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| www..com AN220E04 Datasheet Dynamically Reconfigurable FPAA www..com www.anadigm.com DS020700-U001e -1- www..com www..com 4U www..com Disclaimer Anadigm reserves the right to make any changes without further notice to any products herein. Anadigm makes no warranty, representation or guarantee regarding the suitability of its products for any particular purpose, nor does Anadigm assume any liability arising out of the application or use of any product or circuit, and specifically disclaims any and all liability, including with out limitation consequential or incidental damages. "Typical" parameters can and do vary in different applications. All operating parameters, including "Typicals" must be validated for each customer application by customer's technical experts. Anadigm does not in this document convey any license under its patent rights nor the rights of others. Anadigm software and associated products cannot be used except strictly in accordance with an Anadigm software license. The terms of the appropriate Anadigm software license shall prevail over the above terms to the extent of any inconsistency. www..com (c) Anadigm(R) Ltd. 2003 (c) Anadigm(R), Inc. 2003 All Rights Reserved. DS020700-U001e -2- www..com www..com 4U www..com AN220E04 Datasheet - Dynamically Reconfigurable FPAA PRODUCT AND ARCHITECTURE OVERVIEW The AN220E04 is the first member of Anadigm(R)'s second generation FPAA family - the Anadigmvortex family. Based on a fully differential switched-capacitor architecture, this new product family features higher bandwidth, improved total harmonic distortion (THD) and the ability to implement a host of advanced functions. The AN220E04 consists of a 2 x 2 matrix of fully configurable switched capacitor configurable analog blocks (CABs), enmeshed in a fabric of programmable interconnect resources. These programmable features are directed by an on-chip SRAM configuration memory. The four CABs have access to a single Look-Up Table (LUT) which can be used to implement non linear functions such as user-defined input-to-output transfer functions, and arbitrary signal waveform generation. Analog input signals come in from the outside world via the four input cells. The fourth input cell of the AN220E04 has a special `multiplexing' feature which allows the connection of up to four unique signal sources. An input cell can accept either a singleended signal or a differential signal pair. The input cells each have built-in programmable anti-aliasing filters, as well as a high gain amplifier which has an optional chopper stabilized operating mode designed for use with signals requiring significant gain and hence ultra low input offset voltages. The AN220E04 is also designed to support dynamic reconfiguration. There are two memories on the AN220E04: Figure 1: Architectural overview of the AN220E04 device Shadow SRAM and Configuration SRAM. The new reconfiguration data is stored in the Shadow SRAM, which can then be transferred to the Configuration SRAM at just a single clock edge providing for synchronized on-the-fly update of the analog circuit function. PRODUCT FEATURES * * * * * * * * * * * * * Dynamic reconfiguration Fully differential architecture Fully differential I/O buffering with options for single ended to differential conversion Low input offset through chopper stabilized amplifiers Built-in Successive Approximation Register (SAR) 256 Byte Look-Up Table (LUT) for linearization and arbitrary signal generation 4:1 Input multiplexer Typical Signal Bandwidth: DC-2MHz (Bandwidth is CAM dependent) Signal to Noise Ratio: o Broadband 80dB o Narrowband (audio) 100dB Total Harmonic Distortion (THD): 80dB DC offset <100V Package: 44-pin QFP (10x10x2mm) o Lead pitch 0.8mm Supply voltage: 5V APPLICATIONS * * * * * * * * * * Real-time software control of analog system peripherals Intelligent sensors Adaptive filtering and control Adaptive DSP front-end Adaptive industrial control and automation Self-calibrating systems Compensation for aging of system components Dynamic recalibration of remote systems Ultra-low frequency signal conditioning Custom analog signal processing www..com ORDERING CODES AN220E04-QFPSP AN220E04-QFPTY AN220E04-QFPTR AN220D04-EVAL AN220D04-DEVLP Dynamically reconfigurable FPAA Sample Pack Dynamically reconfigurable FPAA Tray (96 pcs) Dynamically reconfigurable FPAA Tape & Reel (1000 pcs) AN220E04 Evaluation Kit AN220E04 Development Kit [For more detailed information on the features of the AN220E04 device, please refer to the AN120E04/AN220E04 User Manual] DS020700-U001e -3- www..com www..com 4U www..com AN220E04 Datasheet - Dynamically Reconfigurable FPAA ELECTRICAL CHARACTERISTICS Absolute Maximum Ratings Parameter DC Power Supplies xVDD to xVDD Offset Package Power Dissipation Analog and Digital Input Voltage Ambient Operating Temperature Storage Temperature a Symbol AVDD(2) BVDD DVDD Pmax 25C Pmax 85C Vinmax Top Tstg Min -0.5 -0.5 Vss-0.5 -40 -65 Typ - Max 5.5 V 0.5 Unit V V W V C C Comment AVSS, BVSS, DVSS and SVSS all held to 0.0 V a Ideally all supplies should be at the same voltage Still air, No heatsink, 4 layer board, 44 pins. ja = 55C/W - 1.8 0.73 Vdd+0.5 85 150 Absolute Maximum DC Power Supply Rating - The failure mode is non-catastrophic for Vdd of up to 7 volts, but will cause reduced operating life time. The additional stress caused by higher local electric fields within the CMOS circuitry may induce metal migration, oxide leakage and other time/quality related issues. Recommended Operating Conditions Parameter DC Power Supplies Symbol AVDD(2) BVDD DVDD Vina Vind Tj Min 4.75 VMR-1.9 0 -40 Typ 5.00 - Max 5.25 VMR+1.9 DVDD 125 Unit V V V C Comment AVSS, BVSS, DVSS and SVSS all held to 0 V VMR is 2.0 volts above AVSS Assume a package ja = 55C/W b Analog Input Voltage. Digital Input Voltage Junction Temp b In order to calculate the junction temperature you must first empirically determine the current draw (total Idd) for the design. Once the current consumption established then the following formula can be used; Tj = Ta + Idd x Vdd x 55 C/W, where Ta is the ambient temperature. The worst case ja of 55 C/W assumes no air flow and no additional heatsink of any type. www..com Symbol Vih Vil Vol Voh Iil Iil Cmax Rmin Fmax Fmax - General Digital I/O Characteristics (Vdd = 5v +/- 10%, -40 to 85 deg.C) Parameter Input Voltage Low Input Voltage High Output Voltage Low Output Voltage High Input Leakage Current Input Leakage Current Max. Capacitive Load Min. Resistive Load DCLK Frequency ACLK Frequency Clock Duty Cycle Min 0 70 0 80 10 45 Typ 12.0 - Max 30 100 20 100 1.0 10 40 40 55 Unit A A pF Kohm MHz MHz % Comment % of DVDD % of DVDD % of DVDD % of DVDD All pins except DCLK DCLK if a crystal is connected and the on-chip oscillator is used The maximum load for a digital output is 10 pF // 10 Kohm The maximum load for a digital output is 10 pF // 10 Kohm For MODE = 1, Max DCLK is 16 MHz Divide down to <8 MHz prior to use as a CAB clock All clocks DS020700-U001e -4- www..com www..com 4U www..com AN220E04 Datasheet - Dynamically Reconfigurable FPAA Detailed Digital I/O Interface Characteristics: Vdd = 5.0volts LCCb Parameter Output Voltage Low Output Voltage High Max. Capacitive Load Min. Resistive Load Current Sink Current Source Symbol Vol Voh Cmax Rmin Isnkmax Isrcmax Min Vss 4.5 50 - Typ - Max 150 Vdd 20 15 4 Unit mV V pF Kohm mA mA Comment Load 20pF//50Kohm to Vss Load 20pF//50Kohm to Vss Maximum load 20 pF // 50 Kohm Maximum load 20 pF // 50 Kohm LCCb pin shorted to Vdd LCCb pin shorted to Vss CFGFLG, ACTIVATE Parameter Input Voltage Low Input Voltage High Output Voltage Low Output Voltage High Output Voltage Low Vol Output Voltage High Voh Max. Capacitive Load Min. Resistive Load Current Sink Current Source External Resistive Pullup Cmax Rmin Isnkmax Isrcmax 4.5 50 5 Vdd 50 2.5 200 10 V pF Kohm mA A Vss 200 mV Symbol Vil Vih Vol Voh Min 0 70 Vss 4.5 Typ Max 30 100 Unit % % mV V Comment % of DVDD % of DVDD Pin load = Internal pullup + 20pF//50K to Vss Pin load = Internal pullup + 20pF//50K to Vss Pin Load = External 5K ohm pullup + 20pF//50K to Vss Pin Load = External 5Kohm pullup + 20pF//50K to Vss Maximum load 50 pF // 50 Kohm Maximum load 50 pF // 50 Kohm Pin shorted to Vdd Pin shorted to Vss Use only if internal pullup is deselected - 85 Vdd www..com Rpullupext 7.5 Kohm ERRb Parameter Input Voltage Low Input Voltage High Output Voltage Low Output Voltage High Max. Capacitive Load Min. Resistive Load Current Sink Current Source External Resistive Pullup Symbol Vil Vih Vol Voh Cmax Rmin Isnkmax Isrcmax Rpullupext Min 0 70 Vss 4.9 50 10 Typ 10 Max 30 100 50 Vdd 50 10 0 10 Unit % % mV V pF Kohm mA A Kohm Comment % of DVDD % of DVDD Maximum load 50 pF // 50 Kohm Maximum load 50 pF // 50 Kohm DCLK,Mode,DIN,EXECUTE,PORb,CS1b,CS2b Parameter Input Voltage Low Input Voltage High Symbol Vil Vih Min 0 70 Typ - Max 30 100 Unit % % Comment % of DVDD % of DVDD DS020700-U001e -5- www..com www..com 4U www..com AN220E04 Datasheet - Dynamically Reconfigurable FPAA OUTCLK/SPIMEM,DOUTCLK Parameter Output Voltage Low Output Voltage High Max. Capacitive Load Min. Resistive Load Current Sink Current Source Symbol Vol Voh Cmax Rmin Isnkmax Isrcmax Min 0 80 10 - Typ - Max 20 100 50 17 4 Unit % % pF Kohm mA mA Comment % of DVDD % of DVDD Maximum load 50 pF // 50 Kohm Maximum load 50 pF // 50 Kohm ACLK/SPIP Parameter Input Voltage Low Input Voltage High Output Voltage Low Output Voltage High Max. Capacitive Load Min. Resistive Load Current Sink Current Source Symbol Vil Vih Vol Voh Cmax Rmin Isnkmax Isrcmax Min 0 70 0 80 10 - Typ - Max 30 100 20 100 50 15 4 Unit % % % % pF Kohm mA mA Comment % of DVDD % of DVDD % of DVDD % of DVDD Maximum load 50 pF // 50 Kohm Maximum load 50 pF // 50 Kohm www..com DS020700-U001e -6- www..com www..com 4U www..com AN220E04 Datasheet - Dynamically Reconfigurable FPAA Analog Inputs General Parameter High Precision Input Range c Standard precision