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 CS5180 Modulator & 8 kHz to 400 kHz 16-Bit ADC
Features
16-Bit Delta-Sigma A/D Converter Fully Differential Input with 4.0 Vpp Range Dynamic Range: 93 dB Spurious Free Dynamic Range: 96 dB Total Harmonic Distortion: -95 dB @ 22 kHz Up to 400 kHz Output Word Rate No Missing Codes Non-Aliasing Low-Pass Digital Filter High Speed 3-Wire Serial Interface Supply Options:
- VA+ = 5 V, VD+ = 5 V, 690 mW - VA+ = 5 V, VD+ = 3 V, 368 mW
Description
CS5180 is a fully calibrated high-speed analog-todigital converter, capable of 400 kSamples/second output word rate (OWR). The OWR scales with the master clock. It consists of a 5th order modulator, decimation filter, and serial interface. The chip can use the 2.375 V on-chip voltage reference, or an external 2.5 V reference. The input voltage range is 1.6 x VREFIN Vpp fully differential. Multiple CS5180s can be fully synchronized in multi-channel applications with a SYNC signal. The part has a power-down mode to minimize power consumption at times of system inactivity. The high speed digital I/O lines have complementary signals to help reduce radiated noise from traces on the PC board. The CS5180 can also be operated in modulator-only mode which provides the delta-sigma modulator bitstream as the output. ORDERING INFORMATION CS5180-CL 0 C to 70 C 28-pin PLCC
Modulator Output Mode Power Down Mode
I
VA+
AGND
VD+
DGND
AIN+ AINVREFVREF+ VREFIN x1.6
Modulator
Decimator
Clock
MCLK MCLK
Mode Selector
MFLAG
VREFOUT VREFCAP
Reference
Timing and Control
Serial Interface
SDO SDO SCLK SCLK FSO
PWDN
SYNC RESET MODE
Preliminary Product Information
P.O. Box 17847, Austin, Texas 78760 (512) 445 7222 FAX: (512) 445 7581 http://www.cirrus.com
Cirrus Logic reserves the right to modify this product without notice.
Copyright Cirrus Logic, Inc. 2002 (All Rights Reserved)
APR `02 DS259PP4 1
(c)
CS5180
TABLE OF CONTENTS
CHARACTERISTICS/SPECIFICATIONS ............................................................ 4 ANALOG CHARACTERISTICS................................................................... 4 DYNAMIC CHARACTERISTICS ................................................................. 6 DIGITAL CHARACTERISTICS.................................................................... 6 SWITCHING CHARACTERISTICS ............................................................. 7 RECOMMENDED OPERATING CONDITIONS .......................................... 8 ABSOLUTE MAXIMUM RATINGS .............................................................. 8 GENERAL DESCRIPTION .................................................................................. 9 THEORY OF OPERATION .................................................................................. 9 Converter Initialization: Calibration and Synchronization .......................... 9 Clock Generator ........................................................................................ 10 Voltage Reference .................................................................................... 10 Analog Input ............................................................................................. 11 Output Coding .......................................................................................... 11 Modulator-Only mode ............................................................................... 11 Instability Indicator .................................................................................... 13 Digital Filter Characteristics ...................................................................... 13 Serial Interface .......................................................................................... 13 Power Supplies / Board Layout ................................................................ 13 Power-down Mode .................................................................................... 15 PIN DESCRIPTION ............................................................................................ 16 PARAMETER DEFINITIONS ............................................................................. 19 APPENDIX A: CIRCUIT APPLICATIONS ......................................................... 21 PACKAGE OUTLINE DIMENSIONS ................................................................. 26
Contacting Cirrus Logic Support
For a complete listing of Direct Sales, Distributor, and Sales Representative contacts, visit the Cirrus Logic web site at: http://www.cirrus.com/corporate/contacts/sales.cfm
IMPORTANT NOTICE "Preliminary" product information describes products that are in production, but for which full characterization data is not yet available. "Advance" product information describes products that are in development and subject to development changes. Cirrus Logic, Inc. and its subsidiaries ("Cirrus") believe that the information contained in this document is accurate and reliable. However, the information is subject to change without notice and is provided "AS IS" without warranty of any kind (express or implied). Customers are advised to obtain the latest version of relevant information to verify, before placing orders, that information being relied on is current and complete. All products are sold subject to the terms and conditions of sale supplied at the time of order acknowledgment, including those pertaining to warranty, patent infringement, and limitation of liability. No responsibility is assumed by Cirrus for the use of this information, including use of this information as the basis for manufacture or sale of any items, or for infringement of patents or other rights of third parties. This document is the property of Cirrus and by furnishing this information, Cirrus grants no license, express or implied under any patents, mask work rights, copyrights, trademarks, trade secrets or other intellectual property rights. Cirrus owns the copyrights of the information contained herein and gives consent for copies to be made of the information only for use within your organization with respect to Cirrus integrated circuits or other parts of Cirrus. This consent does not extend to other copying such as copying for general distribution, advertising or promotional purposes, or for creating any work for resale. An export permit needs to be obtained from the competent authorities of the Japanese Government if any of the products or technologies described in this material and controlled under the "Foreign Exchange and Foreign Trade Law" is to be exported or taken out of Japan. An export license and/or quota needs to be obtained from the competent authorities of the Chinese Government if any of the products or technologies described in this material is subject to the PRC Foreign Trade Law and is to be exported or taken out of the PRC. CERTAIN APPLICATIONS USING SEMICONDUCTOR PRODUCTS MAY INVOLVE POTENTIAL RISKS OF DEATH, PERSONAL INJURY, OR SEVERE PROPERTY OR ENVIRONMENTAL DAMAGE ("CRITICAL APPLICATIONS"). CIRRUS PRODUCTS ARE NOT DESIGNED, AUTHORIZED, OR WARRANTED TO BE SUITABLE FOR USE IN LIFE-SUPPORT DEVICES OR SYSTEMS OR OTHER CRITICAL APPLICATIONS. INCLUSION OF CIRRUS PRODUCTS IN SUCH APPLICATIONS IS UNDERSTOOD TO BE FULLY AT THE CUSTOMER'S RISK. Cirrus Logic, Cirrus, and the Cirrus Logic logo designs are trademarks of Cirrus Logic, Inc. All other brand and product names in this document may be trademarks or service marks of their respective owners.
