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HI5766KCB

HI5766KCB

  • 厂商:

    L3HARRIS

  • 封装:

    SOIC28

  • 描述:

    IC ADC 10BIT PIPELINED 28SOIC

  • 数据手册
  • 价格&库存
HI5766KCB 数据手册
HI5766 Semiconductor Data Sheet February 1999 File Number 4130.5 10-Bit, 60 MSPS A/D Converter Features The HI5766 is a monolithic, 10-bit, analog-to-digital converter fabricated in a CMOS process. It is designed for high speed applications where wide bandwidth and low power consumption are essential. Its 60 MSPS speed is made possible by a fully differential pipelined architecture with an internal sample and hold. • Sampling Rate . . . . . . . . . . . . . . . . . . . . . . . . . . 60 MSPS The HI5766 has excellent dynamic performance while consuming only 260mW power at 60 MSPS. Data output latches are provided which present valid data to the output bus with a latency of 7 clock cycles. It is pin-for-pin functionally compatible with the HI5702, HI5703 and the HI5746. • Fully Differential or Single-Ended Analog Input For internal voltage reference, please refer to the HI5767 data sheet. Ordering Information PART NUMBER TEMP. RANGE (oC) PACKAGE PKG. NO. 0 to 70 28 Ld SOIC (W) M28.3 HI5766KCA 0 to 70 28 Ld SSOP M28.15 25 • Low Power at 60 MSPS . . . . . . . . . . . . . . . . . . . . 260mW • Wide Full Power Input Bandwidth. . . . . . . . . . . . . 250MHz • On Chip Sample and Hold • Single Supply Voltage. . . . . . . . . . . . . . . . . . . . . . . . . +5V • TTL/CMOS Compatible Digital Inputs • CMOS Compatible Digital Outputs . . . . . . . . . . . . 3.0/5.0V • Offset Binary or Two’s Complement Output Format Applications • Professional Video Digitizing HI5766KCB HI5766EVAL1 • 8.3 Bits at fIN = 10MHz Evaluation Board • Medical Imaging • Digital Communication Systems • High Speed Data Acquisition Pinout HI5766 (SOIC, SSOP) TOP VIEW DVCC1 1 28 D0 DGND 2 27 D1 DVCC1 3 26 D2 DGND 4 25 D3 AVCC 5 24 D4 AGND 6 VREF + 7 23 DVCC2 22 CLK VREF - 8 21 DGND VIN+ 9 20 D5 VIN- 10 19 D6 VDC 11 18 D7 AGND 12 17 D8 AVCC 13 16 D9 OE 14 3-101 15 DFS CAUTION: These devices are sensitive to electrostatic discharge; follow proper IC Handling Procedures. 1-800-4-HARRIS | Copyright © Harris Corporation 1999 HI5766 Functional Block Diagram VDC CLOCK BIAS CLK VINVIN+ S/H STAGE 1 DFS 2-BIT FLASH 2-BIT DAC OE + ∑ DVCC2 X2 D9 (MSB) D8 D7 D6 DIGITAL DELAY AND DIGITAL ERROR CORRECTION STAGE 8 D5 D4 D3 2-BIT FLASH 2-BIT DAC D2 D1 + ∑ D0 (LSB) - X2 DGND2 STAGE 9 2-BIT FLASH AVCC 3-102 AGND DVCC1 DGND1 VREF + VREF - (OPTIONAL) HI5766 Typical Application Schematic HI5766 2.5V 2.0V (OPTIONAL) VREF+ (7) VREF - (8) (LSB) (28) D0 D0 (27) D1 D1 (26) D2 D2 (25) D3 D3 (24) D4 D4 DGND1 (2) (20) D5 D5 DGND1 (4) (19) D6 D6 DGND2 (21) (18) D7 D7 (17) D8 D8 (MSB) (16) D9 D9 AGND (12) AGND (6) VIN + CLOCK VDC (11) (3) DVCC1 VIN - (10) (23) DVCC2 CLK (22) (13) AVCC DFS (15) (5) AVCC AGND BNC 10µF AND 0.1µF CAPS ARE PLACED AS CLOSE TO PART AS POSSIBLE (1) DVCC1 VIN + (9) VIN - DGND OE (14) 0.1µF + 10µF 0.1µF + 10µF +5V +5V Pin Descriptions PIN NO. NAME 1 DVCC1 2 DESCRIPTION PIN NO. NAME Digital Supply (+5.0V). 15 DFS Data Format Select Input. DGND1 Digital Ground. 16 D9 Data Bit 9 Output (MSB). 