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| CS5371A CS5372A Low-power, High-performance Modulators Features Fourth-order Architecture Clock-jitter-tolerant Architecture Input Voltage: 5 Vpp Fully Differential Input Signal Bandwidth: DC to 2 kHz High Dynamic Range * 127 dB SNR @ 215 Hz BW (2 ms sampling) * 124 dB SNR @ 430 Hz BW (1 ms sampling) Description The CS5371A and CS5372A are one- and two-channel, high-dynamic-range, fourth-order modulators intended for geophysical and sonar applications. When combined with CS3301A / CS3302A differential amplifiers, the CS4373A test DAC and CS5376A digital filter, a small, low-power, self-testing, high-accuracy, multichannel measurement system results. The modulators have high dynamic range and low total harmonic distortion with very low power consumption. They convert differential analog input signals from the CS3301A / CS3302A amplifiers to an oversampled serial bit stream at 512 kbits per second. This oversampled bit stream is then decimated by the CS5376A digital filter to a 24-bit output at the selected output word rate. In normal operation, power consumption is 5 mA per channel. Each modulator can be independently powered down to 500 A per channel, and by halting the input clock they will enter a micro-power state using only 2 A per channel. The CS5371A and CS5372A modulators are available in small 24-pin SSOP packages, providing exceptional performance in a very small footprint. ORDERING INFORMATION See page 31. Low Total Harmonic Distortion * -118 dB THD typical (0.000126%) * -112 dB THD maximum (0.000251%) Low Power Consumption * Normal operation: 25 mW per channel * Power down: 10 W per channel Small Footprint, 24-pin SSOP package Multi-channel System Support * * * * 1-channel System: CS5371A 2-channel System: CS5372A 3-channel System: CS5371A + CS5372A 4-channel System: CS5372A + CS5372A Bipolar Power Supply Configuration * VA+ = +2.5 V; VA- = -2.5 V; VD = +3.3 V VA+ PWDN VD VA+ PWDN1 VD MFLAG1 MFLAG INR+ INF+ INFINRVREF+ VREF4th Order Modulator MDATA INR1+ INF1+ INF1INR1VREF+ VREFINR2+ INF2+ INF2INR2- 4th Order Modulator MDATA1 Clock Generator MCLK MSYNC MFLAG2 Clock Generator MCLK MSYNC 4th Order Modulator MDATA2 CS5371A VAOFST GND VAPWDN2 OFST CS5372A GND http://www.cirrus.com Copyright (c) Cirrus Logic, Inc. 2006 (All Rights Reserved) DEC `06 DS748F1 CS5371A CS5372A TABLE OF CONTENTS 1. CHARACTERISTICS AND SPECIFICATIONS ........................................................................ 4 SPECIFIED OPERATING CONDITIONS ................................................................................. 4 ABSOLUTE MAXIMUM RATINGS ........................................................................................... 4 TEMPERATURE CONDITIONS ............................................................................................... 5 ANALOG INPUT CHARACTERISTICS ................................................................................... 5 PERFORMANCE CHARACTERISTICS ................................................................................... 7 PERFORMANCE PLOTS ......................................................................................................... 9 DIGITAL CHARACTERISTICS .............................................................................................. 10 POWER SUPPLY CHARACTERISTICS ................................................................................ 13 2. SYSTEM DIAGRAM ............................................................................................................ 14 3. MODULATOR OPERATION ................................................................................................... 15 3.1 One's Density ................................................................................................................... 15 3.2 Decimated 24-bit Output .................................................................................................. 16 3.3 Synchronization ............................................................................................................... 16 3.4 Idle Tones ........................................................................................................................ 16 3.5 Stability ............................................................................................................................ 16 4. ANALOG SIGNALS ................................................................................................................ 17 4.1 INR, INF Modulator Inputs ........................................................................................... 17 4.2 Input Impedance .............................................................................................................. 17 4.3 Anti-alias Filter ................................................................................................................. 18 4.4 Analog Differential Signals ............................................................................................... 18 5. DIGITAL SIGNALS ................................................................................................................. 19 5.1 MCLK Connection ............................................................................................................ 19 5.2 MSYNC Connection ......................................................................................................... 19 5.3 MDATA Connection ......................................................................................................... 20 5.4 MFLAG Connection ......................................................................................................... 20 5.5 OFST Connection ............................................................................................................ 20 6. POWER MODES ..................................................................................................................... 21 6.1 Normal Operation ............................................................................................................. 21 6.2 Power Down, MCLK Enabled .......................................................................................... 21 6.3 Power Down, MCLK Disabled .......................................................................................... 21 7. VOLTAGE REFERENCE ........................................................................................................ 22 7.1 VREF Power Supply ........................................................................................................ 22 7.2 VREF RC Filter ................................................................................................................ 