Input Range d High Precision Differential Input c Standard Precision Differential Input d Common Mode Input Range Input Offset Input Frequency Symbol Vina Vina Vdiffina Vdiffina Vcm Vos Min 0.5 0.1 0 0 1.8 - Typ 2.0 5 Max 3.5 3.9 +/-3.0 +/-3.8 2.2 15 Unit V V V V V mV Comment VMR +/- 1.5v VMR +/- 1.9v Common mode voltage = 2 V Common mode voltage = 2 V Fain 0 <2 8 MHz Non-chopper stabilized input Max value is clock, CAM and input stage dependant. Input frequency is limited to approx <2MHz due to CAM signal processing which is based on sampled data architectures. c. d. High precision operating range provides optimal linearity and dynamic range. Standard precision operating range provides maximum dynamic range and reduced linearity. Input Differential Amplifier ON and filter OFF Parameter Input Range Gain Setting Gain Accuracy Gain Drift (Temperature, Supply Voltage zand Time) Equivalent Input Offset Voltage Symbol Vina Vdiffina Ginamp Dist Min 16 - Typ 1.0 - Max 128 2.5 1.0 Unit Comment Usable input range will be reduced by the effective gain setting See analog input above % % Vos Offset Voltage Temperature Coefficient Input Frequency c Input Frequency d Power Supply Rejection Ratio - 3 12 mV www..com Voffsettc Fain Fain PSRR CMRR Dist Rin Cin NF 1 10 2 8 5.0 0.1 V/C MHz MHz dB dB dB Mohm pF V/sqrtHz 0 0 65 10 <2 67 -65 Non-chopper stabilized input When the input amplifier and filter are used in combination Vos contribution comes only from the input amplifier from -40C to 125C d.c. Amp Gain =16 a.c. See graphs page 18 0.4v p-p Differential input at 660Hz Gain setting = 16 Input cell Gain = 16 Applies to audio frequency range (400Hz to 30KHz). See graphical data on page 18 Input signal = 285 mV p-p diff, audio frequency range See graphical data on page 18 Input signal = 100 mV p-p diff See graphical data on page 18 Common Mode Rejection Ratio Large Signal Harmonic Distortion Input Resistance Input Capacitance Input Referred Noise Figure Signal-to Noise Ratio and Distortion Spurious Free Dynamic Range c. d. SINAD SFDR - 75 73 - dB dB High precision operating range provides optimal linearity and dynamic range. Standard precision operating range provides maximum dynamic range and reduced linearity. DS020700-U001e -7- www..com www..com 4U www..com AN220E04 Datasheet - Dynamically Reconfigurable FPAA Input Differential Chopper Amplifier ON and Filter OFF Parameter Input Range Gain Setting Gain Accuracy Gain Drift, (Temperature, Supply Voltage and Time) Chopper Frequency Clock Range Symbol Vina Vdiffina Ginamp Min 16 - Typ 1.0 - Max 128 2.5 1.0 >250 Unit Comment Usable input range will be reduced by the effective gain setting See analog input above % % KHz Fc = master clock frequency Set Fch as slow as possible Fch > 250KHz will result in some signal attenuation Chopper stabilized amplifier The maximum value of 200V is guaranteed by production test This is a tester limitation from -40C to 125C d.c. a.c. See graphs on page 18 0.4v p-p Differential input at 660Hz Gain setting = 16 Fch=Chopper clock frequency The chopper frequency and input frequency should be chosen such that subsequent low pass filtering can remove the chopper stage frequency elements Input to filter or chopper Fch Equivalent Input Offset Voltage Vos Offset Voltage Temperature Coefficient Power Supply Rejection Ratio Common Mode Rejection Ratio Large Signal Harmonic Distortion Input Frequency Fain Voffsettc PSRR CMRR Dist Fc/260100 65 - <100 0.5 102 -40 200 2.0 - V V/C dB dB dB 0 Fch/20 Fch/2 KHz Input Resistance Input Capacitance Input Referred Noise Figure www..com NF 0.09 V/sqrtHz SINAD 75 dB Rin Cin 10 - 5.0 Mohm pF Signal-to Noise Ratio and Distortion Spurious Free Dynamic Range SFDR - 74 - dB Input cell Gain = 16 Applies to Audio frequency range Chopper clock Fch = 250KHz See graphical data on page 18 Input signal = 285 mV p-p differential, Audio frequency range See graphical data on page 18 Input signal =100 mV p-p differential See graphical data on page 18 Input Differential Amplifier OFF and Filter ON Parameter Input Range Equivalent Input Offset Offset Voltage Temperature Coefficient Input Frequency Fain MHz Symbol Vina Vdiffina Vos Voffsettc Min Typ Max Unit Comment Non-chopper stabilized input, Filter corner frequency =470KHz from -40C to 125C I. measured at filter corner=470Khz II. maximum at Filter corner=76KHz Input filter frequency will define the maximum frequency Input filter is recommended to be >30x higher than the max input frequency, for 80dB distortion performance See analog input above - 8 0.05 I 32 1.0 II mV mV/C DS020700-U001e -8- www..com www..com 4U www..com AN220E04 Datasheet - Dynamically Reconfigurable FPAA Common Mode Rejection Ration Power Supply Rejection Ratio Large Signal Harmonic Distortion Input Low Pass Filter (Anti-Alias) Corner Frequency Settings Input Resistance Input Capacitance Input Referred Noise Figure Signal-To Noise Ratio and Distortion Spurious Free Dynamic Range CMRR PSRR Dist Ffiltcorner Rin Cin NF SINAD