4320 - - - - - - - - - - - - - - - - 57.6k 5.5296 * 11.0592 16.5888 - - - - - - - - - - - - - - - - - - 115.2k * 11.0592 - - - - - - - - - - - - - - - - - - - -
NOTES TO TABLES 11 AND 12: 1. Tables 6 and 7 apply to UART modes 1 and 3 (variable rate modes), and show CPU clock rates in MHz for standard baud rates from 2400 to 115.2k baud. 2. Table 6 shows timer settings and CPU clock rates with the SMOD1 bit in the PCON register = 0 (the default after reset), while Table 7 reflects the SMOD1 bit = 1. 3. The tables show all potential CPU clock frequencies up to 20 MHz that may be used for baud rates from 9600 baud to 115.2k baud. Other CPU clock frequencies that would give only lower baud rates are not shown. 4. Table entries marked with an asterisk (*) indicate standard crystal and ceramic resonator frequencies that may be obtained from many sources without special ordering.
2001 Aug 06
42
Philips Semiconductors
Preliminary data
Low power, low price, low pin count (20 pin) microcontroller with 4 kB OTP 8-bit A/D, Pulse Width Modulator
87LPC768
More About UART Mode 0 Serial data enters and exits through RxD. TxD outputs the shift clock. 8 bits are transmitted/received: 8 data bits (LSB first). The baud rate is fixed at 1/6 the CPU clock frequency. Figure 32 shows a simplified functional diagram of the serial port in Mode 0, and associated timing. Transmission is initiated by any instruction that uses SBUF as a destination register. The "write to SBUF" signal at S6P2 also loads a 1 into the 9th position of the transmit shift register and tells the TX Control block to commence a transmission. The internal timing is such that one full machine cycle will elapse between "write to SBUF" and activation of SEND. SEND enables the output of the shift register to the alternate output function line of P1.1 and also enable SHIFT CLOCK to the alternate output function line of P1.0. SHIFT CLOCK is low during S3, S4, and S5 of every machine cycle, and high during S6, S1, and S2. At S6P2 of every machine cycle in which SEND is active, the contents of the transmit shift are shifted to the right one position. As data bits shift out to the right, zeros come in from the left. When the MSB of the data byte is at the output position of the shift register, then the 1 that was initially loaded into the 9th position, is just to the left of the MSB, and all positions to the left of that contain zeros. This condition flags the TX Control block to do one last shift and then deactivate SEND and set T1. Both of these actions occur at S1P1 of the 10th machine cycle after "write to SBUF." Reception is initiated by the condition REN = 1 and R1 = 0. At S6P2 of the next machine cycle, the RX Control unit writes the bits 11111110 t o the receive shift register, and in the next clock phase activates RECEIVE. RECEIVE enable SHIFT CLOCK to the alternate output function line of P1.0. SHIFT CLOCK makes transitions at S3P1 and S6P1 of every machine cycle. At S6P2 of every machine cycle in which RECEIVE is active, the contents of the receive shift register are shifted to the left one position. The value that comes in from the right is the value that was sampled at the P1.1 pin at S5P2 of the same machine cycle. As data bits come in from the right, 1s shift out to the left. When the 0 that was initially loaded into the rightmost position arrives at the leftmost position in the shift register, it flags the RX Control block to do one last shift and load SBUF. At S1P1 of the 10th machine cycle after the write to SCON that cleared RI, RECEIVE is cleared as RI is set.
More About UART Mode 1 Ten bits are transmitted (through TxD), or received (through RxD): a start bit (0), 8 data bits (LSB first), and a stop bit (1). On receive, the stop bit goes into RB8 in SCON. In the 87LPC768 the baud rate is determined by the Timer 1 overflow rate. Figure 33 shows a simplified functional diagram of the serial port in Mode 1, and associated timings for transmit receive. Transmission is initiated by any instruction that uses SBUF as a destination register. The "write to SBUF" signal also loads a 1 into the 9th bit position of the transmit shift register and flags the TX Control unit that a transmission is requested. Transmission actually commences at S1P1 of the machine cycle following the next rollover in the divide-by-16 counter. (Thus, the bit times are synchronized to the divide-by-16 counter, not to the "write to SBUF" signal.) The transmission begins with activation of SEND which puts the start bit at TxD. One bit time later, DATA is activated, which enables the output bit of the transmit shift register to TxD. The first shift pulse occurs one bit time after that. As data bits shift out to the right, zeros are clocked in from the left. When the MSB of the data byte is at the output position of the shift register, then the 1 that was initially loaded into the 9th position is just to the left of the MSB, and all positions to the left of that contain zeros. This condition flags the TX Control unit to do one last shift and then deactivate SEND and set TI. This occurs at the 10th divide-by-16 rollover after "write to SBUF." Reception is initiated by a detected 1-to-0 transition at RxD. For this purpose RxD is sampled at a rate of 16 times whatever baud rate has been established. When a transition is detected, the divide-by-16 counter is immediately reset, and 1FFH is written into the input shift register. Resetting the divide-by-16 counter aligns its rollovers with the boundaries of the incoming bit times. The 16 states of the counter divide each bit time into 16ths. At the 7th, 8th, and 9th counter states of each bit time, the bit detector samples the value of RxD. The value accepted is the value that was seen in at least 2 of the 3 samples. This is done for noise rejection. If the value accepted during the first bit time is not 0, the receive circuits are reset and the unit goes back to looking for another 1-to-0 transition. This is to provide rejection of false start bits. If the start bit proves valid, it is shifted into the input shift register, and reception of the rest of the frame will proceed. As data bits come in from the right, 1s shift out to the left. When the start bit arrives at the leftmost position in the shift register (which in mode 1 is a 9-bit register), it flags the RX Control block to do one last shift, load SBUF and RB8, and set RI. The signal to load SBUF and RB8, and to set RI, will be generated if, and only if, the following conditions are met at the time the final shift pulse is generated.: 1. R1 = 0, and 2. Either SM2 = 0, or the received stop bit = 1. If either of these two conditions is not met, the received frame is irretrievably lost. If both conditions are met, the stop bit goes into RB8, the 8 data bits go into SBUF, and RI is activated. At this time, whether the above conditions are met or not, the unit goes back to looking for a 1-to-0 transition in RxD.