2
CS5180
LIST OF FIGURES
Figure 1. Serial Port Timing (not to scale) .................................................................. 7 Figure 2. RESET and SYNC logic and timing. ........................................................... 9 Figure 3. CS5180 connection diagram for using the internal voltage reference. ...... 10 Figure 4. CS5180 connection diagram for using an external voltage reference. ...... 11 Figure 5. Modulator Only Mode Data RTZ Format. .................................................. 12 Figure 6. Circuit to Reconstruct Return-to-Zero (RTZ) Data from SDO/SDO into Original Modulator Bitstream. 12 Figure 7. Magnitude versus frequency spectrum of modulator bitstream (MCLK = 25.6 MHz). .......................................................................... 12 Figure 8. Expanded view of the magnitude versus frequency spectrum of modulator bitstream (MCLK = 25.6 MHz). ......................................................... 12 Figure 9. CS5180 Digital Filter Magnitude Response (MCLK = 25.6 MHz) .............. 13 Figure 10. CS5180 Digital Filter Phase Response (MCLK = 25.6 MHz) ........................................................................................... 13 Figure 11. CS5180 System Connection Diagram ..................................................... 14 Figure 12. Single amplifier driving only AIN+, AIN- held at steady dc value ............. 21 Figure 13. Performance of amplifier of Figure 12 overdriving AIN+ input to the CS5180 at 4 VPP ............................................................................................... 21 Figure 14. Performance of amplifier of Figure 12 with AIN+ driven at 2 VPP ........... 21 Figure 15. AC-coupled driver using two amplifiers. .................................................. 22 Figure 16. Performance of amplifier in Figure 15 ..................................................... 22 Figure 17. Three amplifier driver .............................................................................. 23 Figure 18. Performance of amplifier in Figure 17 ..................................................... 23 Figure 19. Four amplifier driver. ............................................................................... 24 Figure 20. Performance of amplifier in Figure 19 ..................................................... 24 Figure 21. Performance of amplifier in Figure 19 ..................................................... 24 Figure 22. CS5180 Differential Non-linearity plot. (Data taken with repeating ramp) ....................................................................... 25 Figure 23. Histogram of DNL from Figure 22 ........................................................... 25 Figure 24. CS5180 Noise Histogram, > 60,000 samples. ........................................ 25
3
CS5180
CHARACTERISTICS/SPECIFICATIONS
ANALOG CHARACTERISTICS (TA = 0 C to 70 C; VA+ = 5 V 5%, VD+ = 3 V 10%; AGND =
DGND = 0 V; MCLK = 25.6 MHz; VREFIN = VREFOUT; MODE = VD+; Analog source impedance = 301 Ohms with 2200 pF to AGND; Full-Scale input sinewave at 22 kHz; Unless otherwise noted) Parameter Dynamic Performance Dynamic Range Total Harmonic Distortion Signal to (Noise + Distortion) Spurious Free Dynamic Range Static Performance Linearity Error Differential Non-Linearity Full Scale Error Full Scale Drift with Internal Reference Offset Error Offset Drift Analog Input Differential Input Voltage Range Common Mode Range Input Capacitance Differential Input Impedance Common Mode Rejection Ratio Common Mode Input Current Reference Input VREFIN VREFIN Current Reference Output VREFOUT Voltage VREFOUT Output Current VREFOUT Impedance 2.25 2.375 0.1 2.5 500 V A (Note 4) 2.25 2.375 1 2.6 200 V A MCLK = 25.6 MHz (Note 2) MCLK = 25.6 MHz CMRR (Note 3) CMR 1 50 1.6 X VREFIN 4.0 500 100 VREFIN + 0.25 200 Vpp V pF k dB A (Note 2) (Note 2) (Note 6) (Notes 2 and 5) (Note 6) (Note 2) INL DNL 2 8 50 8 6.0 0.5 LSB LSB LSB ppm/C LSB V/C (Note 1) DR THD SINAD SFDR 90 -90 87 90 93 -95 91 96 dB dB dB dBc Symbol Min Typ Max Unit
Notes: 1. Dynamic range is tested with a 22 kHz input signal 60 dB below full scale. 2. Specification guaranteed by design, characterization, and/or test. 3. Full scale fully-differential input span is nominally 1.6 X the VREFIN voltage. The peak negative excursion of the signals at AIN+ or AIN- should not go below AGND for proper operation. 4. VREFIN current is less than 1 A under normal operation, but can be as high as 200 A during calibration. 5. Drift of the on-chip reference alone is typically about 30 ppm/C. If using an external reference, total full scale drift will be that of the external reference 20 ppm/C, which is the typical drift of the X1.6 buffer. 6. Applies after self-calibration at final operating ambient temperature.