SFDR 68 76 10 60 -82 0.17 84 90 470 5.0 dB dB dB KHz Mohm pF V/sqrtHz dB dB Input to filter or chopper Input cell filter corner Fc = 470KHz Applies to Audio frequency range See graphical data on page 18 Input signal = 1400 mV p-p diff, Audio frequency range See graphical data on page 18 Input signal =1400 mV p-p differential See graphical data on page 18 d.c. a.c. See graphical data on page 19 4v p-p Differential input at 660Hz Filter corner frequency 470KHz Input Differential Voltage mode, Amplifier OFF, Filter OFF and Unity Gain Stage ON Parameter Input Range Equivalent Input Offset Offset Voltage Temperature Coefficient Input Frequency Power Supply Rejection Ratio Common Mode Rejection Ratio Large Signal Harmonic Distortion Large Signal Harmonic Distortion Input Resistance Input Capacitance Input Referred Noise Figure Signal-To Noise Ratio and Distortion Spurious Free Dynamic Range Symbol Vina Vdiffina Vos Voffsettc Fain PSRR CMRR Dist Dist Rin Cin NF SINAD SFDR Min 60 - Typ 5 20 60 -80 -80 126 2.0 Max 15 50 1.0 5.0 - Unit V mV V/C MHz dB dB dB dB Kohm pF Comment Non-chopper stabilized input from -40C to 125C Gain Bandwidth limited by input impedance d.c. a.c. See graphs on page 18 4v p-p Differential input at 660Hz 3v p-p single ended signal at 660Hz Input to unity gain stage Applies to Audio frequency range See graphical data on page 18 Input signal = 1400 mV p-p diff, Audio frequency range See graphical data on page 18 Input signal =1400 mV p-p differential See graphical data on page 18 See analog input above www..com 0.16 84 90 V/sqrtHz dB dB Input Differential Voltage mode, Amplifier OFF, Filter OFF and Unity Gain stage OFF Parameter Input Range Equivalent Input Offset Offset Voltage Temperature Coefficient Input Frequency Power Supply Rejection Ratio Large Signal Harmonic Distortion Input Resistance Symbol Vina Vdiffina Vos Voffsettc Fain PSRR Dist Rin Min N/A N/A N/A - Typ N/A N/A N/A -85 - Max N/A N/A 8 N/A - Unit V mV V/C MHz dB dB Mohm Comment See CAM Op Amp See CAM Op Amp. from -40C to 125C Dependant upon CAM See CAM Op Amp See CAM Op Amp Input to CAM directly (Input cell bypass mode). This variable is influenced by CAB capacitor size, CAB clock frequency and CAB architecture Input to CAM directly (Input cell bypass mode) This variable is influenced by CAB capacitor size, CAB clock frequency and CAB architecture See analog input above Input Capacitance Cin pF DS020700-U001e -9- www..com www..com 4U www..com AN220E04 Datasheet - Dynamically Reconfigurable FPAA Analog Outputs (See "Output Cell" section in the AN120E04/AN220E04 user manual for more details) Parameter High Precision Output Range c Standard Precision Output Range d High Precision Differential Output c Standard precision Differential Output d Common Mode Voltage c d Symbol Vouta Vouta Vdiffouta Vdiffouta Vcm Min 0.5 0.1 1.9 Typ 2.0 Max 3.5 3.9 +/-3.0 +/-3.8 2.1 Unit V V V V V Comment VMR +/- 1.5v VMR +/- 1.9v Common mode voltage = 2 V Common mode voltage = 2 V . High precision operating range provides optimal linearity and dynamic range. . Standard precision operating range provides maximum dynamic range and reduced linearity. Output Voltage mode and filter ON, corner frequency 470KHz Parameter Input Range Equivalent Input Offset Offset Voltage Temperature Coefficient Output Frequency Faout MHz Symbol Vina Vdiffina Vos Voffsettc Min - Typ 5 0.05 I Max 15 1.0 II Unit V mV mV/C Comment See analog input above Power Supply Rejection Ratio Large Signal Harmonic Distortion Input Low Pass Filter (Anti-Alias) Corner Frequency Settings Output Load c e Output Load c e Output Load d e PSRR Dist 60 - -82 - - dB dB www..com Ffiltcorner Rload Cload 76 470 50 KHz 0.1 Mohm pF Rload 1 10 Kohm from -40C to 125C I measured at filter corner: 470Khz II maximum at filter corner: 76KHz Output filter frequency will define the maximum frequency Input filter is recommended to be >30x higher then the max input frequency, for good distortion performance d.c. a.c. See graphical data on page 19 4v p-p Differential input at 660Hz Filter corner frequency 470KHz Output Load d e Common Mode Rejection Ratio Input Referred Noise Figure Additional loading causes internal voltage drops across output stage and series resistances The output stage has a small signal output impedance of approx 10ohm Cload CMRR NF - 56 0.22 82 90 100 - pF dB V/sqrtHz dB dB Output filter corner fc = 470KHz Applies to Audio frequency range See graphical data on page 18 Input signal = 1400 mV p-p diff, Audio frequency range See graphical data on page 18 Input signal =1400 mV p-p diff See graphical data on page 18 Signal-To Noise Ratio and Distortion Spurious Free Dynamic Range c SINAD SFDR . High precision operating range provides optimal linearity and dynamic range. . Standard precision operating range provides maximum dynamic range and reduced linearity. e . The maximum load for an analog output is 50 pF // 100 Kohms. This load maybe with respect to analog ground VMR or AVSS. d DS020700-U001e - 10 - www..com