2001 Aug 06
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Philips Semiconductors
Preliminary data
Low power, low price, low pin count (20 pin) microcontroller with 4 kB OTP 8-bit A/D, Pulse Width Modulator
87LPC768
80C51 INTERNAL BUS WRITE TO SBUF D CL S Q SBUF RxD P1.1 ALT OUTPUT FUNCTION
ZERO DETECTOR
START TX CONTROL S6 SERIAL PORT INTERRUPT TX CLOCK REN RI START 1 1 RI RX CONTROL 1 1 1 1 1 TX CLOCK TI
SHIFT TxD P1.0 ALT OUTPUT FUNCTION SHIFT CLOCK
SEND
RECEIVE SHIFT 0
INPUT SHIFT REGISTER LOAD SBUF
RXD P1.1 ALT INPUT FUNCTION
SBUF
READ SBUF
80C51 INTERNAL BUS
S1 ... S6 WRITE TO SBUF SEND SHIFT RXD (DATA OUT) TXD (SHIFT CLOCK) TI
S1 ... S6
S1 ... S6
S1 ... S6
S1 ... S6
S1 ... S6
S1 ... S6
S1 ... S6
S1 ... S6 S1 ... S6
S1 ... S6
S1 ... S6
S1 ... S6
TRANSMIT D0 D1 D2 D3 D4 D5 D6 D7
WRITE TO SCON (CLEAR RI) RI RECEIVE RECEIVE SHIFT RxD (DATA IN) TxD (SHIFT CLOCK) D0 D1 D2 D3 D4 D5 D6 D7
SU01178
Figure 32. Serial Port Mode 0
2001 Aug 06
44
Philips Semiconductors
Preliminary data
Low power, low price, low pin count (20 pin) microcontroller with 4 kB OTP 8-bit A/D, Pulse Width Modulator
87LPC768
80C51 INTERNAL BUS TB8 WRITE TO SBUF
TIMER 1 OVERFLOW
D CL
S Q SBUF TxD P1.0 ALT OUTPUT FUNCTION
/2
ZERO DETECTOR SMOD1 =1 START TX CONTROL /16 TX CLOCK /16 RX CLOCK START RI LOAD SBUF SHIFT 1FFH TI SHIFT DATA SEND SERIAL PORT INTERRUPT
SMOD1 = 0
1-TO-0 TRANSITION DETECTOR
RX CONTROL
BIT DETECTOR RxD P1.1 ALT INPUT FUNCTION LOAD SBUF
INPUT SHIFT REGISTER
SBUF
READ SBUF
80C51 INTERNAL BUS
TX CLOCK WRITE TO SBUF SEND DATA SHIFT TxD TI START BIT D0 D1 D2 D3 D4 D5 D6 D7 STOP BIT TRANSMIT
RX CLOCK RxD / 16 RESET START BIT D0 D1 D2 D3 D4 D5 D6 D7 STOP BIT RECEIVE
BIT DETECTOR SAMPLE TIMES SHIFT RI
SU01179
Figure 33. Serial Port Mode 1
2001 Aug 06
45
Philips Semiconductors
Preliminary data
Low power, low price, low pin count (20 pin) microcontroller with 4 kB OTP 8-bit A/D, Pulse Width Modulator
87LPC768
More About UART Modes 2 and 3 Eleven bits are transmitted (through TxD), or received (through RxD): a start bit (0), 8 data bits (LSB first), a programmable 9th data bit, and a stop bit (1). On transmit, the 9th data bit (TB8) can be assigned the value of 0 or 1. On receive, the 9the data bit goes into RB8 in SCON. The baud rate is programmable to either 1/16 or 1/32 of the CPU clock frequency in Mode 2. Mode 3 may have a variable baud rate generated from Timer 1. Figures 34 and 35 show a functional diagram of the serial port in Modes 2 and 3. The receive portion is exactly the same as in Mode 1. The transmit portion differs from Mode 1 only in the 9th bit of the transmit shift register. Transmission is initiated by any instruction that uses SBUF as a destination register. The "write to SBUF" signal also loads TB8 into the 9th bit position of the transmit shift register and flags the TX Control unit that a transmission is requested. Transmission commences at S1P1 of the machine cycle following the next rollover in the divide-by-16 counter. (Thus, the bit times are synchronized to the divide-by-16 counter, not to the "write to SBUF" signal.) The transmission begins with activation of SEND, which puts the start bit at TxD. One bit time later, DATA is activated, which enables the output bit of the transmit shift register to TxD. The first shift pulse occurs one bit time after that. The first shift clocks a 1 (the stop bit) into the 9th bit position of the shift register. Thereafter, only zeros are clocked in. Thus, as data bits shift out to the right, zeros are clocked in from the left. When TB8 is at the output position of the shift register, then the stop bit is just to the left of TB8, and all positions to the left of that contain zeros. This condition flags the TX Control unit to do one last shift and then deactivate SEND and set TI. This occurs at the 11th divide-by-16 rollover after "write to SBUF." Reception is initiated by a detected 1-to-0 transition at RxD. For this purpose RxD is sampled at a rate of 16 times whatever baud rate has been established. When a transition is detected, the divide-by-16 counter is immediately reset, and 1FFH is written to the input shift register. At the 7th, 8th, and 9th counter states of each bit time, the bit detector samples the value of R-D. The value accepted is the value that was seen in at least 2 of the 3 samples. If the value accepted during the first bit time is not 0, the receive circuits are reset and the unit goes back to looking for another 1-to-0 transition. If the start bit
proves valid, it is shifted into the input shift register, and reception of the rest of the frame will proceed. As data bits come in from the right, 1s shift out to the left. When the start bit arrives at the leftmost position in the shift register (which in Modes 2 and 3 is a 9-bit register), it flags the RX Control block to do one last shift, load SBUF and RB8, and set RI. The signal to load SBUF and RB8, and to set RI, will be generated if, and only if, the following conditions are met at the time the final shift pulse is generated. 1. RI = 0, and 2. Either SM2 = 0, or the received 9th data bit = 1. If either of these conditions is not met, the received frame is irretrievably lost, and RI is not set. If both conditions are met, the received 9th data bit goes into RB8, and the first 8 data bits go into SBUF. One bit time later, whether the above conditions were met or not, the unit goes back to looking for a 1-to-0 transition at the RxD input. Multiprocessor Communications UART modes 2 and 3 have a special provision for multiprocessor communications. In these modes, 9 data bits are received or transmitted. When data is received, the 9th bit is stored in RB8. The UART can be programmed such that when the stop bit is received, the serial port interrupt will be activated only if RB8 = 1. This feature is enabled by setting bit SM2 in SCON. One way to use this feature in multiprocessor systems is as follows: When the master processor wants to transmit a block of data to one of several slaves, it first sends out an address byte which identifies the target slave. An address byte differs from a data byte in that the 9th bit is 1 in an address byte and 0 in a data byte. With SM2 = 1, no slave will be interrupted by a data byte. An address byte, however, will interrupt all slaves, so that each slave can examine the received byte and see if it is being addressed. The addressed slave will clear its SM2 bit and prepare to receive the data bytes that follow. The slaves that weren't being addressed leave their SM2 bits set and go on about their business, ignoring the subsequent data bytes. SM2 has no effect in Mode 0, and in Mode 1 can be used to check the validity of the stop bit, although this is better done with the Framing Error flag. In a Mode 1 reception, if SM2 = 1, the receive interrupt will not be activated unless a valid stop bit is received.