22 7.3 VREF PCB Routing .......................................................................................................... 22 7.4 VREF Input Impedance .................................................................................................... 22 7.5 VREF Accuracy ................................................................................................................ 23 8. POWER SUPPLIES ................................................................................................................ 24 8.1 Power Supply Bypassing ................................................................................................. 24 8.2 PCB Layers and Routing ................................................................................................. 24 8.3 Power Supply Rejection ................................................................................................... 24 8.4 SCR Latch-up Considerations ......................................................................................... 25 8.5 DC-DC Converters ........................................................................................................... 25 9. PIN DESCRIPTION - CS5371A ............................................................................................. 26 10. PIN DESCRIPTION - CS5372A ........................................................................................... 28 11. PACKAGE DIMENSIONS ..................................................................................................... 30 12. ORDERING INFORMATION ................................................................................................ 31 13. ENVIRONMENTAL, MANUFACTURING, & HANDLING INFORMATION .......................... 31 14. REVISION HISTORY ........................................................................................................... 31 2 DS748F1 CS5371A CS5372A LIST OF FIGURES Figure 1. Anti-alias Filter Components............................................................................................ 6 Figure 2. Modulator Noise Performance ......................................................................................... 9 Figure 3. Modulator + CS4373A Test DAC Dynamic Performance ................................................ 9 Figure 4. Digital Input Rise and Fall Times ................................................................................... 10 Figure 5. Digital Output Rise and Fall Times ................................................................................ 10 Figure 6. System Timing Diagram................................................................................................. 12 Figure 7. MCLK / MSYNC Timing Detail ....................................................................................... 12 Figure 9. Connection Diagram ...................................................................................................... 14 Figure 8. System Block Diagram................................................................................................... 14 Figure 10. CS5371A and CS5372A Block Diagrams .................................................................... 15 Figure 11. Analog Signals ............................................................................................................. 17 Figure 12. Digital Signals .............................................................................................................. 19 Figure 13. Power Mode Diagram .................................................................................................. 21 Figure 14. Voltage Reference Circuit ............................................................................................ 22 Figure 15. Power Supply Diagram ................................................................................................ 24 LIST OF TABLES Table 1. 24-Bit Output Coding for the CS5371A and CS5372A Modulator and CS5376A Digital Filter Combination ......................................................................................................................... 16 DS748F1 3 CS5371A CS5372A 1. * * * * CHARACTERISTICS AND SPECIFICATIONS Min / Max characteristics and specifications are guaranteed over the Specified Operating Conditions. Typical performance characteristics and specifications are measured at nominal supply voltages and TA = 25C. GND = 0 V. Single-ended voltages with respect to GND, differential voltages with respect to opposite half. Device is connected as shown in Figure 9 on page 14 unless otherwise noted. SPECIFIED OPERATING CONDITIONS Parameter Bipolar Power Supplies Positive Analog Negative Analog Positive Digital Voltage Reference [VREF+] - [VREF-] VREFThermal Ambient Operating Temperature Industrial (-ISZ) TA -40 25 85 C (Note 2, 3) (Note 4) VREF VREF2.500 VA V V 2% (Note 1) 2% 3% VA+ VAVD 2.45 -2.45 3.20 2.50 -2.50 3.30 2.55 -2.55 3.40 V V V Symbol Min Nom Max Unit Notes: 1. VA- must always be the most-negative input voltage to avoid potential SCR latch-up conditions. 2. By design, a 2.500 V voltage reference input results in the best signal-to-noise performance. 3. Channel-to-channel gain accuracy is directly proportional to the voltage reference absolute accuracy. 4. VREF inputs must satisfy: VA- VREF- < VREF+ VA+. ABSOLUTE MAXIMUM RATINGS Parameter DC Power Supplies Positive Analog Negative Analog Digital (VA+) - (VA-) (VD) - (VA-) (Note 5) (Note 5, 6) (Note 5) Symbol VA+ VAVD VADIFF VDDIFF IPWR IIN IOUT PDN VINA VIND TSTG Min -0.5 -6.8 -0.5 (VA-) - 0.5 -0.5 -65 Max 6.8 0.5 6.8 6.8 6.8 50 10 25 500 (VA+) + 0.5 (VD) + 0.5 150 Parameter V V V V V mA mA mA mW V V C Analog Supply Differential Digital Supply Differential Input Current, Power Supplies Input Current, Any Pin Except Supplies Output Current Power Dissipation Analog Input Voltages Digital Input Voltages Storage Temperature Range WARNING: Operation at or beyond these limits may result in permanent damage to the device. Normal operation is not guaranteed at these extremes. Notes: 5. Transient currents up to 100 mA will not cause SCR latch-up. 6. Includes continuous over-voltage conditions at the modulator analog input pins. 4 DS748F1 CS5371A CS5372A TEMPERATURE CONDITIONS Parameter Ambient Operating Temperature Storage Temperature Range Allowable Junction Temperature Junction to Ambient Thermal Impedance (4-layer PCB) Symbol TA TSTR TJCT JA Min -40 -65 Typ 65 Max 85 150 125 Unit C C C C / W ANALOG INPUT CHARACTERISTICS Parameter VREF Input [VREF+] - [VREF-] VREFVREF Input Current VREF Input Noise Modulator INR, INF Inputs External Anti-alias Filter (Note 8) Differential Input Impedance Single-ended Input Impedance Series Resistance Differential Capacitance INR INF INR INF RAA CDIFF ZDIFINR ZDIFINF ZSEINR ZSEINF 680 20 20 1 40 2 nF k M k M (Note 7) (Note 2, 3) (Note 4) VREF VREFVREFIMOD VREFIN 2.500 VA 120 1 V V A Vrms Symbol Min Typ Max Unit Notes: 7. Maximum integrated noise over the measurement bandwidth for the voltage reference device attached to the VREF inputs. 