www..com 4U www..com AN220E04 Datasheet - Dynamically Reconfigurable FPAA Output Voltage mode and filter off (bypass mode) Parameter Input Range Equivalent Input Offset Offset Voltage Temperature Coefficient Output Frequency c e Output Frequency d f Symbol Vina Vdiffina Vos Voffsettc Faout Faout Min N/A N/A N/A N/A N/A Typ N/A N/A N/A -85 N/A N/A Max N/A N/A 4 8 N/A N/A N/A Unit V mV mV/C MHz MHz dB dB Mohm pF Comment See CAM Op Amp See CAM Op Amp The realizable output frequency is limited to approx <2MHz due to CAM signal processing which is based on sampled data architectures. See CAM Op Amp See CAM Op Amp See CAM Op Amp See analog input above Power Supply Rejection Ratio Large Signal Harmonic Distortion Output Load Output Load c d e PSRR Dist Rload Cload . High precision operating range provides optimal linearity and dynamic range. . Standard precision operating range provides maximum dynamic range and reduced linearity. . The maximum load for an analog output is 50 pF // 100 Kohms. This load maybe with respect to analog ground VMR or AVSS. f . The maximum load for an analog output is 100 pF // 100 Kohms. This load must be differential and with respect to analog ground(VMR). VMR (voltage Mid Rail) and VREF (Reference Voltage) Ratings Parameter VMR Output Voltage VREF+ Output Voltage VREF- Output Voltage Output Voltage Deviation VREF+, VMR, VREFVoltage Temperature Coefficient VREF+, VMR, VREFPower Supply Rejection Ratio, VMR Power Supply Rejection Ratio Vref+ and VrefStart Up Time V+ref vs temperature Symbol Vvmr Vref+ VrefVrefout Vreftc PSSR PSSR Tstart Min 1.925 3.4 0.45 60 75 - Typ 2.01 3.51 0.505 0.5 VMR vs temperature Max 2.075 3.6 0.55 1 1 Unit V V V % dB dB ms Comment At 25C, Vdd=5.00 volts At 25C, Vdd=5.00 volts At 25C, Vdd=5.00 volts Over process and supply voltage corners See typical graphical data below -40C to 125C f www..com 2.010 2.005 Volts Assuming recommended capacitors 0.510 0.505 Vref- vs temperature 3.510 3.505 Volts 3.500 3.495 3.490 -50 0 50 Tchip (C) 100 150 2.000 1.995 1.990 -50 0 50 Tchip (C) 100 150 Volts 0.500 0.495 0.490 -50 0 50 Tchip (C) 100 150 DS020700-U001e - 11 - www..com www..com 4U www..com AN220E04 Datasheet - Dynamically Reconfigurable FPAA CAB (Configurable Analog Block) Differential Operational Amplifier Parameter High Precision Input/Output Range c Standard Precision Input/Output Range d High Precision. Differential Input/Output c Standard Precision Differential Input/Output d Common Mode Input Voltage Range d Common Mode Output Voltage Range Equivalent Input Voltage Offset. Offset Voltage Temperature Coefficient Power Supply Rejection Ratio Common Mode Rejection Ratio CMRR Common Mode Rejection Ratio CMRR 60 dB 77 dB Symbol Vinouta Vinouta Vdiffioa Vdiffioa Vcm Vcm Voffset Min 0.5 0.1 0 1.9 0.1 Typ 2.0 2.0 5 Max 3.5 3.9 +/-3.0 +/-3.8 4 2.1 15 Unit V V V V V V mV Comment VMR +/- 1.5v VMR +/-1.9v Common mode voltage = 2 V Common mode voltage = 2 V Voffsettc - 1 10 V/C PSSR - 80 - dB www..com Differential Slew Rate, Internal Differential Slew Rate, External Unity Gain Bandwidth, Full Power Mode. Input Impedance, Internal Output Impedance, Internal Slew Slew UGB Rin Rout 10 50 10 50 V/sec V/sec MHz Mohm Ohms Some CAMs (Configurable Analog Modules) can inherently compensate from -40C to 125C some CAMs (Configurable Analog Modules) can inherently compensate Variation between CAMs is expected because of variations in architecture Example 1 GainInv CAM CAM clock = 1MHz CAM parameter settings Gain = 1 Example 2 Filterbiquad Setting = Low pass filter CAM clock = 1MHz CAM parameter settings Gain = 1, Corner frequency = 50KHz Quality Factor = 0.707 Applicable when the OpAmp load is internal to the FPAA Applicable when the OpAmp driving signal out of the FPAA package Applicable when sourcing and loading the OpAmp with a load internal to the FPAA The OpAmp output is designed to drive all internal nodes, these are dominantly capacitive loads Output to an FPAA output pin (ouput cell bypass mode). This variable is influenced by CAB capacitor size, CAB clock frequency and CAB architecture Output Impedance, External Output Load, External c e Output Load, External c e Output Load, External d e f Rout Rload Cload 0.1 - - 50 Ohms Mohm pF Rload 1 10 - Kohm Output Load, External d e f Noise Figure g Additional loading causes internal voltage drops across output stage and series resistances The output stage has a small signal output impedance of approx 10ohm Example1 GainInv CAM CAM clock = 1MHz Gain = 1 Cload Noise - 0.13 50 - pF V/sqrtHz DS020700-U001e - 12 - www..com www..com 4U www..com AN220E04 Datasheet - Dynamically Reconfigurable FPAA Signal-To Noise Ratio and Distortion g SINAD 80 dB Input signal=1400 mV p-p differential Audio frequency range Example. GainInv CAM CAM clock = 1MHz Gain = 1 Input signal=1400 mV p-p differential, Audio frequency range Example. GainInv CAM CAM clock = 1MHz Gain = 1 Spurious Free Dynamic Range g SFDR 92 dB c High precision operating range provides optimal