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 MICRF501
Micrel
MICRF501
300MHz to 600MHz RadioWireTM RF Transceiver Final
General Description
The MICRF501 is a single chip tranceiver intended for ISM (Industrial, Scientific and Medical) and SRD (Short Range Device) frequency bands from 300MHz to 600MHz with FSK data rates up to 128k baud. The transmitter consists of a PLL frequency synthesizer and a power amplifier. The frequency synthesizer consists of a voltage-controlled oscillator (VCO), a crystal oscillator, dualmodulus prescaler, programmable frequency dividers and a phase-detector. The loop filter is external for flexibility and can be a simple passive circuit. The VCO is a Colpitts oscillator which requires an external resonator and varactor. FSK modulation can be applied externally to the VCO or the crystal oscillator. The synthesizer has two different N, M and A frequency dividers. FSK modulation can also be implemented by switching between these dividers (max. 2400bps). The lengths of the N and M and A registers are 12, 10 and 6 bits respectively. For all types of FSK modulation, data is entered at the DATAIXO pin (see application circuit). The output power of the power amplifier can be programmed to eight levels. A lock-detect circuit detects when the PLL is in lock. In receive mode the PLL synthesizer generates the local oscillator (LO) signal. The N, M and A values that give the LO frequency are stored in the N0, M0 and A0 registers. The receiver is a zero intermediate frequency (IF) type in order to make channel filtering possible with low-power integrated low-pass filters. The receiver consists of a low noise amplifier (LNA) that drives a quadrature mixer pair. The mixer outputs feed two identical signal channels in phase quadrature. Each channel includes a preamplifier, a third order Sallen-Key RC low pass filter that protects the following gyrator filter from strong adjacent channel signals and finally, a limiter. The main channel filter is a gyrator capacitor implementation of a seven-pole elliptic low pass filter. The elliptic filter minimizes the total capacitance required for a given selectivity and dynamic range. The cut-off frequency of the Sallen-Key RC filter can be programmed to four different frequencies: 10kHz, 30kHz, 60kHz and 200kHz. An external resistor adjusts the cut-off frequency of the gyrator filter. The demodulator demodulates the I and Q channel outputs and produces a digital data output. It detects the relative phase of the I and the Q channel signal. If the I channel signal lags the Q channel, the FSK tone frequency lies above the LO frequency (data `1'). If the I channel leads the Q channel, the FSK tone lies below the LO frequency (data `0'). The output of the receiver is available on the DATAIXO pin. A RSSI (Receive Signal Strength Indicator) circuit indicates the received signal level.
RadioWireTM A two pin serial interface is used to program the circuit. External components are necessary for RF input and output impedance matching and decoupling of power. Other external components are the VCO resonator circuit with varactor, crystal, feedback capacitors and components for FSK modulation with the VCO, loop filter, bias resistors for the power amplifier and gyrator filters. A T/R switch can be implemented with 2-pin diodes. This gives maximum input sensitivity and transmit output power.
Features
* * * * * Frequency range: 300MHz to 600MHz Modulation: FSK RF output power: 12dBm Sensitivity (19.2k bauds, BER=10-3): -105dBm Maximum data rate: 128k bauds
Applications
* * * * * * * Telemetry Remote metering Wireless controller Wireless data repeaters Remote control systems Wireless modem Wireless security system
Ordering Information
Part Number MICRF501BLQ Ambient Temp. Range -40C to +85C Package 44-Lead LQFP
RadioWire is a trademark of Micrel, Inc. Micrel, Inc. * 1849 Fortune Drive * San Jose, CA 95131 * USA * tel + 1 (408) 944-0800 * fax + 1 (408) 944-0970 * http://www.micrel.com
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Pin Configuration
VB_IP QCHC ICHC IFQINN IFQINP MIXQOUTN MIXQOUTP IFIINN IFIINP MIXIOUTN MIXIOUTP
IFGND IFVDD ICHOUT QCHOUT OSCVDD OSCIN OSCGND GND CMPOUT CMPR MOD
1 2 3 4 5 6 7 8 9 10 11
44 43 42 41 40 39 38 37 36 35 34 33 32 31 30 29 28 27 26 25 24 23 12 13 14 15 16 17 18 19 20 21 22
MIXERVDD MIXERGND LNA_C RFGND2 RFIN RFVDD RFGND RFOUT PABIAS PA_C DIGGND
Pin Description
Pin Number 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 Pin Name IFGND IFVDD ICHOUT QCHOUT OSCVDD OSCIN OSCGND GND CMPOUT CMPR MOD XOSCIN XOSCOUT LD_C LOCKDET RSSI PDEXT DATAC DATAIXO CLKIN REGIN DIGVDD DIGGND Pin Function IF Ground IF Power I-Channel Output Q-Channel Output Colpitts Oscillator Power Colpitts Oscillator Input Colpitts Oscillator and Substrate Ground Substrate Ground Charge Cump Output Charge Pump Resistor Input Output for VCO Modulation Crystal Oscillator Input Crystal Oscillator Output External Capacitor for Lock Detector Lock Detector Output Received Signal Strength Indicator Output Power Down Input (0=Power Down) Data Filter Capacitor Data Input/Output Clock Input for Programming Data Input for Programming Digital Circuitry Power Digital Circuitry Ground
MICRF501
XOSCIN XOSCOUT LD_C LOCKDET RSSI PDEXT DATAC DATAIXO CLKIN REGIN DIGVDD