2001 Aug 06
46
Philips Semiconductors
Preliminary data
Low power, low price, low pin count (20 pin) microcontroller with 4 kB OTP 8-bit A/D, Pulse Width Modulator
87LPC768
80C51 INTERNAL BUS TB8 WRITE TO SBUF
PHASE 2 CLOCK (1/2 fOSC)
D CL
S Q SBUF TxD P1.0 ALT OUTPUT FUNCTION
/2
ZERO DETECTOR SMOD1 =1 START STOP BIT GEN. TX CONTROL /16 TX CLOCK /16 RX CLOCK START RI LOAD SBUF SHIFT 1FFH TI SHIFT DATA SEND SERIAL PORT INTERRUPT
SMOD1 = 0
1-TO-0 TRANSITION DETECTOR
RX CONTROL
BIT DETECTOR RxD P1.1 ALT INPUT FUNCTION LOAD SBUF
INPUT SHIFT REGISTER
SBUF READ SBUF
80C51 INTERNAL BUS
TX CLOCK WRITE TO SBUF SEND DATA SHIFT TxD TI STOP BIT GEN. START BIT D0 D1 D2 D3 D4 D5 D6 D7 TB8 STOP BIT TRANSMIT
RX CLOCK RxD / 16 RESET START BIT D0 D1 D2 D3 D4 D5 D6 D7 RB8 STOP BIT RECEIVE
BIT DETECTOR SAMPLE TIMES SHIFT RI
SU01180
Figure 34. Serial Port Mode 2
2001 Aug 06
47
Philips Semiconductors
Preliminary data
Low power, low price, low pin count (20 pin) microcontroller with 4 kB OTP 8-bit A/D, Pulse Width Modulator
87LPC768
80C51 INTERNAL BUS TB8 WRITE TO SBUF
TIMER 1 OVERFLOW
D CL
S Q SBUF TxD P1.0 ALT OUTPUT FUNCTION
/2
ZERO DETECTOR SMOD1 =1 START TX CONTROL /16 TX CLOCK /16 RX CLOCK START RI LOAD SBUF SHIFT 1FFH TI SHIFT DATA SEND SERIAL PORT INTERRUPT
SMOD1 = 0
1-TO-0 TRANSITION DETECTOR
RX CONTROL
BIT DETECTOR RxD P1.1 ALT INPUT FUNCTION LOAD SBUF
INPUT SHIFT REGISTER
SBUF
READ SBUF
80C51 INTERNAL BUS
TX CLOCK WRITE TO SBUF SEND DATA SHIFT TxD TI STOP BIT GEN. START BIT D0 D1 D2 D3 D4 D5 D6 D7 TB8 STOP BIT TRANSMIT
RX CLOCK RxD / 16 RESET START BIT D0 D1 D2 D3 D4 D5 D6 D7 RB8 STOP BIT RECEIVE
BIT DETECTOR SAMPLE TIMES SHIFT RI
SU01181
Figure 35. Serial Port Mode 3
2001 Aug 06
48
Philips Semiconductors
Preliminary data
Low power, low price, low pin count (20 pin) microcontroller with 4 kB OTP 8-bit A/D, Pulse Width Modulator
87LPC768
Automatic Address Recognition Automatic Address Recognition is a feature which allows the UART to recognize certain addresses in the serial bit stream by using hardware to make the comparisons. This feature saves a great deal of software overhead by eliminating the need for the software to examine every serial address which passes by the serial port. This feature is enabled by setting the SM2 bit in SCON. In the 9 bit UART modes, mode 2 and mode 3, the Receive Interrupt flag (RI) will be automatically set when the received byte contains either the "Given" address or the "Broadcast" address. The 9 bit mode requires that the 9th information bit is a 1 to indicate that the received information is an address and not data. Using the Automatic Address Recognition feature allows a master to selectively communicate with one or more slaves by invoking the Given slave address or addresses. All of the slaves may be contacted by using the Broadcast address. Two special Function Registers are used to define the slave's address, SADDR, and the address mask, SADEN. SADEN is used to define which bits in the SADDR are to be used and which bits are "don't care". The SADEN mask can be logically ANDed with the SADDR to create the "Given" address which the master will use for addressing each of the slaves. Use of the Given address allows multiple slaves to be recognized while excluding others. The following examples will help to show the versatility of this scheme: Slave 0 SADDR = 1100 0000 SADEN = 1111 1101 Given = 1100 00X0 SADDR = 1100 0000 SADEN = 1111 1110 Given = 1100 000X
will be FF hexadecimal. Upon reset SADDR and SADEN are loaded with 0s. This produces a given address of all "don't cares" as well as a Broadcast address of all "don't cares". This effectively disables the Automatic Addressing mode and allows the microcontroller to use standard UART drivers which do not make use of this feature.