4
CS5180
ANALOG CHARACTERISTICS (Continued)
Parameter Power Supplies Power Supply Current (MODE = 1, PWDN = 1) VA1+, VA2+ = 5 V VD1+, VD2+ = 5 V VD1+, VD2+ = 3 V (Note 7) PSRR 46 92 46 3.7 0.068 0.060 46 15 8.5 3.7 0.068 0.060 55 55 110 55 6 0.2 0.2 55 20 11.0 6 0.2 0.2 mA mA mA mA mA mA mA mA mA mA mA mA dB Symbol Min Typ Max Unit
Power Supply Current (MODE = 1, PWDN = 0) (Notes 7, 8) VA1+, VA2+ = 5 V VD1+, VD2+ = 5 V VD1+, VD2+ = 3 V Power Supply Current (MODE = 0, PWDN = 1) VA1+, VA2+ = 5 V VD1+, VD2+ = 5 V VD1+, VD2+ = 3 V (Note 7)
Power Supply Current (MODE = 0, PWDN = 0) (Notes 7, 8) VA1+, VA2+ = 5 V VD1+, VD2+ = 5 V VD1+, VD2+ = 3 V Power Supply Rejection (Note 9)
Notes: 7. All outputs unloaded. All digital inputs except MCLK held static at VD+ or DGND. 8. Power consumption when PWDN = 0 applies only with no master clock applied (MCLK held high or low). 9. Measured with a 100 mVpp sine wave on the VA+ supplies at a frequency of 100 Hz.
5
CS5180
DYNAMIC CHARACTERISTICS
Parameter Modulator Sampling Frequency Output Word Rate Filter Characteristics -3 dB Corner Passband Ripple Stopband Frequency Stopband Rejection Group Delay (Note 2) 90 MCLK/142.3804 MCLK/128 2370/MCLK 0.05 Hz dB Hz dB s Symbol Min Typ MCLK MCLK/64 Max Unit Hz Hz
DIGITAL CHARACTERISTICS
Parameter High-Level Input Voltage Low-Level Input Voltage High-Level Output Voltage (IO = -100 A) Low-Level Output Voltage (IO = 100 A) Input Leakage Current Input Capacitance
(TA = 0 C to 70 C; VA+ = 5 V 5%; AGND = DGND = 0 V) Symbol VD+ = 5 V VD+ = 3 V VD+ = 5 V VD+ = 3 V VD+ = 5 V VD+ = 3 V VD+ = 5 V VD+ = 3 V VD+ = 5 V VD+ = 3 V VIH VIH VIL VIL VOH VOH VOL VOL Iin Iin Cin Min 4.0 2.0 4 2.7 Typ 1 1 6 Max 0.8 0.8 0.4 0.3 10 10 Unit V V V V V V V V A A pF
6
CS5180
SWITCHING CHARACTERISTICS (TA = 0 C to 70 C; VA+ = 5 V 5%, VD+ = 2.7 V to 5.5 V;
AGND = DGND = 0 V; MODE = VD+) Parameter Master Clock Frequency Master Clock Duty Cycle Rise Times (Notes 2, 10, and 11) Any Digital Input, Except MCLK MCLK Any Digital Output (Notes 2, 10, and 11) Any Digital Input, Except MCLK MCLK Any Digital Output trise tfall 1/MCLK 1/MCLK (Note 12) t1 t2 t3 t4 t5 MCLK/3 1/MCLK 2/MCLK 2/MCLK + 2E-9 1.5 1/MCLK - 2E-9 Hz s s s ns s 20 3 988205/MCLK 3 5161/MCLK 5168/MCLK 100 .2/MCLK ns s ns ns s ns s s s s 20 100 .2/MCLK ns s ns (Note 2) Symbol MCLK Min 0.512 45 Typ 25.6 Max 26 55 Unit MHz %
Fall Times
Calibration/Sync RESET rising to MCLK rising RESET rising recognized, to FSO falling SYNC rising to MCLK rising SYNC rising recognized to FSO falling PWDN rising recognized to FSO falling SYNC high time RESET low time Serial Port Timing SCLK frequency SCLK high time SCLK low time FSO falling to SCLK rising SCLK falling to new data bit available SCLK rising to FSO rising
Notes: 10. Rise and Fall times are specified at 10% to 90% points on waveform. 11. RESET, SYNC, and PWDN have Schmitt-trigger inputs. 12. Specifications applicable to complementary signals SCLK and SDO.
FSO t3 SCLK t4 SDATA XX MSB MSB-1 LSB-1 LSB XX t1 t2 t5
Figure 1. Serial Port Timing (not to scale)
7
CS5180
RECOMMENDED OPERATING CONDITIONS (AGND = DGND = 0 V)
Parameter DC Power Supplies Analog Reference Voltage AGND to DGND Differential Operating Junction Temperature Tj Digital Analog Symbol VD+ VA+ VREFIN Min 2.7 4.75 2.25 -100 Typ 3 5 2.5 0 Max 5.5 5.25 2.6 100 120 Unit V V V mV C
ABSOLUTE MAXIMUM RATINGS
Parameter DC Power Supplies Symbol Ground AGND/DGND Digital VD+ Analog VA+ Iin Iout VINA VIND TA Tstg Min -0.3 -0.3 -0.3 -0.3 -0.3 0 -65 Max 0.3 6.0 6.0 10 25 1000 (VA+) + 0.3 (VD+) + 0.3 70 150 Unit V V V mA mA mW V V C C
Input Current, Any pin except Supplies Output Current Power Dissipation (Total) Analog Input Voltage and VREFIN voltage Digital Input Voltage Ambient Operating Temperature Storage Temperature
WARNING: Operation beyond these limits may result in permanent damage to the device. Normal operation is not guaranteed at these extremes.