3 DVCC1 Digital Supply (+5.0V). 17 D8 Data Bit 8 Output. 4 DGND1 Digital Ground. 18 D7 Data Bit 7 Output. 5 AVCC Analog Supply (+5.0V). 19 D6 Data Bit 6 Output. 6 AGND Analog Ground. 20 D5 Data Bit 5 Output. 7 VREF+ +2.5V Positive Reference Voltage Input. 21 DGND2 22 CLK Sample Clock Input. 8 VREF - +2.0V Negative Reference Voltage Input (Optional). 23 DVCC2 Digital Output Supply (+3.0V or +5.0V). 24 D4 Data Bit 4 Output. 25 D3 Data Bit 3 Output. 26 D2 Data Bit 2 Output. 27 D1 Data Bit 1 Output. 28 D0 Data Bit 0 Output (LSB). 9 VIN+ Positive Analog Input. 10 VIN- Negative Analog Input. 11 VDC DC Bias Voltage Output. 12 AGND Analog Ground. 13 AVCC Analog Supply (+5.0V). 14 OE Digital Output Enable Control Input. 3-103 DESCRIPTION Digital Ground. HI5766 Absolute Maximum Ratings TA = 25oC Thermal Information Supply Voltage, AVCC or DVCC to AGND or DGND . . . . . . . . . . 6V DGND to AGND . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 0.3V Digital I/O Pins . . . . . . . . . . . . . . . . . . . . . . . . . . . . . DGND to DVCC Analog I/O Pins . . . . . . . . . . . . . . . . . . . . . . . . . . . . AGND to AVCC Operating Conditions Temperature Range HI5766KCB (Typ) . . . . . . . . . . . . . . . . . . . . . . . . . . . 0oC to 70oC Thermal Resistance (Typical, Note 1) θJA (oC/W) SOIC Package . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 70 SSOP Package . . . . . . . . . . . . . . . . . . . . . . . . . . . . 100 Maximum Junction Temperature . . . . . . . . . . . . . . . . . . . . . . .150oC Maximum Storage Temperature Range . . . . . . . . . . -65oC to 150oC Maximum Lead Temperature (Soldering 10s) . . . . . . . . . . . . 300oC (SOIC - Lead Tips Only) CAUTION: Stresses above those listed in “Absolute Maximum Ratings” may cause permanent damage to the device. This is a stress only rating and operation of the device at these or any other conditions above those indicated in the operational sections of this specification is not implied. NOTE: 1. θJA is measured with the component mounted on an evaluation PC board in free air. Electrical Specifications AVCC = DVCC1 = 5.0V, DVCC2 = 3.0V; VREF+ = 2.5V; VREF - = 2.0V; fS = 60 MSPS at 50% Duty Cycle; CL = 10pF; TA = 25oC; Differential Analog Input; Typical Values are Test Results at 25oC, Unless Otherwise Specified PARAMETER TEST CONDITIONS MIN TYP MAX UNITS ACCURACY Resolution 10 - - Bits Integral Linearity Error, INL fIN = DC - ±1.0 ±2.0 LSB Differential Linearity Error, DNL (Guaranteed No Missing Codes) fIN = DC - ±0.5 ±1.0 LSB Offset Error, VOS fIN = DC -40 12 +40 LSB Full Scale Error, FSE fIN = DC - 4 - LSB Minimum Conversion Rate No Missing Codes - 0.5 1 MSPS Maximum Conversion Rate No Missing Codes 60 - - MSPS Effective Number of Bits, ENOB fIN = 10MHz - 8.3 - Bits Signal to Noise and Distortion Ratio, SINAD RMS Signal = -------------------------------------------------------------RMS Noise + Distortion fIN = 10MHz - 51.7 - dB Signal to Noise Ratio, SNR RMS Signal = ------------------------------RMS Noise fIN = 10MHz - 53.7 - dB Total Harmonic Distortion, THD fIN = 10MHz - -56.2 - dBc 2nd Harmonic Distortion fIN = 10MHz - -61.6 - dBc 3rd Harmonic