Watchdog Timer
When enabled via the WDTE configuration bit, the watchdog timer is operated from an independent, fully on-chip oscillator in order to provide the greatest possible dependability. When the watchdog feature is enabled, the timer must be fed regularly by software in order to prevent it from resetting the CPU, and it cannot be turned off. When disabled as a watchdog timer (via the WDTE bit in the UCFG1 configuration register), it may be used as an interval timer and may generate an interrupt. The watchdog timer is shown in Figure 36. The watchdog timeout time is selectable from one of eight values, nominal times range from 16 milliseconds to 2.1 seconds. The frequency tolerance of the independent watchdog RC oscillator is 37%. The timeout selections and other control bits are shown in Figure 37. When the watchdog function is enabled, the WDCON register may be written once during chip initialization in order to set the watchdog timeout time. The recommended method of initializing the WDCON register is to first feed the watchdog, then write to WDCON to configure the WDS2-0 bits. Using this method, the watchdog initialization may be done any time within 10 milliseconds after startup without a watchdog overflow occurring before the initialization can be completed. Since the watchdog timer oscillator is fully on-chip and independent of any external oscillator circuit used by the CPU, it intrinsically serves as an oscillator fail detection function. If the watchdog feature is enabled and the CPU oscillator fails for any reason, the watchdog timer will time out and reset the CPU. When the watchdog function is enabled, the timer is deactivated temporarily when a chip reset occurs from another source, such as a power on reset, brownout reset, or external reset. Watchdog Feed Sequence If the watchdog timer is running, it must be fed before it times out in order to prevent a chip reset from occurring. The watchdog feed sequence consists of first writing the value 1Eh, then the value E1h to the WDRST register. An example of a watchdog feed sequence is shown below.
WDFeed: mov WDRST,#1eh ; First part of watchdog feed sequence. mov WDRST,#0e1h ; Second part of watchdog feed sequence.
Slave 1
In the above example SADDR is the same and the SADEN data is used to differentiate between the two slaves. Slave 0 requires a 0 in bit 0 and it ignores bit 1. Slave 1 requires a 0 in bit 1 and bit 0 is ignored. A unique address for Slave 0 would be 1100 0010 since slave 1 requires a 0 in bit 1. A unique address for slave 1 would be 1100 0001 since a 1 in bit 0 will exclude slave 0. Both slaves can be selected at the same time by an address which has bit 0 = 0 (for slave 0) and bit 1 = 0 (for slave 1). Thus, both could be addressed with 1100 0000. In a more complex system the following could be used to select slaves 1 and 2 while excluding slave 0: Slave 0 SADDR = 1100 0000 SADEN = 1111 1001 Given = 1100 0XX0 SADDR = 1110 0000 SADEN = 1111 1010 Given = 1110 0X0X SADDR = 1110 0000 SADEN = 1111 1100 Given = 1110 00XX
Slave 1
Slave 2
The two writes to WDRST do not have to occur in consecutive instructions. An incorrect watchdog feed sequence does not cause any immediate response from the watchdog timer, which will still time out at the originally scheduled time if a correct feed sequence does not occur prior to that time. After a chip reset, the user program has a limited time in which to either feed the watchdog timer or change the timeout period. When a low CPU clock frequency is used in the application, the number of instructions that can be executed before the watchdog overflows may be quite small. Watchdog Reset If a watchdog reset occurs, the internal reset is active for approximately one microsecond. If the CPU clock was still running, code execution will begin immediately after that. If the processor was in Power Down mode, the watchdog reset will start the oscillator and code execution will resume after the oscillator is stable.
In the above example the differentiation among the 3 slaves is in the lower 3 address bits. Slave 0 requires that bit 0 = 0 and it can be uniquely addressed by 1110 0110. Slave 1 requires that bit 1 = 0 and it can be uniquely addressed by 1110 and 0101. Slave 2 requires that bit 2 = 0 and its unique address is 1110 0011. To select Slaves 0 and 1 and exclude Slave 2 use address 1110 0100, since it is necessary to make bit 2 = 1 to exclude slave 2. The Broadcast Address for each slave is created by taking the logical OR of SADDR and SADEN. Zeros in this result are treated as don't-cares. In most cases, interpreting the don't-cares as ones, the broadcast address
2001 Aug 06
49
Philips Semiconductors
Preliminary data
Low power, low price, low pin count (20 pin) microcontroller with 4 kB OTP 8-bit A/D, Pulse Width Modulator
87LPC768
500 kHz R/C OSCILLATOR CLOCK OUT ENABLE WDCLK * WDTE STATE CLOCK 8 MSBs 20-BIT COUNTER WDTE + WDRUN CLEAR WDTE (UCFG1.7) WATCHDOG INTERRUPT WDS2-0 (WDCON.2-0) 8 TO 1 MUX WATCHDOG RESET
WATCHDOG FEED DETECT BOD (xxx.x) POR (xxx.x)
S Q R WDOVF (WDCON.5)
SU01182
Figure 36. Block Diagram of the Watchdog Timer
WDCON
Address: A7h Not Bit Addressable
Reset Value: S 30h for a watchdog reset. S 10h for other rest sources if the watchdog is enabled via the WDTE configuration bit. S 00h for other reset sources if the watchdog is disabled via the WDTE configuration bit. 7 -- 6 -- 5 WDOVF 4 WDRUN 3 WDCLK 2 WDS2 1 WDS1 0 WDS0
BIT WDCON.7, 6 WDCON.5 WDCON.4 WDCON.3
SYMBOL -- WDOVF WDRUN WDCLK
FUNCTION Reserved for future use. Should not be set to 1 by user programs. Watchdog timer overflow flag. Set when a watchdog reset or timer overflow occurs. Cleared when the watchdog is fed. Watchdog run control. The watchdog timer is started when WDRUN = 1 and stopped when WDRUN = 0. This bit is forced to 1 (watchdog running) if the WDTE configuration bit = 1. Watchdog clock select. The watchdog timer is clocked by CPU clock/6 when WDCLK = 1 and by the watchdog RC oscillator when WDCLK = 0. This bit is forced to 0 (using the watchdog RC oscillator) if the WDTE configuration bit = 1. Watchdog rate select. Timeout Clocks 8,192 16,384 32,768 65,536 131,072 262,144 524,288 1,048,576 Minimum Time 10 ms 20 ms 41 ms 82 ms 165 ms 330 ms 660 ms 1.3 sec Nominal Time 16 ms 32 ms 65 ms 131 ms 262 ms 524 ms 1.05 sec 2.1 sec Maximum Time 23 ms 45 ms 90 ms 180 ms 360 ms 719 ms 1.44 sec 2.9 sec
SU01183
WDCON.2-0 WDS2-0 WDS2-0 000 001 010 011 100 101 110 111
Figure 37. Watchdog Timer Control Register (WDCON)
2001 Aug 06
50
Philips Semiconductors
Preliminary data
Low power, low price, low pin count (20 pin) microcontroller with 4 kB OTP 8-bit A/D, Pulse Width Modulator
87LPC768
Additional Features
The AUXR1 register contains several special purpose control bits that relate to several chip features. AUXR1 is described in Figure 38. Software Reset The SRST bit in AUXR1 allows software the opportunity to reset the processor completely, as if an external reset or watchdog reset had occurred. If a value is written to AUXR1 that contains a 1 at bit position 3, all SFRs will be initialized and execution will resume at program address 0000. Care should be taken when writing to AUXR1 to avoid accidental software resets. Dual Data Pointers The dual Data Pointer (DPTR) adds to the ways in which the processor can specify the address used with certain instructions. The DPS bit in the AUXR1 register selects one of the two Data Pointers. The DPTR that is not currently selected is not accessible to software unless the DPS bit is toggled. Specific instructions affected by the Data Pointer selection are:
* MOV
DPTR, #data16
Load the Data Pointer with a 16-bit constant. Move code byte relative to DPTR to the accumulator. Move data byte the accumulator to data memory relative to DPTR. Move data byte from data memory relative to DPTR to the accumulator.