linearity and dynamic range. Standard precision operating range provides maximum dynamic range and reduced linearity. The maximum load for an analog output is 50 pF || 100 Kohms. This load may be with respect to analog ground VMR or AVSS. Using the FPAA with CAB Op Amp's driving directly off-chip, requires care, full characterization of the performance of each application circuit by the circuit designer is necessary. g . This specification parameter can only be characterized when a circuit topology is configured onto the CAB differential amplifier architecture. The figure provided here is an representative on the performance of one specific CAM, as specified in the comments. d e . . . f . Idealized CAB Op Am p, Open Loop Gain [dB] 90 80 70 60 50 40 30 20 10 0 -10 -20 0.1 Open Loop Gain (dB) www..com 10 1000 100000 Frequency (KHz) The idealized open loop gain plot is provided for information only. This information is associated with the FPAA in full power mode of operation. The FPAA operation amplifier open loop gain cannot be observed nor used when associated with external connections to the device. Internal reprogrammable routing impedances and switched capacitor circuit architecture using this operational amplifier limit the effective usable bandwidth of a circuit realized in the FPAA to less than 2MHz. DS020700-U001e - 13 - www..com www..com 4U www..com AN220E04 Datasheet - Dynamically Reconfigurable FPAA CAB (Configurable Analog Block) Differential Comparator Parameter Input Range, Internal Input Range, External Differential Input, Internal Differential Input, External Common Mode Output Voltage Range, Internal c Common Mode Input Voltage Range, External c Common Mode Input Voltage, External d Differential Output Single Pin Output (Ox1P) Input Voltage Offset Offset Voltage Temperature Coefficient Setup Time, Internal Setup Time, External Delay Time Output Load Rload Output Load Cload Differential Variable Reference Voltage Settings Differential Hysteresis Differential Hysteresis Differential Hysteresis Differential Hysteresis Hysteresis Setting Accuracy Hysteresis Temperature Coefficient Hysteresis Temperature Coefficient Hysteresis Temperature Coefficient Hysteresis Temperature Coefficient c d Symbol Vina Vina Vdiffina Vdiffina Vcm Vcm Vcm Voutdiff Vout Voffcomp Voffsettc Tsetint Tsetext Tdelay Min 0.1 0.0 +/- 0.0 1.9 0 0 0 1/2Td+25 10 0 - Typ 2.0 2.0 2 1 Voffcomp 20 40 80 25 5 50 100 200 Max 3.9 Vdd +/-3.8 +/- Vdd 2.1 4 5 +/-5 5 10 10 125 500 11/2Td+25 50 +/-4.0 - Unit V V V V V V V V V mV V/C nsec nsec nsec Kohm pF V mV mV mV mV % Comment Common mode voltage = 2 V The comparator will function correctly Zero hysterisis from -40C to 125C, Zero Hysterisis Td = 1/Fc Fc = master clock frequency Applies if comparator drive off chip with output cell in bypass mode Applies if comparator drive off chip with output cell in bypass mode Hysteresis setting = zero Hysteresis setting = 10mV Hysteresis setting = 20mV Hysteresis setting = 40mV CompVref Hysta1 Hysta2 Hysta3 Hysta4 Hystb www..com Hysttc1 Hysttc2 Hysttc3 Hysttc4 V/C V/C V/C V/C Hysteresis setting = zero Hysteresis setting = 10mV Hysteresis setting = 20mV Hysteresis setting = 40mV . High precision operating range provides optimal linearity and dynamic range. . Standard precision operating range provides maximum dynamic range and reduced linearity. DS020700-U001e - 14 - www..com www..com 4U www..com AN220E04 Datasheet - Dynamically Reconfigurable FPAA ESD Characteristics Pin Type Digital Inputs Digital Outputs Digital Bidirectional Digital Open Drain Analog Inputs Analog Outputs Reference Voltages Human Body Model 4000V 4000V 4000V 4000V 2000V 1500V 1500V Machine Model 250V 250V 250V 250V 200V 100V 100V Charged Device Model 4kV 4kV 4kV 4kV 4kV 4kV 4kV The AN220E04 is an ESD (electrostatic discharge) sensitive device. Electrostatic charges as high as 4000V readily accumulate on the human body and test equipment and can discharge without detection. Although the AN220E04 device features proprietary ESD protection circuitry, permanent damage may occur on devices subjected to high-energy electrostatic discharges. Therefore, proper ESD precautions are recommended to avoid performance degradation or loss of functionality. Power Consumption - Low Power Mode Parameter Minimum Power 1a Nominal 25% Power1b Nominal 50% Power 1c Nominal 75% Power1d Maximum Power1e Symbol Idd Idd Idd Idd Idd Min - Typ 0.2 25 42 50 60 63 66 -2 Max 30 47 55 68 -10 Unit mA mA mA mA mA A/C Comment Vdd=5.00 volts, Tj=25C Vdd=5.00 volts, Tj=25C Vdd=5.00 volts, Tj=25C Vdd=5.00 volts, Tj=25C Vdd=4.75 volts, Tj=85C Vdd=5.00 volts, Tj=25C Vdd=5.25 volts, Tj= -40C Temperature Coefficient - 1a. External clock, all analog function disabled, memory active. 1b FPAA active elements - Two core op-amps (low power mode), one comparator, one input (bypass mode), one output filter and differential to single-ended converter (low power mode). 