8
CS5180
GENERAL DESCRIPTION
The CS5180 is a monolithic CMOS 16-bit A/D converter designed to operate in a continuous mode after being reset. The CS5180 can operate in a modulator-only mode in which the unfiltered bit stream from the modulator is the data output from the device. word rate equal to MCLK/64. Figure 2 illustrates the RESET and SYNC logic and timing for the converter. The CS5180 is designed to perform conversions continuously with an output rate that is equivalent to MCLK/64. The conversions are performed and the serial port is updated independent of external controls. The converter is designed to measure differential bipolar input signals, and unipolar signals, with a common mode voltage of between 1.0 V and VREF + 0.25 V. Calibration is performed when the RESET signal to the device is released. If RESET is properly framed to MCLK, the converter can be synchronized to a specific MCLK cycle at the system level. The SYNC signal can also be used to synchronize multiple converters in a system. When SYNC is used, the converter does not perform calibration. The SYNC signal is recognized on the first rising edge of MCLK after SYNC goes high. SYNC aligns the output conversion to occur every 64 MCLK clock cycles after the SYNC signal is recognized and the filter is settled. After the SYNC is initiated by going high, the converter will wait 5,161 MCLK cycles for the digital filter to settle before putting out a fully-settled conversion word. To synchronize multiple converters in a system, the
MCLK Q RESET CLK Q RESET FSO MCLK MCLK SYNC D CLK
FSO
THEORY OF OPERATION
The front page of this data sheet illustrates the block diagram of the CS5180.
Converter Initialization: Calibration and Synchronization
The CS5180 does not have an internal power-on reset circuit. Therefore when power is first applied to the device the RESET pin should be held low until power is established and the voltage reference has stabilized. This resets the converter's logic to a known state. When power is fully established the converter will perform a self-calibration, starting with the first MCLK rising edge after RESET goes high. The converter will use 988,205 MCLK cycles to complete the calibration and to allow the digital filter to fully settle, after which, it will output fullysettled conversion words. The converter will then continue to output conversion words at an output
CS5180
RESET D
988205 MCLK Cycles
Q
SYNC SYNC
5161 MCLK Cycles
Figure 2. RESET and SYNC logic and timing.
9
CS5180
SYNC pulse should rise on a falling edge of the MCLK signal. This ensures that the SYNC input to all CS5180s in the system will be recognized on the next rising edge of MCLK. Use of the SYNC input is not necessary to make the converter operate properly. If it is unused it should be tied to DGND. Conversion data is output from the SDO and SDO pins of the device. The data is output from the SDO pin MSB first, in two's complement format. The converter furnishes a serial clock SCLK and its complement SCLK to latch the data bits; and a data framing signal, Frame Sync Output (FSO), which frames the output conversion word. The SCLK output frequency is MCLK/3. to minimize radiated noise from the PC board layout. The CS5180 can be operated with MCLK frequencies from 512 kHz up to 26 MHz. The output word rate scales with the MCLK rate with OWR = MCLK/64.
Voltage Reference
The CS5180 can be configured to operate from either its internal voltage reference, or from an external voltage reference. The on-chip voltage reference is 2.375 V and is referenced to the AGND pin. This 2.375 V reference is output from the VREFOUT pin. It is then filtered and returned to the VREFIN pin. VREFIN pin is connected to a buffer which has a gain of 1.6. This scales the on-chip reference of 2.375 V to 3.8 V. This value sets the peak-to-peak input voltage into the AIN pins of the converter. Figure 3 illustrates the CS5180 connected to use the internal voltage reference. Note that a 1.0 F and 0.1 F capacitor are shown connected to the VREFCAP pin to filter out noise. A larger capacitor can be used, but may require a longer reset period when first applying power to the part to allow for the reference to charge up the capacitors and stabilize before self-calibration begins.
CS5180
Clock Generator
The CS5180 must be driven from a CMOS-compatible clock at its MCLK pin. The MCLK input is powered from the VD+ supply and its signal input should not exceed this supply. The required MCLK is 64 x OWR (Output Word Rate). To achieve an Output Word Rate of 400 kHz, the MCLK frequency must be 64 x 400 kHz, or 25.6 MHz. A second clock input pin, MCLK, is not actually used inside the device but allows the user to run a fully differential clock to the converter
VREFIN VREF+ 10 F + 0.1 F VREF-
X1.6 Modulator
VREFOUT + 10 F 0.1 F VREFCAP + 1 F 0.1 F
X1
Reference
Figure 3. CS5180 connection diagram for using the internal voltage reference.
10
CS5180
CS5180
VS 2.5 V
+ + 0.1 F
VREFIN VREF+ 10 F + 0.1 F VREF10 F
X1.6 Modulator
10 F
0.1 F
VREFOUT + 10 F 0.1 F VREFCAP + 1 F 0.1 F
X1
Reference
Figure 4. CS5180 connection diagram for using an external voltage reference.