8. Anti-alias capacitors are discrete external components and must be of good quality (C0G, NPO, poly). Poor quality capacitors will degrade total harmonic distortion (THD) performance. See Figure 1 on page 6 DS748F1 5 CS5371A CS5372A 0 OUTR+ OUTF+ INR+ INF+ 0 0 20nF C0G 20nF C0G INFINR0 CS3301 / CS3302 AMPLIFIER OUTFOUTR- CS5371A / CS5372A MODULATOR 680 OUTR+ OUTF+ INR+ INF+ 680 680 20nF C0G 20nF C0G INFINR680 CS3301A / CS3302A AMPLIFIER OUTFOUTR- CS5371A / CS5372A MODULATOR Figure 1. Anti-alias Filter Components 6 DS748F1 CS5371A CS5372A PERFORMANCE CHARACTERISTICS Parameter Signal Characteristics Input Signal Frequencies Full-scale Differential AC Input Full-scale Differential DC Input Input Common Mode Voltage Input Voltage Range (Vcm Signal ) Dynamic Performance Dynamic Range (Note 10, 12) (1/4 ms) DC to 1720 Hz (1/2 ms) DC to 860 Hz (1 ms) DC to 430 Hz (2 ms) DC to 215 Hz (4 ms) DC to 108 Hz (8 ms) DC to 54 Hz (16 ms) DC to 27 Hz (1 ms) DC to 430 Hz (Note 14) (Note 14) SNR 121 100 109 121 124 127 130 133 136 110 -118 0.000126 Symbol (Note 9, 10) (Note 9) (Note 9) (Note 11) (Note 9) VBW VAC VDC VCM VRNG Min DC -2.5 (VA-)+0.7 Typ (VA-)+2.5 Max 2000 5 2.5 (VA+)-1.25 Unit Hz Vpp V V V dB dB dB dB dB dB dB dB dB % dB dB - -112 0.000251 Signal-dependent Noise (Note 13, 14) Total Harmonic Distortion Linearity Common Mode Rejection Ratio SDN THD LIN CMRR CXT 110 -150 - Channel Crosstalk (CS5372A only) Notes: 9. Guaranteed by design and/or characterization. 10. The upper bandwidth limit is determined by the digital filter cut-off frequency. 11. Common mode voltage is defined as the mid-point of the differential signal. 12. Dynamic Range defined as 20 log [ (RMS full scale) / (RMS idle noise) ] where idle noise is measured from a CS3301A / CS3302A amplifier terminated input at 1x gain. 13. Signal-dependent Noise defined as 20 log [ (RMS full scale) / (RMS signal noise) ] where signal noise is measured by subtracting out the signal power at the fundamental and harmonic frequencies. 14. Tested with a 31.25 Hz sine wave at -1 dB amplitude. DS748F1 7 CS5371A CS5372A PERFORMANCE CHARACTERISTICS (CONT.) Parameter Gain Accuracy Channel to Channel Gain Accuracy Channel Gain Drift Offset Offset Voltage, Differential Offset Voltage, CS5371A Offset Voltage, CS5372A channel 1 Offset Voltage, CS5372A channel 2 Offset after Calibration Offset Calibration Range Offset Voltage Drift (OFST = 0) (OFST = 1) (OFST = 1) (OFST = 1) OFST OFST OFST OFST 1 -60 -60 -35 1 100 300 mV mV mV mV V %FS nV/C (Note 3) (Note 15) GA GATC 1 22 2 % ppm/C Symbol Min Typ Max Unit (Note 16) OFSTCAL (Note 17) OFSTRNG (Note 15) OFSTTC Notes: 15. Specification is for the parameter over the specified temperature range and is for the device only. It does not include the effects of external components. 16. Specification applies to the effective offset voltage calculated from the output codes of the digital filter following offset calibration and correction. 17. Offset calibration is performed in the digital filter and includes the full-scale signal range. 8 DS748F1 CS5371A CS5372A PERFORMANCE PLOTS Figure 2. Modulator Noise Performance Figure 3. Modulator + CS4373A Test DAC Dynamic Performance DS748F1 9 CS5371A CS5372A DIGITAL CHARACTERISTICS Parameter Digital Inputs High-level Input Voltage Low-level Input Voltage Input Leakage Current Digital Input Capacitance Input Rise Times Except MCLK Input Fall Times Except MCLK Digital Outputs High-level Output Voltage, Iout = -40 A Low-level Output Voltage, Iout = 40 A High-Z Leakage Current Digital Output Capacitance Output Rise Times Output Fall Times (Note 9) (Note 9) (Note 9) (Note 9) (Note 9) VOH VOL IOZ COUT tRISE tFALL VD - 0.3 9 0.3 10 100 100 V V A pF ns ns (Note 9) (Note 9) (Note 9) (Note 9, 18) (Note 9, 18) VIH VIL IIN CIN tRISE tFALL 0.6*VD 0.0 1 9 VD 0.8 10 100 100 V V A pF ns ns Symbol Min Typ Max Unit Notes: 18. Device is intended to be driven with CMOS logic levels. t rise t fall 0.9 * VD 0.1 * VD Figure 4. Digital Input Rise and Fall Times t rise t fall 0.9 * VD 0.1 * VD Figure 5. Digital Output Rise and Fall Times 10 DS748F1 CS5371A CS5372A DIGITAL CHARACTERISTICS (CONT.) Parameter Master Clock Input MCLK Frequency MCLK Period MCLK Duty Cycle MCLK Rise Time MCLK Fall Time MCLK Jitter (in-band or aliased in-band) MCLK Jitter (out-of-band) Master Sync Input MSYNC Setup Time to MCLK Falling MSYNC Period MSYNC Hold Time after MCLK Falling MDATA Output MDATA Output Bit Rate MDATA Output Bit Period MDATA Output One's Density Range Full-scale Output Code (Note 9) (Note 21) fmdata tmdata MDATOD MDATFS 14 0xA2EBE0 Symbol (Note 19) (Note 19) (Note 9) (Note 9) (Note 9) (Note 9) fCLK tmclk MCLKDC tRISE tFALL MCLKIBJ Min 40 20 40 20 Typ 2.048 488 122 976 122 512 1953 - Max 60 50 50 300 1 86 0x5D1420 Unit MHz ns % ns ns ps ns ns ns ns kbits/s ns % (Note 9) MCLKOBJ (Note 9, 20) (Note 9, 20) (Note 9, 20) tmss tmsync tmsh Notes: 19. MCLK is generated by the digital filter. If MCLK is disabled, the device automatically enters a powerdown state. 20. MSYNC is generated by the digital filter and is latched on MCLK falling edge, synchronization instant (t0) is on the next MCLK rising edge. 21. Decimated, filtered, and offset-corrected 24-bit output word from the digital filter. DS748F1 11 CS5371A CS5372A DIGITAL CHARACTERISTICS (CONT.) SYNC MCLK (2.048 MHz) MSYNC t0 MDATA (512 kHz) MFLAG TDATA (256 kHz) Figure 6. System Timing Diagram MCLK (2.048 MHz) tmss tmsh tmclk MSYNC t0 tmsync MDATA (512 kHz) tmdata MFLAG Figure 7. MCLK / MSYNC Timing Detail 12 DS748F1 CS5371A CS5372A POWER SUPPLY CHARACTERISTICS Parameter Power Supply Current, CS5371A Analog Power Supply Current Digital Power Supply Current Power Supply Current, CS5372A ch1 + ch2 Analog Power Supply Current Digital Power Supply Current Analog Power Supply Current Digital Power Supply Current Power Down Current, MCLK enabled Analog Power Supply Current Digital Power Supply Current Power Down Current, MCLK disabled Analog Power Supply Current Digital Power Supply Current Power Down Timing (after MCLK disabled) Power Supply Rejection Power Supply Rejection Ratio (Note 23) PSRR 100 dB (Note 22) (Note 22) (Note 9) IA ID PDTC 1 1 40 A A S (Note 22) (Note 22) IA ID 0.5 75 mA A (Note 22) (Note 22) (Note 22) (Note 22) IA ID IA ID 9 75 5 75 11 125 6 125 mA A mA A (Note 22) (Note 22) IA ID 5 75 6 125 mA A Symbol Min Typ Max Unit Power Supply Current, CS5372A ch1 or ch2 only Notes: 22. All outputs unloaded. Digital inputs forced to VD or GND respectively. 