44-Pin LQFP (BLQ)
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Pin Description, cont'd
Pin Number 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 Pin Name PA_C PABIAS RFOUT RFGND RFVDD RFIN RFGND2 LNA_C MIXERGND MIXERVDD MIXIOUTP MIXIOUTN IFIINP IFIIN MIXQOUTP MIXQOUTN IFQINP IFQINN ICHC QCHC VB_IP Pin Function Capacitor for Slow Ramp Up/Down of PA External Bias Resistor for Power Amplifier Power Amplifier Output LNA, PA and Substrate Ground LNA and PA Power Low Noise RF Amplifier (LNA) Input LNA First Stage Ground External LNA Stabilizing Capacitor Mixer Ground Mixer Power I-Channel Mixer Positive Output I-Channel Mixer Negative Output I-Channel IF Amplifier Positive Input I-Channel IF Amplifier Negative Input Q-Channel Mixer Positive Output Q-Channel Mixer Negative Output Q-Channel IF Amplifier Positive Input Q-Channel IF Amplifier Negative Input I-Channel Amplifier Capacitor Q-channel Amplifier Capacitor Gyrator Filter Resistor
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Absolute Maximum Ratings (Note 1)
Maximum Supply Voltage (VDD) ................................... +7V Maximum NPN Reverse Base-emitter Voltage .......... +2.5V Storage Temperature Range (TS) ............ -55C to +150C ESD Rating, Note 3 ................................................. 500mV
Operating Ratings (Note 2)
Supply Voltage (VIN) ................................... +2.5V to +3.4V Ambient Temperature (TA) ......................... -40C to +85C Package Thermal Resistance TQFP(JA)-Multilayer Board ............................. 46.3C/W
Electrical Characteristics
FREF = 850MHz, VDD = 2.5 to 3.4V, TA = 25C, unless otherwise specified. Parameter Overall Operating Frequency Power Down Current Logic High Input, VIH Logic Low Input, VIL DATAIXO, Logic High Output (VOH) DATAIXO, Logic Low Output (VOL) LockDet, Logic High Output (VOH) LockDet, Logic Low Output (VOL) Clock/Data Frequency Clock/Data Duty-Cycle Data Setup to Clock (rising edge) VCO and PLL Section Prescaler Divide Ratio Reference Frequency PLL Lock Time (int. modulation) PLL Lock Time (ext. modulation) Rx - (Tx with PA on) Switch Time Charge Pump Current Transmit Section Output Power Transmit Data Rate (ext. modulation) Note 4 Transmit Data Rate (int. modulation) Note 5 Frequency Deviation to Modulation Rate Ratio Current Consumption Transmit Mode unfiltered FSK 10 dBm, RLOAD = 50 1.0 1.5 45 mA fOUT = 434MHz RLOAD = 50, VDD = 3.0V 12 128 2.4 dBm kbauds kbauds 4kHz loop filter bandwidth 1kHz loop filter bandwidth 1kHz loop filter bandwidth 1 4 2 95/380 125/500 155/620 32/33 40 MHz ms ms ms A 25 25 IOH = -500A IOL = 500A IOH = -100A IOL = 100A VDD-0.25 0.25 10 75 VDD-0.3 0.3 70% 30% 300 434 <1 600 2 MHz A VDD VDD V V V V MHz % ns Condition Min Typ Max Units
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Parameter Receive Section Receiver Sensitivity (Note 6) Input 1dB Compression Level Input IP3 Input Impedance RSSI Dynamic Range RSSI Output Voltage Adjacent Channel Rejection: fC = 10kHz fC = 30kHz fC = 60kHz fC = 200kHz Blocking Immunity (1MHz) PIN = -100dBm PIN = -30dBm 25kHz channel spacing 100kHz channel spacing 200kHz channel spacing 700kHz channel spacing RC filter: RC filter: RC filter: RC filter: fC = 10kHz fC = 30kHz fC = 60kHz fC = 200kHz Condition fIN = 434MHz BER=10-3 -1056 -41 -31 26-j77 60 0.7 2.1 27 33 45 TBD 63 57 57 TBD 175 1 gyrator filter fC = 60kHz 8 300 11 Min Typ Max
Micrel
Units
dBm dBm dBm dB V V dB dB dB dB dB dB dB kHz ms mA A
Maximum Receiver Bandwidth Receiver Settling Time Current Consumption Receive Mode Current Consumption XCO
Note 1. Note 2. Note 3. Note 4. Exceeding the absolute maximum rating may damage the device. The device is not guaranteed to function outside its operating rating. Devices are ESD sensitive. Handling precautions recommended. Human body model, 1.5k in series with 100pF.
Modulation is applied to the VCO and therefore the modulation cannot have any DC component. Some kind of coding is needed to ensure that the modulation is DC free, e.g., Manchester code or block code. With Manchester code the bitrate is half the baudrate, but with 3B4B block code the bitrate is _ of the baudrate. Bitrate is the same as the baudrate. Measured at 19.2k bauds and frequency deviation 25kHz (external modulation), jitter of received data: < 45%.
Note 5: Note 6:
Output Power vs. Current @ 25C
15 10 5 dBm 0 -5 -10 -15 -20 0 5 10 15 20 25 30 35 40 45 ITOT (mA)
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Functional Diagram
33
32
31
30
29
28
27
26
25
24
23
34
LNA PA
22
35 90 36
Prescaler 32/33
C o n t r Logic o l
Control
21
20
37 A1/A0 38 A-counter
39 RC Filters Gyrator Filters R S S I
N1/N0 N-counter
I n t e r f a c e
19
18
17
40
16
41
M-counter M1/M0
15
42 LD 43 VCO Demod 44 1 2 3 4 5 6 7 8
Phase Detector
14
13 Charge Pump XCO 12 9 10 11
Figure 1. Transceiver Internal Blocks
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Typical Application
Figure 3 shows an example of a transceiver with modulation applied to the VCO. The inductors and trimming capacitors must have a good high frequency performance. The varactor MA4ST-350-1141 is a single variable capacitance diode manufactured by MACOM. The pin diode MA-4P789-1141 is manufactured by MACOM.