Alternatively, the CS5180 can be configured to use an external voltage reference. Figure 4 illustrates the CS5180 connected to use a 2.5 V external reference. In this case, the peak-to-peak input at the AIN pins is 4 V.
Fully Differential Bipolar Input Voltage1 >(VFS - 1.5 LSB) VFS - 1.5 LSB -0.5 LSB -VFS + 0.5 LSB <(-VFS + 0.5 LSB) Twos Complement 7FFF 7FFF 7FFE 0000 FFFF 8001 8000 8000
Analog Input
The analog signal to the converter is input into the AIN+ and AIN- pins. The input signal is fully differential with the maximum peak-to-peak amplitude of VREFIN X 1.6 V. The signal needs to have a common mode voltage in a range from 1 V to VREF + 0.25 V. A resistor-capacitor filter should be included on the AIN+ and AIN- inputs of the converter. This should consist of a 20 resistor and a 2200 pF capacitor on each input to ground as illustrated in the system connection diagram (Figure ).
Notes: 1. VFS = VREFIN x 1.6 Table 1. Output Coding.
Output Coding
Table 1 illustrates the output coding for the converter when operating with the digital filter (MODE = 1). The converter outputs its data from the serial port in twos complement format, MSB first.
The chip offers an MFLAG signal to indicate when the modulator has gone unstable. MFLAG is set when an overrange signal forces the modulator into an unstable condition. Under this condition, output codes from the converter will be locked to either plus or minus full scale as is appropriate for the overrange condition.
Modulator-Only mode
The CS5180 can be operated in modulator-only mode by connecting the MODE pin to a logic 0 (DGND). In modulator-only mode the noise-shaped bitstream from the fifth-order delta-sigma modulator is output from the SDO and SDO (inverse bitstream) pins.
11
CS5180
MCLK Modulator Data SDO SDO Reconstructed Data
Figure 5. Modulator Only Mode Data RTZ Format.
The data from the modulator is output from SDO/SDO in RTZ (Return to Zero) format. The circuit in Figure 6 can be used to reconstruct the data so it can be captured with the rising or falling edge of MCLK. Table 2 illustrates the magnitude of the input signal into the chip versus the ones density out of the modulator. The table does not take into account the potential offset and gain errors of the modulator and their effect on the ones density.
Fully Differential Bipolar Input Voltage2 VFS 0 -VFS Modulator Ones Density3 75% 50% 25%
Figure 7 and Figure 8 illustrate magnitude versus frequency plots of the modulator bitstream when running at 25.6 MHz.
Notes: 2. VFS = VREFIN x 1.6 3. Ones density is approximate; it does not take offset and gain errors into consideration. Table 2. Modulator-Only Mode Ones Density.
Figure 7. Magnitude versus frequency spectrum of modulator bitstream (MCLK = 25.6 MHz).
SDO
Reconstructed Data
SDO
Reconstructed Data
Figure 6. Circuit to Reconstruct Return-to-Zero (RTZ) Data from SDO/SDO into Original Modulator Bitstream.
Figure 8. Expanded view of the magnitude versus frequency spectrum of modulator bitstream
12
CS5180
Instability Indicator
The MFLAG signal is functional in both modes of operation of the part and indicates when the modulator has been overdriven into an unstable condition. In the modulator only mode (MODE = 0), the MFLAG signal will remain set for 3 MCLK cycles when the modulator goes unstable, before being returned to the reset state. While the input condition causing modulator instability persists, the MFLAG signal will continually get set for 3 MCLK cycles and then get reset. When the decimation filter on the part is operational (MODE = 1), the MFLAG signal is set when the modulator goes unstable. In this mode, however, the MFLAG signal stays set until 5,120 MCLK cycles after the input condition causing modulator instability is removed. This delay is provided to allow the digital filter time to settle, and the part will output fully settled conversion words after the MFLAG signal goes low.
Figure 9. CS5180 Digital Filter Magnitude Response (MCLK = 25.6 MHz)
Digital Filter Characteristics
Figure 9 illustrates the magnitude versus frequency plot of the converter when operating at 400 kHz output word rate. The filter is a non-aliasing 4265 tap filter with a -3 dB corner at 0.4495 of the output word rate and an out-of-band attenuation of at least 90 dB at frequencies above one half the output word rate. The passband ripple is less than 0.05 dB up to the -3 dB corner frequency. Figure 10 illustrates the phase response of the digital filter with the converter operating at 400 kHz output word rate. The filter characteristics change proportional to changes in the MCLK rate. The group delay of the digital filter is 2,370 MCLK cycles (92.6 s with MCLK = 25.6 MHz), and the settling time is 4,740 MCLK cycles (185.2 s).
Figure 10. CS5180 Digital Filter Phase Response (MCLK = 25.6 MHz)
rial Data Output pin (SDO), and its complement (SDO); Serial Clock (SCLK), and its complement (SCLK); and the Frame Sync Output (FSO). FSO falls at the beginning of an output word. Data is output in twos complement format, MSB first. FSO stays low for 16 SCLK cycles. SCLK is output at a rate equal to MCLK/3.