23. Power supply rejection is characterized by applying a 100 mVp-p 50 Hz sine wave to each supply. DS748F1 13 CS5371A CS5372A 2. SYSTEM DIAGRAM Differential Sensor CS3301A CS3302A M U X AMP CS5371A CS5372A Modulator Differential Sensor CS3301A CS3302A M U X AMP CS5376A Controller or Configuration EEPROM Digital Filter Differential Sensor CS3301A CS3302A M U X AMP CS5371A CS5372A System Telemetry Modulator Differential Sensor CS3301A CS3302A CS4373A M U X AMP Test DAC Figure 8. System Block Diagram VA+ 0.1F 0.01F VD VD VA+ VA+ VA+ 680 VD MDATA1 MFLAG1 PWDN1 MDATA1 MFLAG1 GPIO VDD2 OUTR+ CS3301A OUTF+ CS3302A AMPLIFIER OUTFOUTRVA- INR+ INF+ 680 680 20nF C0G 20nF C0G INFINR680 VAVA+ 10 MCLK MSYNC VREF 2.5 V VREF+ 100F 0.01F MCLK MSYNC CS5376A Digital Filter CS5372A Modulator VREFOFST GPIO VAVA+ VA+ 680 OUTR+ CS3301A OUTF+ CS3302A AMPLIFIER OUTFOUTRVA- INRINF680 680 20nF C0G 20nF C0G INF+ INR+ 680 MDATA2 MFLAG2 PWDN2 VAGND MDATA2 MFLAG2 GPIO GND VAVA0.1F Figure 9. Connection Diagram 14 DS748F1 CS5371A CS5372A VA+ PWDN VD VA+ PWDN1 VD MFLAG1 MFLAG INR+ INF+ INFINRVREF+ VREF4th Order Modulator MDATA INR1+ INF1+ INF1INR1VREF+ VREFINR2+ INF2+ INF2INR2- 4th Order Modulator MDATA1 Clock Generator MCLK MSYNC MFLAG2 Clock Generator MCLK MSYNC 4th Order Modulator MDATA2 CS5371A VAOFST GND VAPWDN2 OFST CS5372A GND Figure 10. CS5371A and CS5372A Block Diagrams 3. MODULATOR OPERATION The CS5371A and CS5372A are one- and two-channel, fourth-order modulators optimized for extremely high-resolution measurement of signals between DC and 2000 Hz. When combined with CS3301A / CS3302A differential amplifiers, the CS4373A test DAC and CS5376A digital filter, a small, low-power, self-testing, high-accuracy, multi-channel measurement system results. The CS5371A and CS5372A modulators have high dynamic range and low total harmonic distortion with very low power consumption and are optimized for extremely high-resolution measurement of 5 Vp-p or smaller differential signals. They convert analog input signals from the CS3301A / CS3302A differential amplifiers to an oversampled serial bit stream at 512 kbits per second which is then passed to the digital filter. The companion CS5376A digital filter generates the clock and synchronization inputs for the CS5371A / CS5372A modulators while receiving the one-bit data and over-range flag outputs. The digital filter decimates the modulator's oversampled output bit stream to a high-resolution, 24-bit output at the selected output word rate. 3.1 One's Density In normal operation a differential analog input signal is converted to an oversampled serial bit stream on the MDATA output, with a one's density proportional to the differential amplitude of the analog input signal. One's density of the MDATA output is defined as the ratio of `1' bits to total bits in the serial bit stream output, i.e. an 86% one's density has, on average, a `1' value in 86 of every 100 output data bits. The MDATA output has a nominal 50% one's density for a mid-scale differential input, approximately 86% one's density for a positive full-scale input signal, and approximately 14% one's density for a negative full-scale input signal. DS748F1 15 CS5371A CS5372A 3.4 Idle Tones The CS5371A and CS5372A are delta-sigmatype modulators and so can produce "idle tones" in the measurement bandwidth when the differential input signal is a steady-state DC signal near mid-scale. Idle tones result from low-frequency patterns in the output data stream and appear in the measurement spectrum as small tones about -135 dB down from full scale. If the OFST pin is pulled high, idle tones are eliminated within the modulator by adding -60 mV (channel 1 of CS5371A and CS5372A) or -35 mV (channel 2 of CS5372A) of internal differential offset during conversion to push idle tones out of the measurement bandwidth. Care should be taken to ensure external offset voltages do not negate the internally added differential offset, or idle tones will re-appear. 3.5 Stability The CS5371A and CS5372A modulators have a fourth-order architecture which is conditionally stable and may go into an oscillatory condition if the analog inputs are over-ranged more than 5% past either positive or negative full scale. If an unstable condition is detected, the modulator collapses to a first-order system and transitions the MFLAG output low-to-high to signal an error condition to the CS5376A digital filter. The analog input signal must be reduced to within the full-scale range for at least 32 MCLK cycles for the modulator to recover from an oscillatory condition. If the analog input remains over-ranged for an extended period, the modulator will cycle between fourth-order and firstorder operation and the MFLAG output will be seen to pulse. Modulator Differential Analog Input Signal > + (VREF+5%) + VREF 0V - VREF > - (VREF+5%) CS5376A Digital Filter 24-Bit Output Code Offset Corrected 5D1420 000000 A2EBE0 -60 mV Offset 5AD840 FDC420 A527C0 -35 mV Offset 5BC688 FEB268 A43978 Error Flag Possible Error Flag Possible Table 1. 24-Bit Output Coding for the CS5371A and CS5372A Modulator and CS5376A Digital Filter Combination 3.2 Decimated 24-bit Output When the CS5371A and CS5372A modulator operates with the CS5376A digital filter, the final decimated, 24-bit, full-scale output code range depends if digital offset correction is enabled. With digital offset correction enabled within the digital filter, amplifier offset and the modulator internal offset are removed from the final conversion result. 3.3 Synchronization The modulator is designed to operate synchronously with other modulators in a distributed measurement network, so a rising edge on the MSYNC input resets the internal conversion state machine to synchronize analog sample timing. MSYNC is automatically generated by the CS5376A digital filter after receiving a synchronization signal from the external system, and is chip-to-chip accurate within 1 MCLK period. 16 DS748F1 CS5371A CS5372A VA+ 0.1F 0.01F VD VD VA+ VA+ VA+ 680 VD MDATA1 MFLAG1 PWDN1 MDATA1 MFLAG1 GPIO VDD2 CS3301A CS3302A AMPLIFIER OUTFOUTRVAVAVA+ OUTR+ OUTF+ 680 680 20nF C0G 20nF C0G INR+ INF+ INFINR680 MCLK MSYNC 10 MCLK MSYNC CS5376A Digital Filter VREF 2.5 V VAVA+ VA+ 680 VREF+ 100F 0.01F CS5372A Modulator VREFOFST GPIO OUTR+ CS3301A OUTF+ CS3302A AMPLIFIER OUTFOUTRVA- INRINF680 680 20nF C0G 20nF C0G INF+ INR+ 680 MDATA2 MFLAG2 PWDN2 VAGND MDATA2 MFLAG2 GPIO GND VAVA0.1F Figure 11. Analog Signals 4. ANALOG SIGNALS The CS5371A and CS5372A modulators have differential analog inputs which are separated into rough and fine charge differential pairs (INR, INF) to maximize sampling accuracy. Both sets of modulator inputs require a simple differential anti-alias RC filter to ensure highfrequency signals do not alias into the measurement bandwidth. 