Distortion fIN = 10MHz - -58.1 - dBc Spurious Free Dynamic Range, SFDR fIN = 10MHz - 58.1 - dBc Intermodulation Distortion, IMD f1 = 1MHz, f2 = 1.02MHz - 62 - dBc Differential Gain Error fS = 17.72 MSPS, 6 Step, Mod Ramp - 0.8 - % Differential Phase Error fS = 17.72 MSPS, 6 Step, Mod Ramp - 0.1 - Degree DYNAMIC CHARACTERISTICS Transient Response (Note 2) - 1 - Cycle Over-Voltage Recovery 0.2V Overdrive (Note 2) - 1 - Cycle Maximum Peak-to-Peak Differential Analog Input Range (VIN+ - VIN-) - ±0.5 - V Maximum Peak-to-Peak Single-Ended Analog Input Range - 1.0 - V (Note 3) - 1 - MΩ - 10 - pF (Note 3) -10 - +10 µA ANALOG INPUT Analog Input Resistance, RIN Analog Input Capacitance, CIN Analog Input Bias Current, IB+ or IB- 3-104 HI5766 Electrical Specifications AVCC = DVCC1 = 5.0V, DVCC2 = 3.0V; VREF+ = 2.5V; VREF - = 2.0V; fS = 60 MSPS at 50% Duty Cycle; CL = 10pF; TA = 25oC; Differential Analog Input; Typical Values are Test Results at 25oC, Unless Otherwise Specified (Continued) PARAMETER Differential Analog Input Bias Current IBDIFF = (IB+ - IB-) TEST CONDITIONS (Note 3) Full Power Input Bandwidth, FPBW MIN TYP MAX UNITS - ±0.5 - µA - 250 - MHz 0.25 - 4.75 V Total Reference Resistance, RL - 2.5K - Ω Reference Current - 1.0 - mA Analog Input Common Mode Voltage Range (VIN+ + VIN-) / 2 Differential Mode (Note 2) REFERENCE INPUT Positive Reference Voltage Input, VREF+ (Note 2) - 2.5 - V Negative Reference Voltage Input, VREF - (Note 2) - 2.0 - V Reference Common Mode Voltage (VREF+ + VREF -) / 2 (Note 2) - 2.25 - V DC Bias Voltage Output, VDC - 3.2 - V Maximum Output Current - - 0.4 mA DC BIAS VOLTAGE DIGITAL INPUTS Input Logic High Voltage, VIH CLK, DFS, OE 2.0 - - V Input Logic Low Voltage, VIL CLK, DFS, OE - - 0.8 V Input Logic High Current, IIH CLK, DFS, OE, VIH = 5V -10.0 - +10.0 µA Input Logic Low Current, IIL CLK, DFS, OE, VIL = 0V -10.0 - +10.0 µA - 7 - pF Input Capacitance, CIN DIGITAL OUTPUTS Output Logic High Voltage, VOH IOH = 100µA; DVCC2 = 5V 4.0 - - V Output Logic Low Voltage, VOL IOL = 100µA; DVCC2 = 5V - - 0.5 V Output Three-State Leakage Current, IOZ VO = 0/5V; DVCC2 = 5V - ±1 ±10 µA Output Logic High Voltage, VOH IOH = 100µA; DVCC2 = 3V 2.4 - - V Output Logic Low Voltage, VOL IOL = 100µA; DVCC2 = 3V - - 0.5 V Output Three-State Leakage Current, IOZ VO = 0/5V; DVCC2 = 3V - ±1 ±10 µA - 10 - pF Aperture Delay, tAP - 5 - ns Aperture Jitter, tAJ - 5 - psRMS Output Capacitance, COUT TIMING CHARACTERISTICS Data Output Hold, tH - 7 - ns Data Output Delay, tOD - 8 - ns Data Output Enable Time, tEN - 5 - ns Data Output Enable Time, tDIS - 5 - ns Data Latency, tLAT For a Valid Sample (Note 2) - - 7 Cycles Power-Up Initialization Data Invalid Time (Note 2) - - 20 Cycles 4.75 5.0 5.25 V POWER SUPPLY CHARACTERISTICS Analog Supply Voltage, AVCC Digital Supply Voltage, DVCC1 Digital Output Supply Voltage, DVCC2 4.75 5.0 5.25 V At 3.0V 2.7 3.0 3.3 V At 5.0V 4.75 5.0 5.25 V Supply Current, ICC VIN+ - VIN- = 1.25V and DFS = “0” - 52 - mA Power Dissipation VI+ - VIN- = 1.25V and DFS = “0” - 260 - mW 3-105 HI5766 Electrical Specifications AVCC = DVCC1 = 5.0V, DVCC2 = 3.0V; VREF+ = 2.5V; VREF - = 2.0V; fS = 60 MSPS at 50% Duty Cycle; CL = 10pF; TA = 25oC; Differential Analog Input; Typical Values are Test Results at 25oC, Unless Otherwise Specified (Continued) PARAMETER TEST CONDITIONS MIN TYP MAX UNITS Offset Error Sensitivity, ∆VOS AVCC or DVCC = 5V ±5% - ±0.4 - LSB Gain Error Sensitivity, ∆FSE AVCC or DVCC = 5V ±5% - ±0.8 - LSB NOTES: 2. Parameter guaranteed by design or characterization and not production tested. 