C7 4.7n
C8 4.7n C9 1n
C10 1n C11 1n
C12 1n VDD
36 35 34
R6 8.2k
44 43 42
VDD R4 10 C30 47p
41
40
39
38
37
VDD
R1 10
1
R5 10
MIXER VDD MIXER GND LNA_C
VB_IP
QCHC
ICHC
IFQINN
IFQINP
MIXQOUTN
MIXQOUTP
IFIINN
IFIINP
MIXIOUTN
MIXIOUTP
IFGND IFVDD ICHOUT QCHOUT OSCVDD OSCIN OSCGND GND CMPOUT
33
C1 1n R2 10 C2 100p R7 3.6k C13 15p IchOut QchOut
C5 100p C26 10n C27 22p
2
32
C28 6.8p L2 15n ant-switch D2 MA4P-789-1141
3 4
31 30
VDD
RFGND2 RFIN
5
29
6
L1 47n
MICRF501 44-pin LQFP
RFVDD RFGND RFOUT PABIAS PA_C
28
C29 18p R14 1k C25 470p L4 68n C31 15p L5 10n C32 2.2p C4 100p
L3 47n
ANT
7
27 26
C16 100n C35 2.2p D1 MA4ST350 R8 47k R13 C15 270k 6.8n C19 470p R11 150k R9 8.2k R10 8.2k
8
C34 47p D3 MA4P789-1141
9
25
CMPR
10
24
MOD
11
DIGGND
23
XOSCOUT
LOCKDET
C33 5.6p
R15 3.6k VDD
DIGVDD
DATAIX0
XOSCIN
PDEXT
REGIN
DATAC
CLKIN
LD_C
RSSI
C36 1n C18 100n C17 470p
12
13
14
15
16
17
18
19
20
21
22
C21 5.6p 10MHz C22 47p
C23 1n
R12 3.3k
R16 1k
Lock Det C20 2p-6p C24 1n RSSI
R3 10
C3 1n
Figure 3. Application Circuit
PDEXT
DATAIX0
CLKIN
REGIN VDD
C6 100p VDD
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List of components
Component R1 R2 R3 R4 R5 R6 R7 R8 R9 R10 R11 R12 R13 R14 R15 R16 C1 C2 C4 C5 Values 10 10 10 10 10 8.2k 3.6k 47k 8.2k 8.2k 150k 3.3k 270k 1k 3.6k 1k 1nF 100pF 100pF 100pF Component C6 C8 C9 C10 C11 C12 C13 C15 C16 C17 C18 C19 C20 C21 C22 C23 C24 C25 C26 C27 Values 100pF 4.7nF 1nF 1nF 1nF 1nF 15pF 6.8nF 100nF 470pF 100nF 470pF 2pF-6pF 5.6pF 47pF 1nF 1nF 470pF 10nF 22pF Component C28 C29 C30 C31 C32 C33 C34 C35 C36 L1 L2 L3 L4 L5 D1 D2 D3 crystal Values 6.8pF 18pF 47pF 15pF 2.2pF 5.6pF 47pF 2.2pF 1nF 47nH 15nH 47nH 47nH 10nH
Micrel
MA4ST-350-1141 MA4P-789 MA4P-789 10MHz
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DIFVDD
Applications Information
VCO and PLL Section The frequency synthesizer consists of a VCO, crystal oscillator, dual-modulus prescaler, programmable frequency dividers, phase-detector, charge pump, lock detector and an external loop filter. The dual-modulus prescaler divides the VCO-frequency by 32/33. This mode is controlled by the Adivider. There are two sets of M, N and A-frequency dividers. Using both sets in transmit mode, FSK can be implemented by switching between those two sets. The phase-detector is a frequency/phase detector with back slash pulses to minimize phase noise. The VCO, crystal oscillator, charge pump, lock detector and the loop filter will be described in detail below. Voltage Controlled Oscillator (VCO)
VDD Pin 5 R7 3.6k Pin 6
C36 1n C22 5.6p
Pin 12
C20 2-6p 10MHz
Pin 13 C21 47p DIGGND
XOSCOUT
Figure 4. Crystal Oscillator The crystal oscillator is tuned by varying the trimming capacitor C20. The drift of the RF frequency is the same as the drift of crystal frequency when measured in ppm. The total difference in ppm, f(ppm), between the tuned RF frequency and the drifted frequency is given by: f(ppm) = ST x T + n x t where: * ST is the total temperature coefficient of the oscillator frequency (due to crystal and components) in ppmC. * T is the change in temperature from room temperature, at which the crystal was tuned. * n is the ageing in ppm/year. * t is the time (in years) elapsed since the transceiver was last tuned. The demodulator will not be able to decode data when f(Hz) = f(ppm) x fRF is larger than the FSK frequency deviation. For small frequency deviations, the crystal should be pre-aged, and should have a small temperature coefficient. The circuit has been tested with a 10MHz crystal, but other crystal frequencies can be used as well. The circuit has been tested with a 10MHz crystal, but other crystal frequencies can be used as well.
Prestart of XCO
loopfilter_output R8 47k D1 MA4ST350
L1 47nH C35 2.2p
C13 15p
OSCOUT
Pin 7
Figure 3. VCO The circuit schematic of the VCO with external components is shown in Figure 3. The VCO is basically a Colpitts oscillator. The oscillator has an external resonator and varactor. The resonator consists of inductor L1 and the series connection of capacitor C13, the internal capacitance, the capacitance of the varactor and C35 in parallel with D1. The capacitance of the varactor (D1) decreases as the input voltage increases. The VCO frequency will therefore increase as the input voltage increases. The VCO has a positive gain (MHz/Volt). C35 is added, if necessary, to bring VCO tuning voltage to its middle range or VCC/2, which is measured at Pin 9 - CMPOUT. If the value of capacitor C13 and C14 become too small the amplitude of the VCO signal decreases, which leads to lower output power. The layout of the VCO is very critical. The external components should be placed as close to the input pin (Pin 6) as possible. The anode of the varactor D1 must be placed next to pins 7 and 8. Ground vias should be next to component pads. Crystal Oscillator The crystal oscillator is the reference for the RF output frequency as well as for the LO frequency in the receiver. The crystal oscillator is a very critical block since very good phase and frequency stability is required. The schematic of the crystal oscillator with external components for 10MHz is shown in Figure 4. These components are optimized for a crystal with 15pF load capacitance.