4.1 INR, INF Modulator Inputs The modulator analog inputs are separated into differential rough and fine signals (INR, INF). The positive half of the differential input signal is connected to INR+ and INF+, while the negative half is attached to INF- and INR-. The INR pins are switched-capacitor `rough charge' inputs that pre-charge the internal analog sampling capacitor before it is connected to the INF fine input pins. 4.2 Input Impedance The modulator inputs have a dynamic switched-capacitor architecture and so have a rough charge input impedance that is inversely proportional to the input master clock frequency and the input capacitor size, [1 / (f x C)]. * * * MCLK = 2.048 MHz INR Internal Input Capacitor = 20 pF Impedance = [1 / (2.048 MHz * 20 pF)] = 24 k. Internal to the modulator, the rough inputs (INR) pre-charge the sampling capacitor used by the fine inputs (INF), therefore the input current to the fine inputs is typically very low and the effective input impedance is orders of magnitude above the impedance of the rough inputs. DS748F1 17 CS5371A CS5372A 4.3 Anti-alias Filter The modulator inputs are required to be bandwidth limited to ensure modulator loop stability and prevent high-frequency signals from aliasing into the measurement bandwidth. The use of simple, single-pole, differential, low-pass RC filters across the INR and INF inputs ensures high-frequency signals are rejected before they can alias into the measurement bandwidth. The CS3301A / CS3302A differential amplifiers are designed with separate rough and fine analog outputs (OUTR, OUTF) that match the modulator rough and fine inputs (INR, INF). External anti-alias series resistors and external differential capacitors are required to create the anti-alias RC filters. The approximate -3 dB corner of the input antialias filter is nominally set to the internal analog sampling rate divided by 64, which itself is a division by 4 of the MCLK rate. * * * * MCLK Frequency = 2.048 MHz Sampling Frequency = MCLK / 4 = 512 kHz -3 dB Filter Corner = Sampling Freq / 64 = 8 kHz RC filter = 1 / [ 2 x (2 x Rseries) x Cdiff ] ~ 8 kHz ing X7R-type capacitors on the fine analog inputs will significantly degrade total harmonic distortion performance. 4.4 Analog Differential Signals Differential analog signals into the CS5371A and CS5372A consist of two halves with equal but opposite magnitude varying about a common mode voltage. A full-scale, 5 VP-P, differential signal centered on a -0.15 V common mode voltage will have: SIG+ = -0.15 V + 1.25 V = +1.1 V SIG- = -0.15 V - 1.25 V = -1.4 V SIG+ is +2.5 V relative to SIGFor the opposite case: SIG+ = -0.15 V - 1.25 V = -1.4 V SIG- = -0.15 V + 1.25 V = +1.1 V SIG+ is -2.5 V relative to SIGSo the total swing for SIG+ relative to SIG- is (+2.5 V) - (-2.5 V) = 5 Vp-p differential. A similar calculation can be done for SIG- relative to SIG+. It's important to note that a 5 Vp-p differential signal centered on a -0.15 V common mode voltage never exceeds +1.1 V with respect to ground and never drops below -1.4 V with respect to ground on either half. By definition, differential voltages are measured with respect to the opposite half, not relative to ground. A voltmeter differentially measuring between SIG+ and SIG- in the above example would correctly read 1.767 Vrms, or 5 Vp-p. illustrates the CS5371A and CS5372A modulator analog connections with input anti-alias filter components. Filter components on the rough and fine pins should be identical values for optimum performance, with the capacitor values a minimum of 0.02 F. The rough input can use either X7R- or C0Gtype capacitors, while the fine input requires C0G-type capacitors for optimal linearity. UsFigure 9 on page 14 18 DS748F1 CS5371A CS5372A VA+ 0.1F 0.01F VD VD VA+ VA+ VA+ 680 VD MDATA1 MFLAG1 PWDN1 MDATA1 MFLAG1 GPIO VDD2 CS3301A CS3302A AMPLIFIER OUTFOUTRVAVAVA+ OUTR+ OUTF+ 680 680 20nF C0G 20nF C0G INR+ INF+ INFINR680 MCLK MSYNC 10 MCLK MSYNC CS5376A Digital Filter VREF 2.5 V VAVA+ VA+ 680 VREF+ 100F 0.01F CS5372A Modulator VREFOFST GPIO CS3301A CS3302A AMPLIFIER OUTFOUTRVAVA- OUTR+ OUTF+ 680 680 20nF C0G 20nF C0G INRINFINF+ INR+ 680 MDATA2 MFLAG2 PWDN2 VAGND MDATA2 MFLAG2 GPIO GND VA0.1F Figure 12. Digital Signals 5. DIGITAL SIGNALS The CS5371A and CS5372A modulators are designed to operate with the CS5376A digital filter. The digital filter generates the modulator clock and synchronization signals (MCLK and MSYNC) while receiving back the modulator one-bit conversion data and over-range flag (MDATA and MFLAG). 5.1 MCLK Connection The CS5376A digital filter generates the master clock for CS5371A and CS5372A, typically 2.048 MHz, from a synchronous clock input from the external system. If MCLK is disabled during operation, the modulators will enter a power down state after approximately 40 S. By default, MCLK is disabled at reset and is enabled by writing the digital filter CONFIG register. MCLK must have low jitter to guarantee full analog performance, requiring a crystal- or VCXO-based system clock input to the digital filter. Clock jitter on the digital filter CLK input directly translates to jitter on MCLK. 5.2 MSYNC Connection The CS5376A digital filter also provides a synchronization signal to the CS5371A and CS5372A modulators. The MSYNC signal is automatically generated following a rising edge received on the digital filter SYNC input. By default, MSYNC generation is disabled at reset and is enabled by writing the digital filter CONFIG register. The input SYNC signal to the CS5376A digital filter sets a common reference time t0 for measurement events, thereby synchronizing analog sampling across a measurement network. The timing accuracy of the received SYNC signal from measurement node to measurement node must be 1 MCLK to maximize the DS748F1 19 CS5371A CS5372A MSYNC analog sample synchronization accuracy. The CS5371A and CS5372A MSYNC input is rising-edge triggered and resets the internal MCLK counter/divider to guarantee synchronous operation with other system devices. While the MSYNC signal synchronizes the internal operation of the modulators, by default, it does not synchronize the phase of the sine wave from the CS4373A test DAC unless enabled in the digital filter TBSCFG register. 