3. With the clock low and DC input. Timing Waveforms ANALOG INPUT CLOCK INPUT SN - 1 HN - 1 SN HN SN + 1 H N + 1 SN + 2 SN + 5 HN+5 SN + 6 H N + 6 SN + 7 HN + 7 SN + 8 HN + 8 INPUT S/H 1ST STAGE 2ND STAGE B1 , N - 1 B2 , N - 2 B2 , N - 1 9TH STAGE DATA OUTPUT B1 , N B1 , N + 4 B2 , N B9 , N - 5 DN - 7 B1 , N + 1 B9 , N - 4 DN - 6 DN - 2 B1 , N + 5 B2 , N + 4 B2 , N + 5 B2 , N + 6 B9 , N B9 , N + 1 B9 , N + 2 DN - 1 tLAT NOTES: 4. SN : N-th sampling period. 5. HN : N-th holding period. 6. BM , N : M-th stage digital output corresponding to N-th sampled input. 7. DN : Final data output corresponding to N-th sampled input. FIGURE 1. HI5766 INTERNAL CIRCUIT TIMING 3-106 B1 , N + 6 DN B1 , N + 7 B9 , N + 3 DN + 1 HI5766 Timing Waveforms ANALOG INPUT tAP tAJ CLOCK INPUT 1.5V 1.5V tOD tH 2.4V DATA OUTPUT DATA N DATA N - 1 0.5V FIGURE 2. INPUT-TO-OUTPUT TIMING Typical Performance Curves 9 55 SNR fS = 60 MSPS fS = 60 MSPS TA = 25oC 8 SND dB ENOB (BITS) TA = 25oC 45 7 6 35 1 10 100 1 10 100 INPUT FREQUENCY (MHz) INPUT FREQUENCY (MHz) FIGURE 3. EFFECTIVE NUMBER OF BITS (ENOB) vs INPUT FREQUENCY FIGURE 4. SINAD AND SNR vs INPUT FREQUENCY 85 9 fS = 60 MSPS TA = 25oC 75 ENOB (BITS) dBc SFDR 65 -3HD 55 fS = 60 MSPS fIN = 10MHz TA = 25oC 8 -2HD 7 6 5 -THD 4 3 45 1 10 INPUT FREQUENCY (MHz) 100 0 5 10 15 20 25 30 INPUT LEVEL (-dBFS) NOTE: SFDR depicted here does not include any harmonic distortion. FIGURE 5. -2HD, -3HD, -THD AND SFDR vs INPUT FREQUENCY 3-107 FIGURE 6. EFFECTIVE NUMBER OF BITS (ENOB) vs ANALOG INPUT LEVEL 35 HI5766 Typical Performance Curves (Continued) 10 ENOB (BITS) 9 ENOB (BITS) 8.8 fS = 60 MSPS fIN = 10MHz TA = 25oC 8 8.6 fS = 60 MSPS fIN = 10MHz 8.4 TA = 25oC VREF + - VREF - = 0.5V 8.2 8.0 7 7.8 6 40 45 50 55 DUTY CYCLE (%, tH /tCLK) 7.6 2.25 2.30 2.35 2.40 2.45 2.50 2.55 2.60 2.65 2.70 2.75 60 FIGURE 7. EFFECTIVE NUMBER OF BITS (ENOB) vs SAMPLE CLOCK DUTY CYCLE VREF+ (V) FIGURE 8. EFFECTIVE NUMBER OF BITS (ENOB) vs VREF + 53 85 fS = 60 MSPS 52 80 fIN = 10MHz SNR 75 dB SND 50 dBc 51 -2HD 70 TA = 25oC VREF + - VREF - = 0.5V -3HD 65 49 48 fS = 60 MSPS fIN = 10MHz -THD 60 TA = 25oC SFDR 55 VREF + - VREF - = 0.5V 47 2.25 2.30 2.35 2.40 2.45 2.50 2.55 2.60 2.65 2.70 2.75 50 2.25 2.30 2.35 2.40 2.45 2.50 2.55 2.60 2.65 2.70 2.75 VREF+ (V) VREF+ (V) NOTE: SFDR depicted here does not include any harmonic distortion. FIGURE 10. -2HD, -3HD, -THD AND SFDR vs VREF + FIGURE 9. SINAD AND SNR vs VREF + 51 8.4 fS = 60 MSPS fIN = 10MHz 50 SNR 8.2 49 dB ENOB (BITS) TA = 25oC VREF - NOT DRIVEN SINAD 48 8.0 47 7.8 2.25 2.30 2.35 2.40 2.45 2.50 2.55 2.60 2.65 2.70 2.75 VREF+ (V) FIGURE 11. EFFECTIVE NUMBER OF BITS (ENOB) vs VREF + (VREF - NOT DRIVEN) 3-108 fS = 60 MSPS fIN = 10MHz TA = 25oC VREF - NOT DRIVEN 46 2.25 2.30 2.35 2.40 2.45 2.50 