* MOVC A, @A+DPTR * MOVX A, @DPTR * MOVX @DPTR, A
Also, any instruction that reads or manipulates the DPH and DPL registers (the upper and lower bytes of the current DPTR) will be affected by the setting of DPS. The MOVX instructions have limited application for the 87LPC768 since the part does not have an external data bus. However, they may be used to access EPROM configuration information (see EPROM Characteristics section). Bit 2 of AUXR1 is permanently wired as a logic 0. This is so that the DPS bit may be toggled (thereby switching Data Pointers) simply by incrementing the AUXR1 register, without the possibility of inadvertently altering other bits in the register.
* INC * JMP
DPTR @A+DPTR
Increments the Data Pointer by 1. Jump indirect relative to DPTR value.
AUXR1
Address: A2h Not Bit Addressable 7 KBF 6 BOD 5 BOI 4 LPEP 3 SRST 2 0 1 -- 0 DPS
Reset Value: 00h
BIT AUXR1.7 AUXR1.6 AUXR1.5
SYMBOL KBF BOD BOI
FUNCTION Keyboard Interrupt Flag. Set when any pin of port 0 that is enabled for the Keyboard Interrupt function goes low. Must be cleared by software. Brown Out Disable. When set, turns off brownout detection and saves power. See Power Monitoring Functions section for details. Brown Out Interrupt. When set, prevents brownout detection from causing a chip reset and allows the brownout detect function to be used as an interrupt. See the Power Monitoring Functions section for details. Low Power EPROM control bit. Allows power savings in low voltage systems. Set by software. Can only be cleared by power-on or brownout reset. See the Power Reduction Modes section for details. Software Reset. When set by software, resets the 87LPC764 as if a hardware reset occurred. This bit contains a hard-wired 0. Allows toggling of the DPS bit by incrementing AUXR1, without interfering with other bits in the register. Reserved for future use. Should not be set to 1 by user programs. Data Pointer Select. Chooses one of two Data Pointers for use by the program. See text for details.
SU01184
AUXR1.4
LPEP
AUXR1.3 AUXR1.2 AUXR1.1 AUXR1.0
SRST -- -- DPS
Figure 38. AUXR1 Register
2001 Aug 06
51
Philips Semiconductors
Preliminary data
Low power, low price, low pin count (20 pin) microcontroller with 4 kB OTP 8-bit A/D, Pulse Width Modulator
87LPC768
EPROM Characteristics
Programming of the EPROM on the 87LPC768 is accomplished with a serial programming method. Commands, addresses, and data are transmitted to and from the device on two pins after programming mode is entered. Serial programming allows easy implementation of in-circuit programming of the 87LPC768 in an application board. Details of In-System Programming can be found in application note AN466. The 87LPC768 contains three signature bytes that can be read and used by an EPROM programming system to identify the device. The signature bytes designate the device as an 87LPC768 manufactured by Philips. The signature bytes may be read by the user program at addresses FC30h, FC31h and FC60h with the MOVC instruction, using the DPTR register for addressing. A special user data area is also available for access via the MOVC instruction at addresses FCE0h through FCFFh. This "customer code" space is programmed in the same manner as the main code EPROM and may be used to store a serial number, manufacturing date, or other application information.
32-Byte Customer Code Space A small supplemental EPROM space is reserved for use by the customer in order to identify code revisions, store checksums, add a serial number to each device, or any other desired use. This area exists in the code memory space from addresses FCE0h through FCFFh. Code execution from this space is not supported, but it may be read as data through the use of the MOVC instruction with the appropriate addresses. The memory may be programmed at the same time as the rest of the code memory and UCFG bytes are programmed. System Configuration Bytes A number of user configurable features of the 87LPC768 must be defined at power up and therefore cannot be set by the program after start of execution. Those features are configured through the use of two EPROM bytes that are programmed in the same manner as the EPROM program space. The contents of the two configuration bytes, UCFG1 and UCFG2, are shown in Figures 39 and 40. The values of these bytes may be read by the program through the use of the MOVX instruction at the addresses shown in the figure.
UCFG1
Address: FD00h 7 WDTE 6 RPD 5 PRHI 4 BOV 3 CLKR 2 FOSC2 1 FOSC1 0
Unprogrammed Value: FFh
FOSC0
BIT UCFG1.7 UCFG1.6 UCFG1.5 UCFG1.4 UCFG1.3
SYMBOL WDTE RPD PRHI BOV CLKR
FUNCTION Watchdog timer enable. When programmed (0), disables the watchdog timer. The timer may still be used to generate an interrupt. Reset pin disable. When 1 disables the reset function of pin P1.5, allowing it to be used as an input only port pin. Port reset high. When 1, ports reset to a high state. When 0, ports reset to a low state. Brownout voltage select. When 1, the brownout detect voltage is 2.5V. When 0, the brownout detect voltage is 3.8V. This is described in the Power Monitoring Functions section. Clock rate select. When 0, the CPU clock rate is divided by 2. This results in machine cycles taking 12 CPU clocks to complete as in the standard 80C51. For full backward compatibility, this division applies to peripheral timing as well. CPU oscillator type select. See Oscillator section for additional information. Combinations other than those shown below should not be used. They are reserved for future use. Oscillator Configuration External clock input on X1 (default setting for an unprogrammed part). Internal RC oscillator, 6 MHz 25%. Low frequency crystal, 20 kHz to 100 kHz. Medium frequency crystal or resonator, 100 kHz to 4 MHz. High frequency crystal or resonator, 4 MHz to 20 MHz.