5.3 MDATA Connection During normal operation the CS5371A and CS5372A modulators output a serial bit stream to the MDATA pin, with a one's density proportional to the differential amplitude of the analog input signal. The output bit rate from the MDATA output is a divide-by-four of the input MCLK, and so is nominally 512 kHz. The MDATA output has a 50% one's density for a mid-scale analog input, approximately 86% one's density for a positive full-scale analog input, and approximately 14% one's density for a negative full-scale analog input. One's density of the MDATA output is defined as the ratio of `1' bits to total bits in the serial bit stream output; i.e. an 86% one's density has, on average, a `1' value in 86 of every 100 output data bits. 5.4 MFLAG Connection The CS5371A and CS5372A modulators have a fourth-order architecture which is conditionally stable and may go into an oscillatory condition if the analog inputs are over-ranged more than 5% past either positive or negative full-scale. When an unstable condition is detected, the modulator automatically collapses to a first-order system to regain stability and then transitions the MFLAG output low-to-high to signal an error condition to the CS5376A digital filter. The MFLAG output connects to a dedicated input on the digital filter, causing an error flag to be set in the status byte of the next output data word. For the modulator to recover from an unstable condition, the analog input signal must be reduced to within the full-scale input range for at least 32 MCLK cycles. If the analog input remains over-ranged for an extended period, the modulator will cycle between fourth-order and first-order operation and the MFLAG output will be seen to pulse. 5.5 OFST Connection The CS5376A controls 12 general-purpose input output (GPIO) pins through the digital filter GPCFG register. These GPIO pins can be assigned to operate the CS5371A and CS5372A OFST and PWDN pins. If the OFST pin is pulled high, idle tones are eliminated within the modulator by adding -60 mV (channel 1 of CS5371A and CS5372A) or -35 mV (channel 2 of CS5372A) of internal differential offset during conversion to push idle tones out of the measurement bandwidth. Care should be taken to ensure external offset voltages do not negate the internally added differential offset, or idle tones will re-appear. 20 DS748F1 CS5371A CS5372A POWER DOWN MCLK = OFF PWDN = X NORMAL OPERATION MCLK = ON PWDN = 0 POWER DOWN MCLK = ON PWDN = 1 Figure 13. Power Mode Diagram 6. POWER MODES The CS5371A and CS5372A modulators have three power modes. Normal operation, power down with MCLK enabled, and power down with MCLK disabled. 6.1 Normal Operation With MCLK active and the PWDN pin driven low, the CS5371A and CS5372A modulators perform normal data acquisition. A differential analog input signal is converted to an oversampled 1-bit bit stream at 512 kHz. This bit stream is then digitally filtered and decimated by the CS5376A device to a high-precision 24-bit output. 6.2 Power Down, MCLK Enabled With MCLK active and the PWDN pin driven high, the CS5371A and CS5372A modulators are placed into a power-down state. During this power-down state the modulators are disabled and all outputs are high impedance. 6.3 Power Down, MCLK Disabled If MCLK is stopped, an internal loss-of-clock detection circuit automatically places the CS5371A and CS5372A into a power-down state. This power-down state is independent of the PWDN pin setting and is automatically invoked after approximately 40 s without receiving an incoming MCLK edge. During this power-down state, the modulators are disabled and all outputs are high impedance. When used with the CS5376A digital filter, the CS5371A and CS5372A are in this power-down state immediately after reset since MCLK is disabled by default. DS748F1 21 CS5371A CS5372A From VA+ Regulator 100 F 0.1 F 10 2.500 V VREF 0.1 F Route VREF as a differential pair from the 100uF RC filter capacitor + 100 F 0.1 F To VREF+ From VARegulator 100 F 0.1 F 0.1 F To VREF- Figure 14. Voltage Reference Circuit 7. VOLTAGE REFERENCE The CS5371A and CS5372A modulators require a 2.500 V precision voltage reference to be supplied to the VREF pins. 7.1 VREF Power Supply To guarantee proper regulation headroom for the voltage reference device, the voltage reference GND pin should be connected to VA- instead of system ground, as shown in Figure 14. This connection results in a VREFvoltage equal to VA- and a VREF+ voltage very near ground [(VA-) + 2.500 VREF]. Power supply inputs to the voltage reference device should be bypassed to system ground with 0.1 F capacitors placed as close as possible to the power and ground pins. In addition to 0.1 F local bypass capacitors, at least 100 F of bulk capacitance to system ground should be placed on each power supply near the voltage regulator outputs. Bypass capacitors should be X7R, C0G, tantalum, or other high-quality dielectric type. 7.2 VREF RC Filter A primary concern in selecting a precision voltage reference device is noise performance in the measurement bandwidth. The Linear Technology LT1019AIS8-2.5 voltage reference yields acceptable noise levels if the output is filtered with a low-pass RC filter. A separate RC filter is required for each system device connected to a given voltage refer22 ence output. By sharing a common RC filter, signal-dependent sampling of the voltage reference by one system device could cause unwanted tones to appear in the measurement bandwidth of another system device via common impedance coupling. 7.3 VREF PCB Routing To minimize the possibility of outside noise coupling into the CS5371A and CS5372A voltage reference input, the VREF traces should be routed as a differential pair from the large capacitor of the voltage reference RC filter. Careful control of the voltage reference source and return currents by routing VREF as a differential pair will significantly improve immunity from external noise. To further improve noise rejection of the VREF differential route, include 0.1 F bypass capacitors to system ground as close as possible to the VREF+ and VREF- pins of the CS5371A and CS5372A. 7.4 VREF Input Impedance The switched-capacitor input architecture of the VREF inputs results in an input impedance that depends on the internal capacitor size and the MCLK frequency. With a 15 pF internal capacitor and a 2.048 MHz MCLK, the VREF input impedance is approximately 1 / [(2.048 MHz) x (15 pF)] = 32 k. While the size of the internal capacitor is fixed, the voltDS748F1 CS5371A CS5372A age reference input impedance will vary with MCLK. The voltage reference external RC filter series resistor creates a voltage divider with the VREF input impedance to reduce the effective applied input voltage. To minimize gain error resulting from this voltage divider effect, the RC filter series resistor should be the minimum size recommended in the voltage reference device data sheet. 