2.55 2.60 2.65 2.70 VREF+ (V) 2.75 FIGURE 12. SINAD AND SNR vs VREF + (VREF - NOT DRIVEN) HI5766 Typical Performance Curves (Continued) 80 8.6 fS = 60 MSPS fIN = 10MHz 75 TA = 25oC VREF - NOT DRIVEN -3HD ENOB (BITS) 70 dBc fS = 60 MSPS TA = 25oC 65 SFDR 60 8.5 10MHz 8.4 -2HD 1MHz 55 -THD 50 2.25 2.30 2.35 2.40 2.45 2.50 2.55 2.60 2.65 2.70 8.3 0.25 2.75 0.75 1.25 1.75 2.25 VREF+ (V) 2.75 3.25 3.75 4.25 4.75 VCM (V) FIGURE 13. -2HD, -3HD, -THD AND SFDR vs VREF + (VREF - NOT DRIVEN) FIGURE 14. EFFECTIVE NUMBER OF BITS (ENOB) vs ANALOG INPUT COMMON MODE VOLTAGE 60 1MHz ≤ fIN ≤ 15MHz 8.9 SUPPLY CURRENT (mA) 8.7 ENOB (BITS) 60 MSPS/1MHz 8.5 8.3 60 MSPS/10MHz 8.1 7.9 ICC 40 AICC 30 DICC1 20 10 7.7 7.5 -40 TA = 25oC 50 DICC2 0 -20 0 20 40 TEMPERATURE (oC) 60 80 10 20 30 40 50 60 fS (MSPS) FIGURE 15. EFFECTIVE NUMBER OF BITS (ENOB) vs TEMPERATURE FIGURE 16. SUPPLY CURRENT vs SAMPLE CLOCK FREQUENCY 1200 9.5 1000 9.0 IREF + 8.5 tOD tOD (ns) IREF (µA) 800 600 8.0 7.5 400 7.0 200 6.5 IREF - 0 -40 -20 0 20 40 TEMPERATURE (oC) 60 FIGURE 17. REFERENCE CURRENT vs TEMPERATURE 3-109 80 6.0 -40 -20 0 20 40 TEMPERATURE (oC) 60 FIGURE 18. DATA OUTPUT DELAY vs TEMPERATURE 80 HI5766 (Continued) 0.90 0.70 0.2 0.65 DG DG (%) 0.75 0.70 0.15 0.65 DP 0.60 0.1 0.55 0.45 60 0.15 DG 0.1 0.05 fS = 17.72 MSPS AVCC /DVCC1 = 5V ±5%, TA = 25oC 0.40 0 2.75 3.00 3.25 3.50 3.75 4.00 4.25 4.50 4.75 5.00 5.25 DVCC2 (V) 0 0 20 40 TEMPERATURE (oC) 0.2 0.50 0.05 -20 0.25 DP 0.45 0.40 -40 DP DG 0.55 0.50 0.3 0.60 DG (%) 0.80 DP (DEGREES) 0.85 0.25 fS = 17.72 MSPS DP (DEGREES) Typical Performance Curves 80 FIGURE 19. DIFFERENTIAL GAIN/PHASE vs TEMPERATURE FIGURE 20. DIFFERENTIAL GAIN/PHASE vs SUPPLY VOLTAGE 3.30 OUTPUT LEVEL (dB) 0 VDC (V) 3.20 3.10 -10 fS = 60 MSPS fIN = 1MHz -20 TA = 25oC -30 -40 -50 -60 -70 -80 -90 3.00 -40 -100 -20 0 20 40 TEMPERATURE (oC) 60 80 0 100 FIGURE 21. DC BIAS VOLTAGE (VDC) vs TEMPERATURE 200 300 400 500 600 700 FREQUENCY (BIN) FIGURE 22. 2048 POINT FFT PLOT OUTPUT LEVEL (dB) 0 -10 fS = 60 MSPS fIN = 10MHz -20 TA = 25oC -30 -40 -50 -60 -70 -80 -90 -100 0 100 200 300 400 500 600 700 FREQUENCY (BIN) 800 FIGURE 23. 2048 POINT FFT PLOT 3-110 800 900 1023 900 1023 HI5766 Detailed Description Theory of Operation The HI5766 is a 10-bit fully differential sampling pipeline A/D converter with digital error correction logic. Figure 24 depicts the circuit for the front end differential-in-differential-out sampleand-hold (S/H). The switches are controlled by an internal sampling clock which is a non-overlapping two phase signal, φ1 and φ2 , derived from the master sampling clock. During the sampling phase, φ1 , the input signal is applied to the sampling capacitors, CS. At the same time the holding capacitors, CH , are discharged to analog ground. At the falling edge of φ1 the input signal is sampled on the bottom plates of the sampling capacitors. In the next clock phase, φ2 , the two bottom plates of the sampling capacitors are connected together and the holding capacitors are switched to the op amp output nodes. The charge then redistributes between CS and CH completing one sample-and-hold cycle. The front end sample-and-hold output is a