SU01185
UCFG1.2-0 FOSC2-FSOC0 FOSC2-FOSC0 111 011 010 001 000
Figure 39. EPROM System Configuration Byte 1 (UCFG1)
2001 Aug 06
52
Philips Semiconductors
Preliminary data
Low power, low price, low pin count (20 pin) microcontroller with 4 kB OTP 8-bit A/D, Pulse Width Modulator
87LPC768
UCFG2
Address: FD01h 7 SB2 6 SB1 5 -- 4 -- 3 -- 2 -- 1 -- 0 --
Unprogrammed Value: FFh
BIT UCFG2.7, 6 UCFG2.5-0
SYMBOL SB2, SB1 --
FUNCTION EPROM security bits. See table entitled, "EPROM Security Bits" for details. Reserved for future use.
SU01186
Figure 40. EPROM System Configuration Byte 2 (UCFG2) Security Bits When neither of the security bits are programmed, the code in the EPROM can be verified. When only security bit 1 is programmed, all further programming of the EPROM is disabled. At that point, only security bit 2 may still be programmed. When both security bits are programmed, EPROM verify is also disabled.
Table 13. EPROM Security Bits
SB2 1 1 0 0 SB1 1 0 1 0 Protection Description Both security bits unprogrammed. No program security features enabled. EPROM is programmable and verifiable. Only security bit 1 programmed. Further EPROM programming is disabled. Security bit 2 may still be programmed. Only security bit 2 programmed. This combination is not supported. Both security bits programmed. All EPROM verification and programming are disabled.
ABSOLUTE MAXIMUM RATINGS
PARAMETER Operating temperature under bias Storage temperature range Voltage on RST/VPP pin to VSS Voltage on any other pin to VSS Maximum IOL per I/O pin Power dissipation (based on package heat transfer, not device power consumption) RATING -55 to +125 -65 to +150 0 to +11.0 -0.5 to VDD+0.5V 20 1.5 UNIT C C V V mA W
NOTES: 1. Stresses above those listed under Absolute Maximum Ratings may cause permanent damage to the device. This is a stress rating only and functional operation of the device at these or any conditions other than those described in the AC and DC Electrical Characteristics section of this specification are not implied. 2. This product includes circuitry specifically designed for the protection of its internal devices from the damaging effects of excessive static charge. Nonetheless, it is suggested that conventional precautions be taken to avoid applying greater than the rated maximum. 3. Parameters are valid over operating temperature range unless otherwise specified. All voltages are with respect to VSS unless otherwise noted.
2001 Aug 06
53
Philips Semiconductors
Preliminary data
Low power, low price, low pin count (20 pin) microcontroller with 4 kB OTP 8-bit A/D, Pulse Width Modulator
87LPC768
DC ELECTRICAL CHARACTERISTICS
VDD = 2.7 V to 6.0 V unless otherwise specified; Tamb = 0C to +70C or -40C to +85C, unless otherwise specified. SYMBOL IDD IID IPD VRAM VIL VIL1 VIH VIH1 HYS VOL VOL1 VO OH VOH1 CIO IIL ILI ITL RRST VBO2.5 VBO3.8 VREF tC (VREF) SS PARAMETER Power supply current operating current, Power supply current, Idle mode current Power supply current Power Down mode current, RAM keep-alive voltage Input low voltage (TTL input) Negative going threshold (Schmitt input) Input high voltage (TTL input) Positive going threshold (Schmitt input) Hysteresis voltage Output low voltage all ports5, 9 Output low voltage all ports5, 9 Output high voltage, all ports3 voltage Output high voltage, all ports4 IOL = 3.2 mA, VDD = 2.7 V IOL = 20 mA, VDD = 2.7 V IOH = -20 A, VDD = 2.7 V IOH = -30 A, VDD = 4.5 V IOH = -1.0 mA, VDD = 2.7 V VIN = 0.4 V VIN = VIL or VIH VIN = 1.5 V at VDD = 3.0 V VIN = 2.0 V at VDD = 5.5 V Tamb = 0C to +70C -30 -150 40 2.45 3.45 1.11 2.5 3.8 1.26 tbd tbd VDD-0.7 VDD-0.7 VDD-0.7 15 -50 2 -250 -650 225 2.65 3.90 1.41 4.0 V < VDD < 6.0 V 2.7 V < VDD < 4.0 V TEST CONDITIONS 5.0 V, 20 MHz11 3.0 V, 10 MHz11 5.0 V, 20 MHz11 3.0 V, 10 MHz11 5.0 V11 3.0 V11 1.5 -0.5 -0.5 -0.5 VDD 0.2 VDD+0.9 0.7 VDD 0.6 VDD 0.2 VDD 0.4 1.0 0.4 VDD 0.2 VDD-0.1 0.7 0.3 VDD VDD+0.5 VDD+0.5 LIMITS MIN TYP1 15 4 6 2 1 1 MAX 25 7 10 4 10 5 UNIT mA mA mA mA A A V V V V V V V V V V V V pF A A A A k V V V ppm/C %/V
Input/Output pin capacitance10 Logical 0 input current, all ports8 Input leakage current, all ports7 Logical 1 to 0 transition current, all ports3, 6 current Internal reset pull-up resistor Brownout trip voltage with BOV = 112 Brownout trip voltage with BOV = 0 Bandgap reference voltage Bandgap temperature coefficient Bandgap supply sensitivity
NOTES: 1. Typical ratings are not guaranteed. The values listed are at room temperature, 5 V. 2. See other Figures for details. Active mode: ICC(MAX) = tbd Idle mode: ICC(MAX) = tbd 3. Ports in quasi-bidirectional mode with weak pull-up (applies to all port pins with pull-ups). Does not apply to open drain pins. 4. Ports in PUSH-PULL mode. Does not apply to open drain pins. 5. In all output modes except high impedance mode. 6. Port pins source a transition current when used in quasi-bidirectional mode and externally driven from 1 to 0. This current is highest when VIN is approximately 2 V. 7. Measured with port in high impedance mode. Parameter is guaranteed but not tested at cold temperature. 8. Measured with port in quasi-bidirectional mode. 9. Under steady state (non-transient) conditions, IOL must be externally limited as follows: 20 mA Maximum IOL per port pin: Maximum total IOL for all outputs: 80 mA Maximum total IOH for all outputs: 5 mA If IOL exceeds the test condition, VOL may exceed the related specification. Pins are not guaranteed to sink current greater than the listed test conditions. 10. Pin capacitance is characterized but not tested. 11. The IDD, IID, and IPD specifications are measured using an external clock with the following functions disabled: comparators, brownout detect, and watchdog timer. For VDD = 3 V, LPEP = 1. Refer to the appropriate figures on the following pages for additional current drawn by each of these functions and detailed graphs for other frequency and voltage combinations. 12. Devices initially operating at VDD = 2.7V or above and at fOSC = 10 MHz or less are guaranteed to continue to execute instructions correctly at the brownout trip point. Initial power-on operation below VDD = 2.7 V is not guaranteed.