7.5 VREF Accuracy The nominal voltage reference input is specified as 2.500 V across the VREF pins, and all CS5371A and CS5372A gain accuracy specifications are measured using a nominal voltage reference input. Any variation from a nominal VREF input will proportionally vary the analog full-scale gain accuracy. Since temperature drift of the voltage reference results in gain drift of the analog full-scale amplitude, care should be taken to minimize temperature drift effects through careful selection of passive components and the voltage reference device itself. Gain drift specifications of the CS5371A and CS5372A do not include the temperature drift effects of external passive components or of the voltage reference device itself. DS748F1 23 CS5371A CS5372A To VA+ Regulator 100 uF 0.1 uF VA+ VD 0.1 uF 100 uF To VD Regulator CS5371A CS5372A VATo VARegulator 100 uF 0.1 uF GND Figure 15. Power Supply Diagram 8. POWER SUPPLIES The CS5371A and CS5372A modulators have a positive analog power supply pin (VA+), a negative analog power supply pin (VA-), a digital power supply pin (VD), and a ground pin (GND). For proper operation, power must be supplied to all power supply pins, and the ground pin must be connected to system ground. The CS5371A and CS5372A digital power supply (VD) and the CS5376A digital power supply (VDD) must share a common voltage. 8.1 Power Supply Bypassing The VA+, VA-, and VD power supplies should be bypassed to system ground with 0.1 F capacitors placed as close as possible to the power pins of the device. In addition to the 0.1 F local bypass capacitors, at least 100 F bulk capacitance to system ground should be placed on each power supply near the voltage regulator output, with additional power supply bulk capacitance placed among the analog component route if space permits. Bypass capacitors should be X7R, C0G, tantalum, or other high-quality dielectric type. 8.2 PCB Layers and Routing The CS5371A and CS5372A are high-performance devices, and special care must be taken to ensure power and ground routing is correct. Power can be supplied either through dedicated power planes or routed traces. When routing power traces, it is recommended to use a "star" routing scheme with the star point either at the voltage regulator output or at a local power supply bulk capacitor. It is also recommended to dedicate a full PCB layer to a solid ground plane, without splits or routing. All bypass capacitors should connect between the power supply circuit and the solid ground plane as near as possible to the device power supply pins. The CS5371A and CS5372A analog signals are differentially routed and do not normally require connection to a separate analog ground. However, if a separate analog ground is required, it should be routed using a "star" routing scheme on a separate layer from the solid ground plane and connected to the ground plane only at a single point. Be sure all active devices and passive components connected to the separate analog ground are included in the "star" route to ensure sensitive analog currents do not return through the ground plane. 8.3 Power Supply Rejection Power supply rejection of the CS5371A and CS5372A is frequency dependent. The CS5376A digital filter fully rejects power supply noise for frequencies above the selected digital filter corner frequency. Power supply noise frequencies between DC and the digital filter corner frequency are rejected as specified in the Power Supply Characteristics table. DS748F1 24 CS5371A CS5372A 8.4 SCR Latch-up Considerations It is recommended to connect the VA- power supply to system ground (GND) with a reverse-biased Schottky diode. At power up, if the VA+ power supply ramps up before the VA- supply is established, the VA- pin voltage could be pulled above ground potential through the CS5371A and CS5372A device. If the VA- supply is pulled 0.7 V or more above GND, SCR latch-up can occur. A reverse-biased Schottky diode will clamp the VA- voltage a maximum of 0.3 V above ground to ensure SCR latch-up does not occur at power up. 8.5 DC-DC Converters Many low-frequency measurement systems are battery powered and utilize DC-DC converters to efficiently generate power supply voltages. To minimize interference effects, operate the DC-DC converter at a frequency which is rejected by the digital filter, or operate it synchronous to the MCLK rate. A synchronous DC-DC converter whose operating frequency is derived from MCLK will theoretically minimize the potential for "beat frequencies" to appear in the measurement bandwidth. However this requires the source clock to remain jitter free within the DC-DC converter circuitry. If clock jitter can occur within the DC-DC converter (as in a PLL-based architecture), it's better to use a nonsynchronous DC-DC converter whose switching frequency is rejected by the digital filter. During PCB layout, do not place high-current DC-DC converters near sensitive analog components. Carefully routing a separate DC-DC "star" ground will help isolate noisy switching currents away from the sensitive analog components. DS748F1 25 CS5371A CS5372A 9. PIN DESCRIPTION - CS5371A Rough Non-Inverting Input Fine Non-Inverting Input Fine Inverting Input Rough Inverting Input Positive Voltage Reference Input Negative Voltage Reference Input Negative Analog Power Supply Positive Analog Power Supply No Internal Connection No Internal Connection No Internal Connection No Internal Connection INR+ INF+ INFINRVREF+ VREFVAVA+ NC NC NC NC 1 2 3 4 24 23 22 21 PWDN GND MFLAG MDATA MSYNC MCLK VD GND NC NC OFST VD Power-down Enable Digital Ground Modulator Flag Output Modulator Data Output Modulator Sync Input Modulator Clock Input Positive Digital Power Supply Digital Ground No Internal Connection No Internal Connection Offset Mode Select Positive Digital Power Supply 5 6 7 20 19 18 8 9 10 11 12 17 16 15 14 13 Power Supplies VA+ VAVD _ _ _ Positive Analog Power Supply, pin 8 Negative Analog Power Supply, pin 7 Positive Digital Power Supply, pin 13, 18 _ GND Ground, pin 17, 23 Analog Inputs INR+ _ Rough Non-Inverting Input, pin 1 Rough non-inverting analog input. The rough input settles non-linear currents to improve linearity on the fine input and reduce harmonic distortion. INF+ _ Fine Non-Inverting Input, pin 2 Fine non-inverting analog input. INF- _ Fine Inverting Input, pin 3 Fine inverting analog input. _ INR- Rough Inverting Input, pin 4 Rough inverting analog input. The rough input settles non-linear currents to improve linearity on the fine input and reduce harmonic distortion. 