fully-differential, sampled-data representation of the analog input. The circuit not only performs the sample-and-hold function but will also convert a single-ended input to a fullydifferential output for the converter core. During the sampling phase, the VIN pins see only the on-resistance of a switch and CS. The relatively small values of these components result in a typical full power input bandwidth of 250MHz for the converter. φ1 VIN+ φ1 φ1 φ1 CS φ2 VIN- CH -+ VOUT+ +- VOUT- CS φ1 CH φ1 FIGURE 24. ANALOG INPUT SAMPLE-AND-HOLD As illustrated in the functional block diagram and the timing diagram in Figure 1, eight identical pipeline subconverter stages, each containing a two-bit flash converter and a two-bit multiplying digital-to-analog converter, follow the S/H circuit with the ninth stage being a two bit flash converter. Each converter stage in the pipeline will be sampling in one phase and amplifying in the other clock phase. Each individual subconverter clock signal is offset by 180 degrees from the previous stage clock signal resulting in alternate stages in the pipeline performing the same operation. The output of each of the eight identical two-bit subconverter stages is a two-bit digital word containing a supplementary bit to be used by the digital error correction logic. The output of each subconverter stage is input to a digital delay line which is controlled by the internal sampling clock. The function of the digital delay line is to time align the digital outputs of the eight identical two-bit subconverter stages with the corresponding output of the ninth stage flash converter before applying the eighteen bit result to the digital error correction logic. The digital error correction logic uses the supplementary bits to correct any error that may exist before generating the final 10-bit digital data output of the converter. 3-111 Because of the pipeline nature of this converter, the digital data representing an analog input sample is output to the digital data bus on the 7th cycle of the clock after the analog sample is taken. This time delay is specified as the data latency. After the data latency time, the digital data representing each succeeding analog sample is output during the following clock cycle. The digital output data is synchronized to the external sampling clock by a double buffered latching technique. The output of the digital error correction circuit is available in two’s complement or offset binary format depending on the state of the Data Format Select (DFS) control input (see Table 1, A/D Code Table). Reference Voltage Inputs, VREF - and VREF+ The HI5766 is designed to accept two external reference voltage sources at the VREF input pins. Typical operation of the converter requires VREF+ to be set at +2.5V and VREF - to be set at 2.0V. However, it should be noted that the input structure of the VREF+ and VREF - input pins consists of a resistive voltage divider with one resistor of the divider (nominally 500Ω) connected between VREF+ and VREF - and the other resistor of the divider (nominally 2000Ω) connected between VREF - and analog ground. This allows the user the option of supplying