The start-up time of a crystal oscillator is typically some milliseconds. Therefore, to save current consumption, the MICRF501 circuit has been designed so that the XCO is turned on before any other circuit block. During start-up the XCO amplitude will eventually reach a sufficient level to trigger the M-counter. After counting two M-counter output pulses the rest of the circuit will be turned on. The current consumption during the prestart period is approximately 300A. Lock Detector The MICRF501 circuit has a lock detector feature that indicates whether the PLL is in lock or not. A logic high on Pin 15 (LOCKDET) means that the PLL is in lock. The phase detector output is converted into a voltage that is filtered by the external capacitor C23, connected to Pin 14, LDC. The resulting DC voltage is compared to a reference window set by bits Ref0 - Ref5. The reference window can be stepped up/down linearly between 0V, Ref0 - Ref5 =1, and Ref0 - Ref5 = 0, which gives the highest value (DC voltage) of the reference window. The size of the window can either be
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equal to two (Ref6 = 1) reference steps or four reference steps (Ref6 = 0). The bit setting that corresponds to lock can vary, depending on temperature, loop filter and type of varactor. Therefore, the lock detect circuit needs to be calibrated regularly by a software routine that finds the correct bit setting, by running through all combinations of bits Ref0 - Ref5. Depending on the size of the reference window, there will be several bit combinations that show lock. For instance, with a large reference window, as much as five bit combinations can make the lock detector show lock. To have the maximum robustness to noise, the third of the bit settings should be chosen. Charge Pump The charge pump can be programmed to four different modes with two currents, 125A and 500A. Bits 70 and 71 in the control word (cpmp1 and cpmp0) controls the operation. The four modes are: 1. cpmp1 = 0 Current is constant 125A. Used in cpmp0 = 0 applications where short PLL lock time is not important. 2. cpmp1 = 0 Current is constant 500A. Used in cpmp0 = 1 applications where a short PLL lock time is important, e.g., internal modulation. See "Modulation Inside PLL" section. 3. cpmp1 = 1 Current is 500A when PLL is out of cpmp0 = 0 lock and 125A when it is in lock. Controlled by LOCKDET (Pin 15). Lock time is halved. See "Modulation Outside PLL" section. 4. cpmp1 = 1 Same as above in Tx. In Rx the current cpmp0 = 1 is 500A. Used when using dual-loop filters. See "Modulation Outside PLL Dual-Loop Filters" section. Tuning of VCO and XCO There are two circuit blocks that may need tuning, the VCO and the crystal oscillator.
VCO Tuning
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very close to the desired frequency. Because of the small tuning range the VCO will not go out of lock when tuning the crystal oscillator. FSK Modulation The circuit has two sets of frequency dividers A0, N0, M0 and A1, N1, M1. The frequency dividers are programmed via the control word. A0, N0, M0 are to be programmed with the receive frequency and are used in receive mode. There are three ways of implementing FSK: * FSK modulation can be applied to the VCO. This way of implementing FSK modulation is explained more in detail in the next section. The values corresponding to the transmit frequency should be programmed in dividers A1, N1 and M1. Pin DATAIXO must be kept in tri-state from the time Tx-mode is entered until one starts sending data. * FSK modulation can be applied to the crystal oscillator. A, N and M values corresponding to the receive frequency and the low transmit frequency have to be found. The values corresponding to the low transmit frequency should be programmed in dividers A1, N1 and M1. In transmit mode, set DataIXO=`1' and tune the trimming capacitor until the output frequency that corresponds to data `1' is reached. Check that the output frequency equals the low FSK frequency when DataIXO=`0'. * FSK modulation by switching between the two sets of A, N and M dividers. A, N and M values corresponding to the receive frequency and both transmit frequencies have to be found. In transmit the values corresponding to data `0' should be programmed in dividers A0, N0 and M0, and the values corresponding to data `1' should be programmed in dividers A1, N1 and M1. * FSK modulation by adding/subtracting 1 to divider A1. The frequency deviation will be equal to the comparison frequency. The values corresponding to the transmit frequency should be programmed in dividers A1, N1 and M1. For all types of FSK modulation, data is entered at the DATAIXO pin. Loop Filter The design of the loop filter is of great importance for optimizing parameters like modulation rate, PLL lock time, bandwidth and phase noise. Low bitrates will allow modulation inside the PLL, which means the loop will lock on different frequency for 1s and 0s. This can be implemented by switching the internal dividers (M, N and A), or by pulling the reference frequency (XCO-modulation). Higher modulation rates (above 2400bps) imply implementation of modulation outside the PLL. This can be implemented by applying the modulation directly to the VCO. Loop filter values can be found using an appropriate software program. 10 March 2003
When the tuning voltage is not at its mid-point measured at Pin 9, a capacitor value for C35 is chosen. This is particularly important when using VCO modulation. The gain curve of the VCO (MHz/Volt) is not linear and the gain will therefore vary with loop voltage. This means that the FSK frequency deviation also varies with loop voltage. It is therefore important to trim the loop voltage to the same value from circuit to circuit. When using internal modulation, tuning the VCO can be omitted as long as the VCO gain is large enough to allow the PLL to handle variations in process parameters and temperature without going out of lock.