26 DS748F1 CS5371A CS5372A VREF+ _ Positive Voltage Reference Input, pin 5 Input for an external +2.500 V voltage reference relative to VREF-. VREF- _ Negative Voltage Reference Input, pin 6 This pin should be tied to VA- near the voltage reference output. Digital Inputs MCLK _ Modulator Clock Input, pin 19 A CMOS compatible clock input for the modulator internal master clock, nominally 2.048 MHz with an amplitude equal to the VD digital power supply. MSYNC _ Modulator Sync Input, pin 20 A low to high transition resets the internal clock phasing of the modulator. This assures the sampling instant and modulator data output are synchronous to the external system. OFST _ Offset Mode Select, pin 14 When high, adds approximately -60 mV or -35 mV of internal differential offset to the analog input signal to guarantee any idle tones are removed. When low, no offset is added. PWDN _ Power-down Mode, pin 24 When high, the modulator is in power-down mode. Halting MCLK while in power down mode reduces modulator power dissipation further. Digital Outputs MDATA _ Modulator Data Output, pin 21 Modulator data is output as a 1-bit serial data stream at 512 kHz with an MCLK input of 2.048 MHz. MFLAG _ Modulator Flag Output, pin 22 A high level output indicates the modulator is unstable due to an over-range on the analog inputs. DS748F1 27 CS5371A CS5372A 10. PIN DESCRIPTION - CS5372A Ch. 1 Rough Non-Inverting Input Ch. 1 Fine Non-Inverting Input Ch. 1 Fine Inverting Input Ch. 1 Rough Inverting Input Positive Voltage Reference Input Negative Voltage Reference Input Negative Analog Power Supply Positive Analog Power Supply Ch. 2 Rough Inverting Input Ch. 2 Fine Inverting Input Ch. 2 Fine Non-Inverting Input Ch. 2 Rough Non-Inverting Input INR1+ INF1+ INF1INR1VREF+ VREFVAVA+ INR2INF2INF2+ INR2+ 1 2 3 4 24 23 22 21 PWDN1 GND MFLAG1 MDATA1 MSYNC MCLK VD GND MDATA2 MFLAG2 OFST PWDN2 Ch. 1 Power-down Enable Digital Ground Ch. 1 Modulator Flag Output Ch. 1 Modulator Data Output Modulator Sync Input Modulator Clock Input Positive Digital Power Supply Digital Ground Ch. 2 Modulator Data Output Ch. 2 Modulator Flag Output Offset Mode Select Ch. 2 Power-down Enable 5 6 7 20 19 18 8 9 10 11 12 17 16 15 14 13 Power Supplies VA+ VAVD _ _ _ Positive Analog Power Supply, pin 8 Negative Analog Power Supply, pin 7 Positive Digital Power Supply, pin 18 _ GND Ground, pin 17, 23 Analog Inputs INR1+, INR2+ _ Channel 1 & 2 Rough Non-Inverting Inputs, pin 1, 12 Rough non-inverting analog inputs. The rough inputs settle non-linear currents to improve linearity on the fine inputs and reduce harmonic distortion. INF1+, INF2+ _ _ Channel 1 & 2 Fine Non-Inverting Input, pin 2, 11 Fine non-inverting analog inputs. INF1-, INF2- Channel 1 & 2 Fine Inverting Input, pin 3, 10 Fine inverting analog inputs. INR1-, INR2- _ Channel 1 & 2 Rough Inverting Inputs, pin 4, 9 Rough inverting analog inputs. The rough inputs settle non-linear currents to improve linearity on the fine inputs and reduce harmonic distortion. 28 DS748F1 CS5371A CS5372A VREF+ _ Positive Voltage Reference Input, pin 5 Input for an external +2.5 V voltage reference relative to VREF-. VREF- _ Negative Voltage Reference Input, pin 6 This pin should be tied to VA- near the voltage reference output. Digital Inputs MCLK _ Modulator Clock Input, pin 19 A CMOS compatible clock input for the modulator internal master clock, nominally 2.048 MHz with an amplitude equal to the VD digital power supply. MSYNC _ Modulator Sync Input, pin 20 A low to high transition resets the internal clock phasing of the modulator. This assures the sampling instant and modulator data output are synchronous to the external system. OFST _ Offset Mode Select, pin 14 When high, adds approximately -60 mV or -35 mV of internal differential offset to the analog input signal to guarantee any idle tones are removed. When low, no offset is added. PWDN1, PWDN2 _ Channel 1 & 2 Power-down Mode, pin 24, 13 When high, the modulator is in power down mode. Halting MCLK while in power down mode reduces modulator power dissipation further. Digital Outputs MDATA1, MDATA2 _ Modulator Data Output, pin 21, 16 Modulator data is output as a 1-bit serial data stream at 512 kHz with an MCLK input of 2.048 MHz. MFLAG1, MFLAG2 _ Modulator Flag, pin 22, 15 A high level output indicates the modulator is unstable due to an over-range on the analog inputs. DS748F1 29 CS5371A CS5372A 11.PACKAGE DIMENSIONS 24 PIN SSOP PACKAGE DRAWING N D E11 A2 A1 L E A e b2 SIDE VIEW END VIEW SEATING PLANE 123 TOP VIEW INCHES DIM A A1 A2 b D E E1 e L MIN -0.002 0.064 0.009 0.311 0.291 0.197 0.024 0.025 0 MAX 0.084 0.010 0.074 0.015 0.335 0.323 0.220 0.027 0.040 8 MILLIMETERS MIN MAX -2.13 0.05 0.25 1.62 1.88 0.22 0.38 7.90 8.50 7.40 8.20 5.00 5.60 0.61 0.69 0.63 1.03 0 8 NOTE 2,3 1 1 Notes: 1. "D" and "E1" are reference datums and do not included mold flash or protrusions, but do include mold mismatch and are measured at the parting line, mold flash or protrusions shall not exceed 0.20 mm per side. 2. Dimension "b" does not include dambar protrusion/intrusion. Allowable dambar protrusion shall be 0.13 mm total in excess of "b" dimension at maximum material condition. Dambar intrusion shall not reduce dimension "b" by more than 0.07 mm at least material condition. 3. These dimensions apply to the flat section of the lead between 0.10 and 0.25 mm from lead tips. 30 DS748F1 CS5371A CS5372A 12. ORDERING INFORMATION Model Temperature Package CS5371A-ISZ (lead free) CS5372A-ISZ (lead free) -40 to +85 C 24-pin SSOP 13.ENVIRONMENTAL, MANUFACTURING, & HANDLING INFORMATION Model Number Peak Reflow Temp MSL Rating* Max Floor Life CS5371A-ISZ (lead free) CS5372A-ISZ (lead free) 260 C 3 7 Days * MSL (Moisture Sensitivity Level) as specified by IPC/JEDEC J-STD-020. DS748F1 31 CS5371A CS5372A 14.REVISION HISTORY Revision PP1 F1 Date OCT 2006 DEC 2006 Preliminary release. Updated to final status with most-recent characterization data for Cirrus QPL process. Changes Contacting Cirrus Logic Support For all product questions and inquiries contact a Cirrus Logic Sales Representative. To find the one nearest to you go to www.cirrus.com IMPORTANT NOTICE 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, indemnification, 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 associated with 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 products 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. 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 FOR USE IN AIRCRAFT SYSTEMS, MILITARY APPLICATIONS, PRODUCTS SURGICALLY IMPLANTED INTO THE BODY, AUTOMOTIVE SAFETY OR SECURITY DEVICES, LIFE SUPPORT PRODUCTS OR OTHER CRITICAL APPLICATIONS. INCLUSION OF CIRRUS PRODUCTS IN SUCH APPLICATIONS IS UNDERSTOOD TO BE FULLY AT THE CUSTOMER'S RISK AND CIRRUS DISCLAIMS AND MAKES NO WARRANTY, EXPRESS, STATUTORY OR IMPLIED, INCLUDING THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR PARTICULAR PURPOSE, WITH REGARD TO ANY CIRRUS PRODUCT THAT IS USED IN SUCH A MANNER. IF THE CUSTOMER OR CUSTOMER'S CUSTOMER USES OR PERMITS THE USE OF CIRRUS PRODUCTS IN CRITICAL APPLICATIONS, CUSTOMER AGREES, BY SUCH USE, TO FULLY INDEMNIFY CIRRUS, ITS OFFICERS, DIRECTORS, EMPLOYEES, DISTRIBUTORS AND OTHER AGENTS FROM ANY AND ALL LIABILITY, INCLUDING ATTORNEYS' FEES AND COSTS, THAT MAY RESULT FROM OR ARISE IN CONNECTION WITH THESE USES. 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. 32 DS748F1 |
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