only the +2.5V VREF+ voltage reference with the +2.0V VREF - being generated internally by the voltage division action of the input structure. The HI5766 is tested with VREF - equal to +2.0V and VREF+ equal to +2.5V yielding a fully differential analog input voltage range of ±0.5V. VREF+ and VREF - can differ from the above voltages. In order to minimize overall converter noise it is recommended that adequate high frequency decoupling be provided at both of the reference voltage input pins, VREF+ and VREF -. Analog Input, Differential Connection The analog input to the HI5766 is a differential input that can be configured in various ways depending on the signal source and the required level of performance. A fully differential connection (Figure 25 and Figure 26) will give the best performance for the converter. VIN+ VIN R HI5766 VDC R -VIN VIN- FIGURE 25. AC COUPLED DIFFERENTIAL INPUT Since the HI5766 is powered by a single +5V analog supply, the analog input is limited to be between ground and +5V. For the differential input connection this implies the analog input common mode voltage can range from 0.25V to 4.75V. HI5766 The performance of the ADC does not change significantly with the value of the analog input common mode voltage. A DC voltage source, VDC, equal to 3.2V (Typ), is made available to the user to help simplify circuit design when using an AC coupled differential input. This low output impedance voltage source is not designed to be a reference but makes an excellent DC bias source and stays well within the analog input common mode voltage range over temperature. For the AC coupled differential input (Figure 25) assume the difference between VREF+, typically 2.5V, and VREF -, typically 2V, is 0.5V. Full scale is achieved when the VIN and -VIN input signals are 0.5VP-P, with -VIN being 180 degrees out of phase with VIN . The converter will be at positive full scale when the VIN+ input is at VDC + 0.25V and the VIN- input is at VDC - 0.25V (VIN+ VIN- = +0.5V). Conversely, the converter will be at negative full scale when the VIN+ input is equal to VDC 0.25V and VIN- is at VDC + 0.25V (VIN+ - VIN- = -0.5V). The analog input can be DC coupled (Figure 26) as long as the inputs are within the analog input common mode voltage range (0.25V ≤ VDC ≤ 4.75V). sinewave, then VIN+ is a 1VP-P sinewave riding on a positive voltage equal to VDC. The converter will be at positive full scale when VIN+ is at VDC + 0.5V (VIN+ - VIN- = +0.5V) and will be at negative full scale when VIN+ is equal to VDC - 0.5V (VIN+ - VIN- = -0.5V). Sufficient headroom must be provided such that the input voltage never goes above +5V or below AGND. In this case, VDC could range between 0.5V and 4.5V without a significant change in ADC performance. The simplest way to produce VDC is to use the DC bias source, VDC , output of the HI5766. The single ended analog input can be DC coupled (Figure 28) as long as the input is within the analog input common mode voltage range. VIN VIN+ VDC R C VDC HI5766 VIN- VIN VIN+ VDC R C FIGURE 28. DC COUPLED SINGLE ENDED INPUT HI5766 VDC -VIN R VDC VIN- FIGURE 26. DC COUPLED DIFFERENTIAL INPUT The resistors, R, in