XCO Tuning
Tune the trimming capacitor in the crystal oscillator to the precise desired transmit frequency. It is not possible to tune the crystal oscillator over a large frequency range. N, M and A values must therefore be chosen to give a RF frequency MICRF501
MICRF501
Modulation Inside PLL
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Data rates above approximately 19200baud (including Manchester encoding) can be used with this loop filter without significant tracking of the modulating signal. PLL lock time will be approximately 4ms. If a faster PLL lock time is wanted, the charge pump can be made to deliver a current of 500A per unit phase error, while an open drain NMOS on chip (Pin 10, CmpR) switches in a second damping resistor (R10) to ground as shown in Figure 6. Once locked on the correct frequency, the PLL automatically returns to standard low noise operation (charge pump current: 125A/rad). If correct settings have been made in the control word (cpmp1 = 1, cpmp0 = 0), the fast locking feature is activated and will reduce PLL lock time by a factor of two without affecting the phase margin in the loop. Components C17, C18 C19, R11, R12, R13 and R16 (see application circuit) are necessary if FSK modulation is applied to the VCO. Data entered at the DATAIXO-pin will then be fed through the Mod-pin (Pin 11) which is a current output. The pin sources a current of 50A when Logic 1 is entered at the DATAIXO and drains the current for Logic 0. The capacitance of C17 will set the order of filtering of the baseband signal. A large capacitance will give a slow ramp-up and therefore a high order of filtering of the baseband signal, while a small capacitance gives a fast ramp-up, which in turn also gives a broader frequency spectrum. Resistors R11 and R12 set the frequency deviation. If C18 is large compared to C17, the frequency deviation will be large. R13 should be large to avoid influencing the loop filter. Pin DATAIXO must be kept in tri-state from the time Tx-mode is entered until one starts sending data.
Modulation Outside PLL, Dual-Loop Filters
A fast PLL requires a loop filter with relatively high bandwidth. If a second order loop filter is chosen, it may not give adequate attenuation of the comparison frequency. Therefore in the following example a third order loop filter is chosen. Example 1: Radio frequency fRF 434MHz 100kHz Comparison frequency fC Loop bandwidth BW 4.3kHz VCO gain Ko 28MHz/V Phase comparator gain Kd 500A/rad Phase margin j 62 Breakthrough suppression A 20dB The component values will be:
IN R101 C116 33n C115 1.5n R109 6.2k C103 150p 22k OUT
Figure 5. Third Order Loop Filter With this loop filter, internal modulation up to 2400bps is possible. The PLL lock time from power-down to Rx will be approximately 1ms.
Modulation Outside PLL (Closed Loop)
When modulation is applied outside the PLL, it means that the PLL should not track the changes in the loop due to the modulation signal. A loop filter with relatively low bandwidth is therefore necessary. The exact bandwidth will depend on the actual modulation rate. Because the loop bandwidth will be significantly lower than the comparison frequency, a second order loop filter will normally give adequate attenuation of the comparison frequency. If not, a third order loop filter may give the extra attenuation needed. Example 2: Radio frequency fRF 434MHz Comparison frequency fC 140kHz Loop bandwidth BW 1.03kHz VCO gain Ko 28MHz/V Phase comparator gain Kd Phase margin j The component values will be:
IN C16 100n C15 6.8n R9 8.2k CmpR R10 8.2k
Modulation outside the PLL requires a loop filter with a relatively low bandwidth compared to the modulation rate. This results in a relatively long loop lock time. In applications where modulation is applied to the VCO, but at the same time a short start-up time from power down to receive mode is needed, dual-loop filters can be implemented. Figure 7 shows how to implement dual-loop filters.
CMPOUT Pin9 C16 Pin10 FLC 100n R10 6.2k C15 6.8n C116 33n R109 6.2k C115 1.5n R102 22k C103 150p R8 47k towards_VCO
R9 6.2k
125A/rad 62
DFC
Pin4
OUT
Figure 7. Dual-Loop Filters The loop filter used in transmit mode is made up of C15, C16, R9 and R10. The fast lock feature is also included (internal NMOS controlled by FLC, Fast Lock Control). This filter is automatically switched in/out by an internal NMOS at Pin 4, QchOut, which is controlled by DFC (Dual Filter Control). Bits OutS2, OutS1, OutS0 must be set to 110. When QchOut is used to switch the Tx loop filter to ground, neither QchOut nor IchOut can be used as test pins to look at the different receiver
Figure 6. Second Order Loop Filter
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signals. The receive mode loop filter comprises C115, C116, R109, R101 and C101.
Modulation Outside PLL (Open Loop)
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stabilizes the overall dc feedback loop, which has a large low frequency loop gain. Figure 8 shows the input impedance of the LNA.
In this mode the charge pump output is tri-stated. The loop is open and will therefore not track the modulation. This means that the loop filter can have a relatively high bandwidth, which give short switching times. However, the loop voltage will decrease with time due to current leakage. The transmit time will therefore be limited and is dependent on the bandwidth of the loop filter. High bandwidth gives low capacitor values and the loop voltage will decrease faster, which gives a shorter transmit time. The loop is closed until the PLL is locked on the desired frequency and the power amplifier is turned on. The loop immediately opens when the modulation starts. The loop will not track the modulation, but the modulation still needs to be DC free due to the AC coupling in the modulation network.