Power Supplies / Board Layout
The CS5180 can be operated with VA+ supplies at 5 V and VD+ supplies at 5 V; or with VA+ at 5 V and VD+ at 3 V. Figure illustrates the system connection diagram for the chip. For best performance, each of the
13
Serial Interface
The CS5180 has a serial interface through which conversion words are output in a synchronous selfclocking format. The serial port consists of the Se-
CS5180
supply pins should be bypassed to the nearest ground pin on the chip. The bypass capacitors should be located as close to the chip as possible. If the chip is surface mounted the bypass capacitors should be on the same side of the circuit card as the chip. The CS5180 is a high speed component that requires adherence to standard high-frequency printed circuit board layout techniques to maintain optimum performance. These include the use of ground and power planes, using low noise power supplies in conjunction with proper supply decoupling, minimizing circuit trace lengths, and physical separation of digital and analog components and circuit traces. It is preferred that any clock oscillator circuitry be located on a ground plane separate from the digital plane in order to ensure that digital noise does not induce clock jitter. For additional insight, see the CDB5180 evaluation board for more details. Also refer to Application Note AN18 about layout and design rules for data converters.
1 0.1 F
AGND1
DGND1
22 0.1 F +5 V or +3.0 V
+5 V
28 8
VA1+ VA2+ CS5180
VD1+ VD2+
21 12
0.1 F
7 AGND2 18 AGND3 4 VREFOUT 5 VREFIN 3 VREF2
VREF+
DGND2
11
0.1 F
+
PWDN MODE RESET SYNC MFLAG
10 F
0.1 F
25 24 23 10 9
Control Logic
+
10 F
0.1 F 6 VREFCAP
MCLK MCLK
20 19
Clock Source
+ 1 F
0.1 F 26 2200 pF
AIN+
20 3.8 Vpp Fully Differential ~ CMV = 2.375 V
20 2200 pF
27
FSO SCLK SCLK SDO SDO
17 14 13 16 15
Data Interface
AIN-
The 3.8 Vpp fully differential input span is set by the converter's internal voltage reference at 2.375 V. An input span of 4.0 Vpp fully differential would result if an external voltage reference of 2.5 V is used. Miniature surface mount 25.6 MHz clock oscillators may be ordered from the CTS Reeves Company. For 4.5 V to 5.5 Volt Operation, order P/N 974-7725-0000A For 3.0 to 3.6 Volt Operation, order P/N 974-7727-0000A
Figure 11. CS5180 System Connection Diagram
14
CS5180
Power-down Mode
The CS5180 has a PWDN (power-down) function. When active low, power to most of the converter's circuitry will be reduced. If MCLK is to be stopped to save power, it should not be stopped until at least ten clock cycles after PWDN is taken low. The ten clock cycles are required to allow the part to turn off it's internal circuitry. If the part does not get the full ten clock cycles, it will still go into a power down state, but the power dissipation could be more than is listed in the specifications for the full power down condition. When PWDN is active, the calibration information inside of the converter is maintained. When coming out of the power-down state, the converter is not recalibrated and will start-up similar to when SYNC is initiated.
15
CS5180
PIN DESCRIPTION
Analog Ground Pos. Reference Neg. Reference Pos. Reference Input Analog Ground Analog Supply Invalid Conversion Sync. Filter Digital Ground Pos. Digital Supply Inverse Serial Clock Serial Clock AGND VREF+ VREFVREFIN
5 6 7 8 9 10 11 12 13 14 15 16 17 18 43
VA1+ AINAIN+ PWDN
2 1 28 27 26 25 24
Positive Analog Supply Negative Analog Input Positive Analog Input Power Down Mode Modulator Only Mode Digital Ground Positive Digital Supply Master Clock Inverse Master Clock Analog Ground Frame Sync Output Serial Data Out Inverse Serial Data Out\
Reference Output VREFOUT Reference Bypass VREFCAP AGND VA2+ MFLAG SYNC DGND VD2+ SCLK SCLK
MODE DGND VD1+ MCLK MCLK AGND FSO SDO SDO
RESET Reset and Calibration
CS5180
23 22 21 20 19
Supply Inputs VA1+, VA2+ -- Positive Analog Supply Input for positive analog supply is +5 V typical when AGND is 0 V. AGND -- Analog Ground Analog ground for circuits supplied by VA+. VD1+, VD2+ -- Positive Digital Supply Input for positive digital supply is +5 V typical when DGND is 0 V. DGND -- Digital Ground Digital ground for circuits supplied by VD+. Signal and Reference Related Inputs AIN+, AIN- -- Differential Analog Inputs Fully differential signal inputs. VREFIN -- Voltage Reference Input VREFOUT or an external reference is connected to VREFIN. Analog input voltage (full scale fully differential peak-to-peak) into the converter is 1.6 times this value.
16
CS5180
VREF+ -- Positive Voltage Reference Filter capacitor connection for the reference input buffer. The voltage on this pin equals VREFIN X 1.6. VREF- -- Negative Voltage Reference VREF- is connected to AGND. VREFOUT -- Voltage Reference Output Output pin for the 2.375 volt on-chip reference relative to AGND. VREFCAP -- Reference Bypass Filter capacitor connection for the internal reference. Serial Interface I/O Signals SCLK, SCLK -- Serial Interface Clock Serial Clock Output. A gated serial clock output from the converter at a rate equal to 1/3 the MCLK clock rate. The SCLK output is a complement of SCLK and helps reduce radiated noise if the two lines are run adjacent on the PC board layout. SDO, SDO -- Serial Data Out Serial Data Output. Output pin for 16-bit serial data word. The SDO output is the complement of SDO and helps to reduce radiated noise if the two lines are run adjacent on the PC board layout. Output data is output in twos complement format MSB first. FSO -- Frame Sync Output The Frame Sync Output indicates the beginning of an output word from the SDO pin by falling to a logic low state. FSO remains low until all 16 bits are clocked out. Control Pins RESET -- Reset and Calibration When the RESET pin is pulled to a logic low the converter will perform a reset of its digital logic. When the level on this pin is brought back to a logic high the chip starts normal operation, following a two clock cycle delay period. When MODE = 1 the chip goes through an internal gain and offset calibration routine following this reset sequence. PWDN -- Power Down Mode A logic 0 on PWDN pin will put the device into a power-down mode.