1c. FPAA active elements - Four core op-amps (low power mode), two comparators (one using SAR), two inputs (bypass mode), two output filters and two differential to singleended converters (low power mode). 1d FPAA active elements - Six core op-amps (low power mode), three comparators (two using SAR), three inputs (bypass mode, two output filters and two differential to single-ended converters (low power mode). 1e FPAA active elements - Eight core op-amps (low power mode), four comparators (two using SAR), four inputs (bypass mode), two output filters and two differential to singleended converters (low power mode). Power consumption low power mode (temp 25 degree C) 70 60 50 Idd (mA) 40 30 20 10 Vdd=4.75V Vdd=5.0V Vdd=5.25V 75% 100% www..com 0 25% 50% Resource Utilization Power Consumption - Full Power Mode Parameter Full Power Mode Minimum Power 2a Full Power Mode Nominal 25% Power2b Full Power Mode Nominal 50% Power2c Full Power Mode Nominal 75% Power2d Full Power Mode Maximum Power2e Symbol Idd Idd Idd Idd Idd Min - Typ 1.5 80 150 170 200 210 220 Max 90 160 190 230 - Unit mA mA mA mA mA Comment Vdd=5.00 volts, Tj=25C Vdd=5.00 volts, Tj=25C Vdd=5.00 volts, Tj=25C Vdd=5.00 volts, Tj=25C Vdd=4.75 volts, Tj=85C Vdd=5.00 volts, Tj=25C Vdd=5.25 volts, Tj= -40C 2a. AN220E04 Crystal Oscillator, all analog functions disabled, memory active. 2b. FPAA active elements - Two core op-amps, one comparator, one input filter and chopper amplifier, one output filter and differential to single-ended converter. 2c. FPAA active elements - Four core op-amps, two comparators (one using SAR), two Input filters and two chopper amplifiers, two output filters and two differential to single-ended converters. 2d FPAA active elements - Six core op-amps, three comparators (two using SAR), three input filters and three chopper amplifiers, two output filters and two differential to single-ended converters. 2e FPAA active elements - Eight core op-amps, four comparators (two using SAR), four input filters and two chopper amplifiers, two output filters and two differential to single-ended converters. Power consumption full power mode (temp 25 degree C) 250 200 Idd (mA) 150 100 50 0 25% 50% 75% Vdd=4.75V Vdd=5.0V Vdd=5.25V 100% Resource Utilization DS020700-U001e - 15 - www..com www..com 4U www..com AN220E04 Datasheet - Dynamically Reconfigurable FPAA PINOUT Pin Numb er 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 Pin Name I4PA I4NA O1P O1N AVSS AVDD O2P O2N I1P I1N I2P I2N SHIELD AVDD2 VREFMC VREFPC VMRC BVDD BVSS CFGFLGb Pin Type Analog IN+ Analog INAnalog OUT+ Analog OUTAnalog Vss Analog Vdd Analog OUT Analog OUT Analog IN+ Analog INAnalog IN+ Analog INAnalog Vdd Analog Vdd Vref Vref Vref Analog Vdd Analog Vss Digital IN Digital OUT Comments 21 22 CS2b CS1b Digital IN Digital IN (during config) Digital IN (after config)_ Digital IN Digital Vss Digital IN Digital IN Digital OUT Digital OUT Digital OUT Digital Vdd Digital Vss Digital IN Digital OUT Low noise Vdd bias for capacitor array n-wells Analog power Attach filter capacitor for VREFAttach filter capacitor for VREF+ Attach filter capacitor for VMR (Voltage Main Reference) Analog power for bandgap Vref Generators Analog ground for bandgap Vref Generators In multi-device systems... 0, Ignore incoming data (unless currently addressed) 1, Pay attention to incoming data (watching for address) 0, Device is being configured Z, Device is not being configured (if internal pullup is selected) 0, Chip is selected 1, Chip is not selected 0, Allow configuration to proceed 1, Hold off configuration Passes read-back data through to LCC_B pin Digital ground - substrate tie 0, Synchronous serial interface 1, SPI EPROM Interface MODE = 0, analog clock < 40 MHz MODE = 1, SPI EPROM or serial EPROM clock During power-up, sources SPI EPROM initialization command string After power-up, sources any of the four internal analog clocks 23 24 25 26 27 28 29 30 31 32 DCLK SVSS MODE ACLK / SPIP OUTCLK / SPIMEM DVDD DVSS DIN LCCb ERRb www..com Serial configuration data input 1, Local configuration is needed. Once configuration is completed, it is a registered version of CS1b or if the device is addressed for read, it serves as serial data out port 0, Initiate reset 1, No action 0, Error condition Z, No error condition (external pullup required) 0, Hold off completion of configuration Rising Edge, Allow completion of configuration O.D. Output 0, device has not yet completed primary configuration Z, Device has completed primary configuration (if internal pullup is selected) A buffered version of DCLK. (Factory reserved test input. Float if unused) 0, Chip held in reset state Rising edge, re-initiates power on reset sequence To initiate a POR reset cycle, the minimum pulse width required on the PORb pin is 25ns. 0, No action 1, Transfer shadow RAM into configuration RAM Digital IN (monitored OUT) Digital OUT Digital IN 33 ACTIVATE 34 35 36 37 38 39 40 41 42 43 44 DOUTCLK / TEST PORb EXECUTE I3P I3N I4PD I4ND I4PC I4NC I4PB I4NB Digital OUT Digital IN Digital IN Digital IN Analog IN+ Analog INAnalog