Transmit
Power Amplifier (PA) The power amplifier is biased in class AB. The last stage has an open collector, and an external load inductor (L5) is therefore necessary. The DC current in the amplifier is adjusted with an external bias resistor (R14). A good starting point when designing the PA is a 1.5k bias resistor which gives a bias current of approximately 50A. This will give a bias current in the last stage of about 15mA. R14 is optimized to 1k, as shown in the application circuit. The impedance matching circuit will depend on the type of antenna used, but should be designed for maximum output power. For maximum output power the load seen by the PA must be resistive and should be about 100. The output power is programmable in eight steps, with approximately 3dB between each step. This is controlled by bits Pa2 - Pa0. To prevent spurious components from being transmitted the PA should be switched on/off slowly, by allowing the bias current to ramp up/down at a rate determined by the external capacitor C25 connected to Pin 24. The ramp up/down current is typically 1.1A, which makes the on/off rate for a 2.8V power supply 2.6s/pF. Turning the PA on/off affects the PLL. Therefore the on/off rate must be adjusted to the PLL bandwidth. PA Buffer A buffer amplifier is connected between the VCO and the PA to ensure that the input signal of the PA has sufficient amplitude to achieve the desired output power. This buffer can be bypassed by setting the bit Gc to 0. Figure 8. Input Impedance Input matching is very important to get high receive sensitivity. The LNA can be bypassed by setting bit LNA to `1'. This is useful for very strong signal levels. The RSSI signal can be used to drive a microcontroller to create a subroutine when a strong income signal is present to bypass the LNA. This will increase the dynamic range by approximately 25dB. The mixers have a gain of about 15dB at 434MHz. The differential outputs of the mixers are available at Pins 34, 35 and at Pins 38, 39. The output impedance of each mixer is about 30k. Sallen-Key Filter and Preamplifier Each channel includes a preamplifier and a prefilter, which is a three-pole elliptic Sallen-Key lowpass filter with 20dB stopband attenuation. It protects the following gyrator filter from strong adjacent channel signals. The preamplifier has a gain of 35dB and output voltage swing is about 200mVPP. The third order Sallen-Key lowpass filter is programmable to four different cut-off frequencies according to the table below:
Fc1 0 0 1 1 Fc0 0 1 0 1 Cut-Off Frequency (kHz) 10 2.5 30 7.5 60 15 200 50 Recommended Channel Spacing 25kHz 100kHz 200kHz 700kHz
Receive
Front End (LNA and Mixers) A low noise amplifier in the RF receiver is used to boost the incoming signal prior to the frequency conversion process. This is important in order to prevent mixer noise from dominating the overall front end noise performance. The LNA is a two stage amplifier and has a nominal gain of 25dB at 434MHz. The LNA has a dc feedback loop, which provides bias for the LNA. The external capacitor C26 decouples and MICRF501 12
For the 10kHz cut-off frequency the first pole must be generated externally by connecting a 330pF capacitor between the outputs of each mixer. As the cut-off frequency of the gyrator filter can be set by varying an external resistor, the optimum channel spacing will depend on the cut-off frequencies of the Sallen-Key filter. The table above shows the recommended channel spacing depending on the different bit settings.
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MICRF501
Gyrator Filter The main channel filter is a gyrator capacitor implementation of a seven-pole elliptic lowpass filter. The elliptic filter minimizes the total capacitance required for a given selectivity and dynamic range. An external resistor can adjust the cutoff frequency of the gyrator filter. The table below shows how the cut-off frequency varies with bias resistor:
Bias Resistor (k) 6.8 8.2 15 30 47 Cut-Off Frequency (kHz) 70 55 30 14 8
Micrel
Limiter The limiter serves as a zero crossing detector, thus removing amplitude variations in the IF signal, while retaining only the phase variations. The limiter outputs are ideally suited to measure the I-Q phase difference, since its outputs are square waves with sharp edges. Demodulator The demodulator demodulates the I and Q channel outputs and produces a digital data output. It detects the relative phase difference between the I and the Q channel signals. For every edge (positive and negative) of the I channel limiter output, the amplitude of the Q channel limiter output is sampled, and vice versa. The output of the demodulator is available on the DATAIXO pin. The data output is therefore updated 4 times per cycle of the IF signal. This also means that the maximum jitter of the data output is 1/(4xf) (valid only for zero frequency offsets). If the I channel signal lags the Q channel, the FSK tone frequency lies above the LO frequency (data `1'). If the I channel leads the Q channel, the FSK tone lies below the LO frequency (data `0'). The inputs and the output of the demodulator are filtered by first order RC lowpass filters and then amplified by Schmitt triggers to produce clean square waves. It is recommended for low bitrates (<10kbps) that an additional capacitor is connected to Pin 18 (DataC) to decrease the bandwidth of the Rx data signal filter. The bandwidth of the filter must be adjusted for the bitrate. This functionality is controlled by bit RxFilt. Received Signal Strength Indicator (RSSI) The RSSI provides a DC output voltage proportional to the strength of the RF input signal. A graph of a typical RSSI response is shown in Figure 9 (fDEV = 30kHz, Gc = 1).
2.2 2 1.8
The gyrator filter cut-off frequency should be chosen to be approximately the same as the cut-off frequency of the Sallen-Key filter. Cut-Off Frequency Setting The cut-off frequency must be high enough to pass the received signal (frequency deviation + modulation). The minimum cut-off frequency is given by: fC(min) = fDEV + Baudrate/2 For a frequency deviation of fDEV = 30kHz and a baudrate of 20k baud, the minimum cut-off frequency is 40kHz. Bit setting Fc1 = 1 and Fc0 = 0, which gives a cut-off of (60 15) kHz, would be the best choice. The gyrator filter bias resistor should therefore be 7.5k or 8.2 k, to set the gyrator filter cut-off frequency to approximately 60kHz. The crystal tolerance must also be taken into account when selecting the receiver bandwidth. If the crystal has a temperature tolerance of say 10ppm over the total temperature range, the incoming RF signal and the LO signal can theoretically be 20ppm away from each other. The frequency deviation must always be larger than the maximum frequency drift for the demodulator to be able to demodulate the signal. The minimum frequency deviation (fDEVmin) is equal to the baudrate, according to the electrical characteristic's. This means that the frequency deviation has to be at least equal to the baudrate plus the maximum frequency drift. The frequency deviation may therefore vary from the minimum frequency deviation to the minimum frequency deviation plus two times the maximum frequency drift. The minimum cut-off frequency when crystal tolerances are considered is therefore given by: fCmin = f x 2 fDEVmin + Baudrate/2 where f is the maximum frequency drift between the LO signal and the incoming RF signal due to crystal tolerances. A frequency drift of 20ppm is 8680Hz at 434MHz. The frequency deviation must be higher than 28.68kHz for a baudrate of 20k baud. The frequency deviation may then vary from 20kHz, when the RF signal is 20ppm lower than the LO signal; to 37.36kHz when the RF signal is 20ppm higher than the LO signal. The minimum cut-off frequency is therefore 47.36kHz. March 2003 13
VOUT (V)
1.6 1.4 1.2 1 0.8
-90
-80
-70
-60
-50
-40
-30
-110
-100
PIN (dBm)
Figure 9. Typical RSSI Characteristics This graph shows a range of 0.7V to 2.05V over a RF input range of 70dB. The RSSI can be used as a signal presence indicator. When a RF signal is received, the RSSI output increases. This could be used to wake up circuitry that is normally in a sleep mode configuration to conserve battery life. Another application for which the RSSI could be used is to determine if transmit power can be reduced in a system. If the RSSI detects a strong signal, it could tell the transmitter to reduce the transmit power to reduce current consumption.