2001 Aug 06
54
Philips Semiconductors
Preliminary data
Low power, low price, low pin count (20 pin) microcontroller with 4 kB OTP 8-bit A/D, Pulse Width Modulator
87LPC768
COMPARATOR ELECTRICAL CHARACTERISTICS
VDD = 3.0 V to 6.0 V unless otherwise specified; Tamb = 0C to +70C or -40C to +85C, unless otherwise specified SYMBOL VIO VCR CMRR PARAMETER Offset voltage comparator inputs1 Common mode range comparator inputs Common mode rejection ratio1 Response time Comparator enable to output valid IIL Input leakage current, comparator 0 < VIN < VDD NOTE: 1. This parameter is guaranteed by characterization, but not tested in production. 250 0 TEST CONDITIONS LIMITS MIN TYP MAX 10 VDD-0.3 -50 500 10 10 UNIT mV V dB ns s A
A/D CONVERTER DC ELECTRICAL CHARACTERISTICS
Vdd = 3.0V to 6.0V unless otherwise specified; Tamb = 0 to +70C for commercial, -40C to +85C for industrial, unless otherwise specified. SYMBOL AVIN RREF CIA DLe ILe OSe Ge Ae MCTC Ct PARAMETER Analog input voltage Resistance between VDD and VSS Analog input capacitance Differential non-linearity1,2,3 Integral non-linearity1,4 Offset error1,5 Gain error1,6 Absolute voltage error1,7 Channel-to-channel matching Crosstalk between inputs of port8 Input slew rate 0 - 100kHz A/D enabled TEST CONDITIONS LIMITS MIN VSS - 0.2 tbd MAX VDD + 0.2 tbd 15 1 1 2 1 1 1 -60 100 UNIT V k pF LSB LSB LSB % LSB LSB dB V/ms
Input source impedance 10 k NOTES: 1. Conditions: VSS = 0V; VDD = 5.12V. 2. The A/D is monotonic, there are no missing codes 3. The differential non-linearity (DLe) is the difference between the actual step width and the ideal step width. See Figure 41. 4. The integral non-linearity (ILe) is the peak difference between the center of the steps of the actual and the ideal transfer curve after appropriate adjustment of gain and offset errors. See Figure 41. 5. The offset error (OSe) is the absolute difference between the straight line which fits the actual transfer curve (after removing gain error), and the straight line which fits the ideal transfer curve. See Figure 41. 6. The gain error (Ge) is the relative difference in percent between the straight line fitting the actual transfer curve (after removing offset error), and the straight line which fits the ideal transfer curve. Gain error is constant at every point on the transfer curve. See Figure 41. 7. The absolute voltage error (Ae) is the maximum difference between the center of the steps of the actual transfer curve of the non-calibrated ADC and the ideal transfer curve. 8. This should be considered when both analog and digital signals are input simultaneously to A/D pins. 9. Changing the input voltage faster than this may cause erroneous readings. 10. A source impedance higher than this driving an A/D input may result in loss of precision and erroneous readings.
2001 Aug 06
55
Philips Semiconductors
Preliminary data
Low power, low price, low pin count (20 pin) microcontroller with 4 kB OTP 8-bit A/D, Pulse Width Modulator
87LPC768
Offset error OSe 255
Gain error Ge
254
253
252
251
250
(2)
7 Code Out 6 (1)
5 (5) 4 (4) 3 (3) 2
1
1 LSB (ideal)
0 1 2 3 4 5 6 7 AVIN (LSBideal) Offset error OSe 1 LSB = 250 251 252 253 254 255 256
VDD - VSS 256
(1) Example of an actual transfer curve. (2) The ideal transfer curve. (3) Differential non-linearity (DLe). (4) Integral non-linearity (ILe). (5) Center of a step of the actual transfer curve.
Figure 41. A/D Conversion Characteristics
SU01355
2001 Aug 06
56
Philips Semiconductors
Preliminary data
Low power, low price, low pin count (20 pin) microcontroller with 4 kB OTP 8-bit A/D, Pulse Width Modulator
87LPC768
AC ELECTRICAL CHARACTERISTICS
Tamb = 0C to +70C or -40C to +85C, VDD = 2.7 V to 6.0 V unless otherwise specified, VSS = 0 V1, 2, 3 SYMBOL FIGURE PARAMETER LIMITS MIN 0 0 1/fC 20 20 6tC 5tC - 133 1tC - 80 5tC - 133 0 MAX 20 10 UNIT
External Clock fC fC tC tCHCX tCLCX Shift Register tXLXL tQVXH tXHQX tXHDV tXHDX 42 42 42 42 42 Serial port clock cycle time Output data setup to clock rising edge Output data hold after clock rising edge Input data setup to clock rising edge Input data hold after clock rising edge ns ns ns ns ns 43 43 43 43 43 Oscillator frequency (VDD = 4.5 V to 6.0 V) Oscillator frequency (VDD = 2.7 V to 6.0 V) Clock period and CPU timing cycle Clock high-time4 Clock low time4 MHz MHz ns ns ns
NOTES: 1. Parameters are valid over operating temperature range unless otherwise specified. 2. Load capacitance for all outputs = 80 pF. 3. Parts are guaranteed to operate down to 0 Hz. 4. Applies only to an external clock source, not when a crystal is connected to the X1 and X2 pins.