17
CS5180
MODE -- Modulator Mode MODE is held at a logic high for normal operation. In normal operation the device utilizes the digital decimation filter and calibration circuitry. MODE = 0 puts the part in modulator-only mode whereby most of the digital circuitry is powered-down and the modulator bit-stream is output from the SDO and SDO pins. SYNC -- Synchronization of Filter The SYNC input can be used to restart the digital filter of the converter at the beginning of its convolution cycle. The SYNC input is used to synchronize the filters of multiple converters in a system. When the SYNC pin goes high, the filter will be initialized and will begin its convolution cycle on the next rising edge of MCLK. If not used, tie sync to DGND. MFLAG -- Invalid Conversion Flag MFLAG goes high if the modulator portion of the converter goes unstable. If MFLAG is high, the output data from the converter may be invalid. MCLK, MCLK -- Master Clock Signal Master clock input accepts a CMOS level clock input to the converter with worst case duty cycle of 45-55% (typically 25.6 MHz). MCLK is not actually used inside the device, but can be used for radiated noise cancellation if MCLK and MCLK are run adjacent to each other on the PC board.
18
CS5180
PARAMETER DEFINITIONS
Differential Non-Linearity Error - DNL The deviation of a code's width from ideal. Units in LSBs. Integral Non-Linearity Error - INL The deviation of a code from a straight line passing through the endpoints of the transfer function after zero- and full-scale errors have been accounted for. "Zero-scale" is a point 1/2 LSB below the first code transition and "full-scale" is a point 1/2 LSB beyond the code transition to all ones. The deviation is measured from the middle of each particular code. Units in LSB's. Full-Scale Error - FSEP The deviation of the last code transition from the ideal (VREF-3/2 LSB's). Units in LSB's. Offset Error - VOS The deviation of the mid-scale transition from the ideal (1/2 LSB below 0 Volts). Units in LSB's. Spurious-Free-Dynamic-Range - SFDR The ratio of the rms value of the full-scale signal, to the rms value of the next largest spectral component (excepting dc). This component is often an aliased harmonic when the signal frequency is a significant proportion of the sampling rate. Units in dBc (decibels relative to the carrier). Total Harmonic Distortion - THD The ratio of the rms sum of the significant harmonics (2nd through 7th), to the rms value of the full-scale signal. Units in decibels. Dynamic Range - DR The ratio of the rms value of the inferred full-scale signal, to the rms sum of the broadband noise signals below the Nyquist rate (excepting dc and distortion terms). Expressed in decibels. Dynamic Range is tested with a 22 kHz input signal 60 dB below full scale. 60 dB is then added to the resulting number to refer the noise level to the full-scale signal. This technique ensures that the distortion components are below the noise level and do not affect the measurement. Signal-to-Noise-and-Distortion (s/[n+d]) - SINAD The ratio of the rms value of the full-scale signal, to the rms sum of all other spectral components below the Nyquist rate (excepting dc), including distortion components. Expressed in decibels. Group Delay The time delay through the digital filter section of the part. Units in seconds.
19
CS5180
Resolution - N The number of different output codes possible. Expressed as N, where 2N is the number of available output codes. Noise A measure of the variability of the converter's output when a fixed DC input (usually ground) is applied to the input and a large number of samples are taken. RMS noise is determined statistically as the Standard Deviation of the Probability Density Function derived from the histogram of the ADC with the differential inputs shorted together and tied to an appropriate common mode voltage. Common Mode Rejection Ratio - CMRR A measure of the device's ability to cancel out the effect of a common voltage applied to both of its differential inputs. CMRR is specified as the ratio of the differential signal gain to the gain for the common-mode signal. Units in dB. Offset Drift Changes in the offset error of the part after self calibration due to changes in ambient temperature. Specified in microvolts per degree C, relative to the input signal. Full Scale Drift Changes in the full scale error of the part after self calibration due to changes in ambient temperature. Specified in parts-per-million (PPM) of the full scale range per degree C.