-20
0.6
MICRF501
MICRF501
Micrel
Programming
A two-line bus is used to program the circuit; the two lines being CLKIN and REGIN. The 2-line serial bus interface allows control over the frequency dividers and the selective powering up of Tx, Rx and Synthesizer circuit blocks. The interface consists of an 80-bit programming register. Data is entered on the REGIN line with the most significant bit first. The first bit entered is called p1, the last one p80. The bits in the programming register are arranged as shown in Table 1.
p1 - p6 A1 p59 Pa1 p67 Ref2 p75 OutS1
p7 - p12 A0 p60 Pa0 p68 Ref1 p76 OutS0
p13 - p24 N1 p61 Gc p69 Ref0 p77 Mod1
p25 - p36 N0 p62 ByLNA p70 Cpmp1 p78 Mod0
p37 - p46 M1 p63 Ref6 p71 Cpmp0 p79 RT
p47 - p56 M0 p64 Ref5 p72 Fc1 p80 Pu
p57 RxFilt p65 Ref4 p73 Fc0 -- --
p58 Pa2 p66 Ref3 p74 OutS2 -- --
Table 1. Bit Allocation
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Name A1 A0 N1 N0 M1 M0 RxFilt Pa2 Pa1 Pa0 Gc ByLNA Ref6 Ref5 Ref4 Ref3 Ref2 Ref1 Ref0 Cpmp1 Cpmp0 charge pump setting: Cpmp1=0, Cpmp0=0 : 125A Cpmp1=0, Cpmp0=1 : 500A Cpmp1=1, Cpmp0=0 : controlled by LockDet (LD) LD=0: 500A, LD=1: 125A Cpmp1=1, Cpmp0=1 : same as previous in Tx. In Rx the current is 500A. Active RC-filter settings Fc1=0, Fc0=0 : 10kHz Fc1=0, Fc0=1 : 30kHz I- and Q-channel output select OutS2 OutS1 0 0 Fc1=1, Fc0=0 : 60kHz Fc1=1, Fc0=1 : 200kHz QchOut high Z OutS2 1 OutS1 0 OutS0 0 IchOut lim_qch all 0's: highest reference all 1's: lowest reference reference settings in lock detector Description frequency divider A1, 6 bits frequency divider A0, 6 bits frequency divider N1, 12 bits frequency divider N0, 12 bits frequency divider M1, 10 bits frequency divider M0, 10 bits 1=external capacitor for filtering of Rx data signal gain setting in power amplifier pa2, pa1, pa0 = 0 : lowest output power pa2, pa1, pa0 = 1 : highest output power gain control in power amplifier buffer: 1=high gain gain control in preamplifier in receiver: 1=high gain 1 = the LNA is bypassed
Micrel
Fc1 Fc0 OutS2 OutS1 OutS0
OutS0 IchOut 0 high Z
QchOut gm_qch lim_ich Dual LF M_div
0 0 1 sk_ich sk_qch 1 0 1 gm_ich 0 1 0 gm_ich gm_qch 1 1 0 high Z 0 1 1 lim_ich lim_qch 1 1 1 N_div sk:_*:Sallen-Key-filter output, gm_*:gyrator filter output, lim_*:limiter output, *_div:frequency divider output (for testing). 110 is for dual-loop filter applications, see Modulation Outside PLL, Dual-Loop Filters. Mod1 = 0, Mod0 = 0: FSK modulation can be applied to the VCO Mod1 = 0, Mod0 = 1: FSK modulation can be applied to the VCO: crystal modulation Mod1 = 1, Mod0 = 0: FSK modulation by switching between the two sets of dividers Mod1 = 1, Mod0 = 1: FSK modulation by adding/subtracting 1 to divider A1: fdeviation = fcomparison 0 = receive mode 1 = transmit mode 1 = power up, 0 = power down (When Pu=1, power down is controlled by PuExt)
Mod1 Mod0
RT Pu
Table 2. Bit Description
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When FSK modulation is applied to the VCO the PLL is using the dividers A1, N1 and M1. When Mod1 = 1 and Mod0 = 0 it is possible to switch between the different dividers in the PLL. DATAIXO controls the switching. When DATAIXO = 0 the PLL uses dividers A0, N0 and M0. When DATAIXO = 1 the PLL uses dividers A1, N1 and M1. Switching between the different dividers can be used to implement FSK modulation. The N, M and A values can be calculated from the formula:
f fRF fC = XCO = M 32 x N + A where fC is the comparison frequency.