2001 Aug 06
57
Philips Semiconductors
Preliminary data
Low power, low price, low pin count (20 pin) microcontroller with 4 kB OTP 8-bit A/D, Pulse Width Modulator
87LPC768
tXLXL CLOCK tXHQX tQVXH OUTPUT DATA
0
WRITE TO SBUF tXHDV INPUT DATA VALID CLEAR RI
1
tXHDX
2
3
4
5
6
7
SET TI
VALID
VALID
VALID
VALID
VALID
VALID
VALID
SET RI
SU01187
Figure 42. Shift Register Mode Timing
VDD - 0.5 0.2VDD + 0.9 0.2 VDD - 0.1 0.45V tCHCX
tCHCL
tCLCX
tCLCH
tC
SU01188
Figure 43. External Clock Timing
100
1000
Idd (uA)
Idd (uA)
6.0 V 5.0 V 10 4.0 V 3.3 V 2.7 V
6.0 V 5.0 V 100 4.0 V 3.3 V 2.7 V
1 10 Frequency (kHz) 100
10 100 1,000 Frequency (kHz) 10,000
SU01202
SU01203
Figure 44. Typical low frequency oscillator Idd at 25C (See Note 1)
Figure 45. Typical medium frequency oscillator Idd at 25C (See Note 1)
2001 Aug 06
58
Philips Semiconductors
Preliminary data
Low power, low price, low pin count (20 pin) microcontroller with 4 kB OTP 8-bit A/D, Pulse Width Modulator
87LPC768
10,000 10,000 4.0 V 3.3 V 6.0 V 5.0 V Idd (uA) 1,000 4.0 V 3.3 V 2.7 V 1,000 2.7 V Idd (uA) 100
10
100 1 10 Frequency (MHz) 100
1 10 100 1,000 Frequency (kHz) 10,000
SU01204
SU01207
Figure 46. Typical high frequency oscillator Idd versus frequency at 25C (See Note 1)
Figure 49. Typical Idle Idd versus frequency (external clock, 25C, LPEP=1)
100,000 6.0 V 10,000 Idd (uA) 5.0 V 4.0 V 3.3 V 1,000
10,000 6.0 V 1,000 Idd (uA)
5.0 V 4.0 V
3.3 V
2.7 V
2.7 V 100
100
10 10 100 1,000 Frequency (kHz) 10,000 100,000
10 10 100 1,000 Frequency (kHz) 10,000 100,000
SU01205
SU01208
Figure 47. Typical Active Idd versus frequency (external clock, 25C, LPEP=0)
4.0 V 3.3 V
Figure 50. Typical Idle Idd versus frequency (external clock, 25C, LPEP=0) NOTE: 1. Total Idd at sum of oscillator current and active or idle current shown in Figures 47, 48, 49 or 50 as appropriate
10,000
1,000
2.7 V
Idd (uA)
100
10
1 10
100 Frequency (kHz)
1,000
10,000
SU01206
Figure 48. Typical Active Idd versus frequency (external clock, 25C, LPEP=1)
2001 Aug 06
59
Philips Semiconductors
Preliminary data
Low power, low price, low pin count (20 pin) microcontroller with 4 kB OTP 8-bit A/D, Pulse Width Modulator
87LPC768
DIP20: plastic dual in-line package; 20 leads (300 mil)
SOT146-1
2001 Aug 06
60
Philips Semiconductors
Preliminary data
Low power, low price, low pin count (20 pin) microcontroller with 4 kB OTP 8-bit A/D, Pulse Width Modulator
87LPC768
SO20: plastic small outline package; 20 leads; body width 7.5 mm
SOT163-1
2001 Aug 06
61
Philips Semiconductors
Preliminary data
Low power, low price, low pin count (20 pin) microcontroller with 4 kB OTP 8-bit A/D, Pulse Width Modulator
87LPC768
Purchase of Philips I2C components conveys a license under the Philips' I2C patent to use the components in the I2C system provided the system conforms to the I2C specifications defined by Philips. This specification can be ordered using the code 9398 393 40011.
Data sheet status
Data sheet status [1] Objective data Preliminary data Product status [2] Development Qualification Definitions This data sheet contains data from the objective specification for product development. Philips Semiconductors reserves the right to change the specification in any manner without notice. This data sheet contains data from the preliminary specification. Supplementary data will be published at a later date. Philips Semiconductors reserves the right to change the specification without notice, in order to improve the design and supply the best possible product. This data sheet contains data from the product specification. Philips Semiconductors reserves the right to make changes at any time in order to improve the design, manufacturing and supply. Changes will be communicated according to the Customer Product/Process Change Notification (CPCN) procedure SNW-SQ-650A.
Product data
Production
[1] Please consult the most recently issued data sheet before initiating or completing a design. [2] The product status of the device(s) described in this data sheet may have changed since this data sheet was published. The latest information is available on the Internet at URL http://www.semiconductors.philips.com.
Definitions
Short-form specification -- The data in a short-form specification is extracted from a full data sheet with the same type number and title. For detailed information see the relevant data sheet or data handbook. Limiting values definition -- Limiting values given are in accordance with the Absolute Maximum Rating System (IEC 60134). Stress above one or more of the limiting values may cause permanent damage to the device. These are stress ratings only and operation of the device at these or at any other conditions above those given in the Characteristics sections of the specification is not implied. Exposure to limiting values for extended periods may affect device reliability. Application information -- Applications that are described herein for any of these products are for illustrative purposes only. Philips Semiconductors make no representation or warranty that such applications will be suitable for the specified use without further testing or modification.
Disclaimers
Life support -- These products are not designed for use in life support appliances, devices or systems where malfunction of these products can reasonably be expected to result in personal injury. Philips Semiconductors customers using or selling these products for use in such applications do so at their own risk and agree to fully indemnify Philips Semiconductors for any damages resulting from such application. Right to make changes -- Philips Semiconductors reserves the right to make changes, without notice, in the products, including circuits, standard cells, and/or software, described or contained herein in order to improve design and/or performance. Philips Semiconductors assumes no responsibility or liability for the use of any of these products, conveys no license or title under any patent, copyright, or mask work right to these products, and makes no representations or warranties that these products are free from patent, copyright, or mask work right infringement, unless otherwise specified. Philips Semiconductors 811 East Arques Avenue P.O. Box 3409 Sunnyvale, California 94088-3409 Telephone 800-234-7381 (c) Copyright Philips Electronics North America Corporation 2001 All rights reserved. Printed in U.S.A. Date of release: 08-01 Document order number: 9397 750 08661
Philips Semiconductors
2001 Aug 06 62


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