IN+ Analog INAnalog IN+ Analog INAnalog IN+ Analog IN- Analog multiplexer input signals. The multiplexer can accept 4 differential inputs or 8 single ended inputs DS020700-U001e - 16 - www..com www..com 4U www..com AN220E04 Datasheet - Dynamically Reconfigurable FPAA MECHANICAL AND HANDLING The AN220E04 comes in the industry standard 44 lead QFP package. Dry pack handling is recommended. The package is qualified to MSL3 (JEDEC Standard, J-STD-020A, Level 3). Once the device is removed from dry pack, 30C at 60% humidity for not longer than 168 hours is the maximum recommended exposure prior to solder reflow. If out of dry pack for longer than this recommended period of time, then the recommended bake out procedure prior to solder reflow is 24 hours at 125C. www..com DS020700-U001e - 17 - www..com www..com 4U www..com AN220E04 Datasheet - Dynamically Reconfigurable FPAA Distortion, SINAD and SNR Measurements The following plots give an indication of the Distortion, SINAD and SNR for some representative CAMs. INPUT CELL UGB SNR, DSTN, SINAD 120 100 80 60 40 20 0 -20 -40 -60 -80 -100 0.7 1.4 2.8 5.6 7.0 120 100 80 SNR[ dB] INPUT CELL LOW PASS FILTER SNR, DSTN, SINAD 60 [dB] [dB] SINAD[ dB] DISTN[ dB] 40 20 0 -20 -40 -60 -80 -100 0.7 SNR[ dB] SINAD[ dB] DISTN[ dB] INPUT [Vp-p] 1.4 INPUT [Vp-p] 2.8 5.6 7.0 100.00 80.00 60.00 40.00 20.00 0.00 -20.00 -40.00 -60.00 -80.00 -100.00 0.08 0.14 0.21 0.28 0.35 0.42 0.49 SNR[ dB] SINAD[ dB] DISTN[ dB] INPUT CELL AMPLIFIER SNR,DSTN,SINAD Measured with Inputcell Gain G = 16 Same results for Input Amplifier and Chopper Amplifier stage, If the signal from the chopper Amplifier is correctly filtered before measurement. [dB] www..com Output Cell SNR, DSTN, SINAD 120 100 80 60 40 20 0 -20 -40 -60 -80 -100 0.7 INPUT [Vp-p] [dB] SNR[dB] SINAD[dB] DISTN[dB] 1.4 2.8 3.5 5.6 7.0 INPUT [Vp-p] 100 80 60 40 20 SNR[ dB] SINAD[ dB] DISTN[ dB] 0 - 20 - 40 - 60 - 80 - 100 - 120 0.7 1.4 2.8 GAININV CAM SNR, DSTN, SINAD This graph shows the typical performance of an FPAA CAB when configured with a CAM in this example GainInv CAM Input signal=1400 mV p-p differential, CAM clock = 1MHz CAM parameter settings Gain = 1 5.6 7.0 [dB] 3.5 INPUT [Vp-p] DS020700-U001e - 18 - www..com www..com 4U www..com AN220E04 Datasheet - Dynamically Reconfigurable FPAA Power Supply Rejection Ratio (PSRR) Measurements The following plots give an indication of the PSRR for some representative CAMs. AVDD to Power Supply (PS): 5v +/- 0.25v sinusoidal waveform (100 kHz to 1 MHz) INPUT AMP PSRR [dB] 80.00 70.00 60.00 50.00 40.00 30.00 20.00 DC 100 1KHz 10KHz 100KHz 1M Hz 80.00 70.00 60.00 50.00 40.00 30.00 20.00 DC 15 50 100 1KHz 10KHz 100KHz 1M Hz INPUT LPF PSRR [dB] 100.00 90.00 80.00 70.00 60.00 50.00 40.00 30.00 20.00 DC VMR, Vref+, Vref- PSRR [dB] PSRR_VMR [ dB] PSRR_VREFP [ dB] PSRR_VREFP [ dB] 100 1KHz 10KHz 100KHz 1M Hz www..com OUTPUT Voltage Mode + LPF PSRR [dB] 80.00 70.00 60.00 50.00 40.00 30.00 20.00 DC 100 1KHz 10KHz 100KHz 1M Hz GAININV_1MHz PSRR [dB] 100 90 80 70 60 50 40 30 20 DC 50 100 1KHz 10KHz 100KHz 1M Hz 100 90 80 70 60 50 40 30 20 100 GAININV_4MHz PSRR [dB] 1KHz 10KHz 100KHz 1M Hz DS020700-U001e - 19 - www..com www..com 4U www..com AN220E04 Datasheet - Dynamically Reconfigurable FPAA The following is provided for information only, as and when additional characterization data is collected `noise measurements' will be added formally to the datasheet. Noise And Distortion Observations The following plots give an indication of the noise characteristics of Anadigm(R)'s AN220E04 FPAA device. These were done using a simple set-up and in many cases reflect the noise limit of the setup. Actual device noise margins are expected to be better. Signal and Noise for the Input Cell (input signal - 50mVp-p differential to the FPAA at 10 kHz) Signal to Noise: -92 dB, at 376KHz, 3Hz BW Input gain stage set at X16 Input anti-aliasing filter set off Input chopper amplifier set off www..com Signal and Noise for the Output Cell (with a differential input 4V p-p, 660Hz) Signal to Noise: -106 dB, at 345KHz, 3Hz BW Voltage output mode (including filter) ON Output smoothing filter set at fC = 470 kHz DS020700-U001e - 20 - www..com www..com 4U www..com AN220E04 Datasheet - Dynamically Reconfigurable FPAA Measured THD for input and output cells (with a differential input 4V p-p, 660Hz) Settings Input cell with anti-aliasing filter set at fC = 470 kHz Output cell with differential to single ended converter and output smoothing filter set at fC = 470 kHz Distortion in dB 81.6 82 Signal and Noise for a representative CAM - Gaininv CAM (input signal of 700mV p-p differential at 10 kHz) Signal to Noise: 108 dB, at 528 kHz, 3Hz BW THD for a representative CAM - Gaininv CAM (with a differential input 4V p-p, 660Hz) CAM Clock Frequency 250 KHz 1 MHz 2 MHz 4 MHz Distortion (dB) 80.00 72.83 69.22 73.48 www..com As above, zoom to lower frequency DS020700-U001e - 21 - www..com www..com 4U |
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