Micrel
6. A new control word is entered into the first register. A transition on the REGIN signal when CLKIN is high will now turn the power amplifier off. 7. When the power amplifier is turned off an internal load pulse is generated. The new control word is loaded into the parallel register and the circuit enters a new mode (in this case power down mode). CLKIN must go low after the internal load pulse is generated. As long as transitions on REGIN are avoided when CLKIN is high, a new control word can be clocked into the first register any time without affecting the operation of the transceiver. Example 1. f RF = 434.245MHz, frequency deviation: 10kHz, fXCO = 10.00MHz. FSK modulation is implemented by switching between dividers.
A1 Tx Rx 18 27 RxFilt A0 11 27 Pa2 1 1 Ref5 0 0 N1 127 143 Pa1 1 1 Ref4 0 0 N0 115 143 Pa0 1 1 Ref3 0 0 Fc1 0 0 Mod0 0 0 M1 94 106 Gc 1 1 Ref2 0 0 Fc0 1 1 RT 1 0 M0 85 106 ByLNA 0 0 Ref1 0 0 OutS2 0 0 Pu 1 1
The 8bit control word is first read into a shift-register, and is then loaded into a parallel register by a transition of the REGIN signal (positive or negative) when the CLKIN signal is high. The circuit then goes directly into the specified mode (receive, transmit, etc.).
1 CLKIN REGIN LOAD_INT PA_C LOCKDET 23 4 5 6 7
Tx Rx
0 0 Ref6
Tx Rx
0 0 Ref0
Cpmp1 Cpmp0 1 1 OutS0 0 0 0 0 Mod1 1 1
Tx Rx
0 0 OutS1
Figure 10. Timing of CLKIN, REGIN and the Internal LOAD_INT and PA_C Signals 1. The second last bit is clocked into the first shift register (`1'). 2. The last bit is clocked into the first shift register (`1'). 3. A transition on the REGIN signal generates an internal load pulse that loads the control word into the parallel register. The circuit enters the new mode (in this case Tx-mode). The circuit stabilizes in the new mode. 4. When the clock signal goes low, the power amplifier (PA) is turned on slowly in order to minimize spurious components on the RF output signal. To be sure the PLL is in lock before the PA is turned on, the PA should be turned on after LOCKDET has been set. The negative transition on the clock signal should come a minimum time of one period of the comparison frequency after the internal load pulse is generated. 5. The power amplifier is fully turned on.
Tx Rx
0 0
Binary form: (MSB to the left): Tx: 010010 001011 000001111111 000001110011 0001011110 0001010101 011110000000010010001011 Rx: 011011 011011 000010001111 000010001111 0001101010 0001101010 011110000000010010001001 When FSK modulation is implemented by switching between the different dividers A, N and M values corresponding to the receive frequency and both transmit frequencies have to be found.
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Example 2. fRF = 434.245MHz, fRF = 10.00MHz. FSK modulation is applied to the VCO.
A1 Tx Rx 27 27 RxFilt Tx Rx 0 0 Ref6 Tx Rx 0 0 Ref0 Tx Rx 0 0 OutS1 Tx Rx 0 0 A0 27 27 Pa2 1 1 Ref5 0 0 N1 143 143 Pa1 1 1 Ref4 0 0 N0 143 143 Pa0 1 1 Ref3 0 0 Fc1 1 1 Mod0 0 0 M1 106 106 Gc 1 1 Ref2 0 0 Fc0 0 0 RT 1 0 M0 106 106 ByLNA 0 0 Ref1 0 0 OutS2 0 0 Pu 1 1
Micrel
Binary form: (MSB to the left): Tx: 011011 011011 000010001111 000010001111 0001101010 0001101010 011110000000001100000011 Rx: 011011 011011 000010001111 000010001111 0001101010 0001101010 011110000000001100000001 With modulation applied to the VCO, A, N and M values corresponding to the receive frequency have to be found. The same set of A, N and M values are used in all modes. Programming After Battery Reset In order to ensure a successful programming after VDD has been zero volts, the PDEXT needs to be kept low during the first programming sequence. This can be done by a seperate I/O-line from a microcontroller, or a RC circuit on the PDEXT pin to the VDD (a capacitor between PDEXT and ground and a resistor between PDEXT and VDD). Using the latter method, R and C values need to be chosen so that the voltage on the PDEXT pin is lower then VDD/2 when the control word is loaded into the parallel register. (See Figure 10.)
Cpmp1 Cpmp0 0 0 OutS0 0 0 1 1 Mod1 0 0
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Micrel
Package Information
0.5510.012 (14.00.3) 0.3940.012 (10.00.3) 0.3150.012 (8.00.3) 44 34
1 0.031 (0.8)
33
11
23
12 0.039 (1.0)
22 0.0850.004 (2.150.1)
0.002 (0.05)
0.016 (0.4)
0.047 (1.2)
44-Pin LQFP (BLQ)
MICREL, INC.
TEL
1849 FORTUNE DRIVE SAN JOSE, CA 95131 USA
FAX
+ 1 (408) 944-0800
+ 1 (408) 944-0970
WEB
http://www.micrel.com
The information furnished by Micrel in this datasheet is believed to be accurate and reliable. However, no responsibility is assumed by Micrel for its use. Micrel reserves the right to change circuitry and specifications at any time without notification to the customer. Micrel Products are not designed or authorized for use as components in life support appliances, devices or systems where malfunction of a product can reasonably be expected to result in personal injury. Life support devices or systems are devices or systems that (a) are intended for surgical implant into the body or (b) support or sustain life, and whose failure to perform can be reasonably expected to result in a significant injury to the user. A Purchaser's use or sale of Micrel Products for use in life support appliances, devices or systems is at Purchaser's own risk and Purchaser agrees to fully indemnify Micrel for any damages resulting from such use or sale. (c) 2003 Micrel, Incorporated.
MICRF501
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March 2003


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