20
CS5180
+15
0.1 F 0.15 C0G + 10 k 10 k U1 +
20 AIN+ 2200 pF 0.1 F
CS5180
-15
20
AIN-
2200 pF 1 k VREFOUT 10 F + 5 k 0.1 F + 10 F
Figure 12. Single amplifier driving only AIN+, AIN- held at steady dc value
APPENDIX A: CIRCUIT APPLICATIONS
Several amplifier circuits have been tested with the CS5180. Performance at higher frequencies is generally limited by the operational amplifiers used to drive the A/D converter. Figure 12 illustrates a single operational amplifier circuit which can accept a single-ended ground-referenced signal and condition it for the input of the CS5180. The amplifier is AC-coupled to the signal source. In this circuit the AIN- input to the CS5180 is held at a constant DC value and the AIN+ input is driven (it is actually overdriven to achieve high dynamic range, but this sacrifices performance with regard to distortion). The common mode voltage for the CS5180 input should be designed to stay between 1 V and VREF + 0.25 V when driven at its AIN+ and AIN- inputs. In Figure 12 the dc voltage at the AIN- input is set so that when driven with a 4 Vpp signal on the AIN+ pin, the common mode voltage remains within the proper range. Figures 13 and 14 illustrate the performance of the amplifier of Figure 12 operating with a 4 Vpp input into the AIN+ input; and with 2 Vpp input into the AIN+ input respectively. Figure 15 illustrates an AC-coupled two amplifier circuit. This circuit gives better performance than
Figure 14. Performance of amplifier of Figure 12 with AIN+ driven at 2 VPP 21
Figure 13. Performance of amplifier of Figure 12 overdriving AIN+ input to the CS5180 at 4 VPP
CS5180
2 k +15
20 F + 10 k
2 k U1 +
0.1 F
400 AIN2200 pF
CS5180
-15
0.1 F 2 k +15
100 2200 pF
2 k U2 +
0.1 F
400 AIN+
-15
0.1 F VREFOUT
0.1 F
10 F +
Figure 15. AC-coupled driver using two amplifiers.
the single amplifier circuit of Figure 12 because the inputs to the CS5180 are driven differentially. The 400 and 100 output divider scales down the input from the amplifier. The scaling should be optimized for the application. Figure 16 illustrates the performance of the converter when using this amplifier circuit. The amplifier of Figure 17 uses three amplifiers and can accept a ground referenced signal or a fully differential signal. Figure 18 illustrates its performance when driven with 57.6 kHz signal. Figure 19 illustrates a four amplifier circuit which gives the best performance by keeping everything balanced. Performance is generally limited by the amplifiers. Again, the output resistors are used to scale down the input signal. Figures 20 and 21 il22
Figure 16. Performance of amplifier in Figure 15
CS5180
+12 V 0.1 F 7.77 k + U1 0.1 F -12 V + 10 F C0G 20 pF C0G 20 pF C0G 7.77 k 0.1 F XLR 7.77 k 0.1 F U2 + 10 pF 2200 pF 1 M +12 V 100 2200 pF 10 k
CS5180
150 AIN-
0.1 F 10 k
47 F
VREFOUT
-12 V +12 V 10 F C0G + 7.77 k + 20 pF C0G 20 pF C0G U3
0.1 F 150 AIN+ 0.1 F -12 V
Figure 17. Three amplifier driver
lustrate the performance of the CS5180 with this amplifier circuit. Figure 22 illustrates a Differential Non-linearity plot of the converter. Data for the plot was taken using a repeating ramp. Figure 23 is a histogram of the DNL data in Figure 22. Figure 24 illustrates a noise histogram of the converter with its inputs shorted and connected to a proper common mode voltage.
Figure 18. Performance of amplifier in Figure 17
23
CS5180
2 k +15 V +15 V
0.1 F
U1
+
2 k U3
0.1 F
301 AIN2200 pF
CS5180
10 k -15 V 2 k +15 V
0.1 F
+ -15
0.1 F 2 k
100 2200 pF
+15 V
2 k
U2 +
0.1 F
2 k
U4
0.1 F
301
AIN+
+ -15 V
0.1 F -15 V
0.1 F
10 k 10 F 10 k VREFOUT
+
Figure 19. Four amplifier driver.
Figure 20. Performance of amplifier in Figure 19
Figure 21. Performance of amplifier in Figure 19
24
50000
000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000 0000000000000000000000000000000000000000000 000000000000000000000000000000000000000000 000000000000000000000000000000000000000000
10684 42468 12085
Figure 22. CS5180 Differential Non-linearity plot. (Data taken with repeating ramp)
40000
000000000000000000000000000000000000000000000000000000000000000000000000000000000000 0000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000 00000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000 0000000000000000000000000000000000000000000000000000000000 0000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000 0000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000 0000000000000000000000000000
FFF6 146 33885 FFF5 31415 FFF4
10000
Count
20000
30000
Figure 24. CS5180 Noise Histogram, > 60,000 samples.
0
Code (Hexadecimal)
10000
20000
30000
40000
Figure 23. Histogram of DNL from Figure 22
0
FFF3
105
88
1 LSB = 61 V STD = 0.507 LSB Noise (rm s) = 31 V
DNL (LSB) Range
CS5180
192
25
-0.05 to 0.05 -0.15 to -0.05 -0.25 to -0.15 0.15 to 0.25 0.05 to 0.15 Codes
CS5180
PACKAGE OUTLINE DIMENSIONS
28L PLCC PACKAGE DRAWING
e D2/E2
E1 E
B
D1 D A
A1
INCHES DIM A A1 B D D1 D2 E E1 E2 e MIN 0.165 0.090 0.013 0.485 0.450 0.390 0.485 0.450 0.390 0.040 MAX 0.180 0.120 0.021 0.495 0.456 0.430 0.495 0.456 0.430 0.060 JEDEC # : MS-018
MILLIMETERS MIN MAX 4.043 4.572 2.205 3.048 0.319 0.533 11.883 12.573 11.025 11.582 9.555 10.922 11.883 12.573 11.025 11.582 9.555 10.922 0.980 1.524
26
* Notes *


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