Figure 26 are not absolutely necessary but may be used as load setting resistors. A capacitor, C, connected from VIN+ to VIN- will help filter any high frequency noise on the inputs, also improving performance. Values around 20pF are sufficient and can be used on AC coupled inputs as well. Note, however, that the value of capacitor C chosen must take into account the highest frequency component of the analog input signal. Analog Input, Single-Ended Connection The configuration shown in Figure 27 may be used with a single ended AC coupled input. VIN+ VIN R HI5766 VDC VIN- FIGURE 27. AC COUPLED SINGLE ENDED INPUT Again, assume the difference between VREF+, typically 2.5V, and VREF-, typically 2V, is 0.5V. If VIN is a 1VP-P 3-112 The resistor, R, in Figure 28 is not absolutely necessary but may be used as a load setting resistor. A capacitor, C, connected from VIN+ to VIN- will help filter any high frequency noise on the inputs, also improving performance. Values around 20pF are sufficient and can be used on AC coupled inputs as well. Note, however, that the value of capacitor C chosen must take into account the highest frequency component of the analog input signal. A single ended source may give better overall system performance if it is first converted to differential before driving the HI5766. Digital Output Control and Clock Requirements The HI5766 provides a standard high-speed interface to external TTL logic families. In order to ensure rated performance of the HI5766, the duty cycle of the clock should be held at 50% ±5%. It must also have low jitter and operate at standard TTL levels. Performance of the HI5766 will only be guaranteed at conversion rates above 1 MSPS. This ensures proper performance of the internal dynamic circuits. Similarly, when power is first applied to the converter, a maximum of 20 cycles at a sample rate above 1 MSPS will have to be performed before valid data is available. A Data Format Select (DFS) pin is provided which will determine the format of the digital data outputs. When at logic low, the data will be output in offset binary format. When at logic high, the data will be output in two’s complement format. Refer to Table 1 for further information. HI5766 TABLE 1. A/D CODE TABLE OFFSET BINARY OUTPUT CODE (DFS LOW) TWO’S COMPLEMENT OUTPUT CODE (DFS HIGH) M L M L S S S DIFFERENTIAL S B B B INPUT VOLTAGE B D9 D8 D7 D6 D5 D4 D3 D2 D1 D0 D9 D8 D7 D6 D5 D4 D3 D2 D1 D0 (VIN+ - VIN-) CODE CENTER DESCRIPTION +Full Scale (+FS) -1/4 LSB 0.499756V 1 1 1 1 1 1 1 1 1 1 0 1 1 1 1 1 1 1 1 1 +FS - 11/4 LSB 0.498779V 1 1 1 1 1 1 1 1 1 0 0 1 1 1 1 1 1 1 1 0 +3/4 LSB 732.422µV 1 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 -1/4 LSB -FS + 13/4 LSB -244.141µV 0 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 -0.498291V 0 0 0 0 0 0 0 0 0 1 1 0 0 0 0 0 0 0 0 1 -Full Scale (-FS) + 3/4 LSB -0.499268V 0 0 0 0 0 0 0 0 0 0 1 0 0 0 0 0 0 0 0 0 NOTES: 8. The voltages listed above represent the ideal center of each output code shown as a function of the reference differential voltage, (VREF + - VREF -) = 0.5V. 9. VREF+ = 2.5V and VREF - = 2V. The output enable pin, OE, when pulled high will three-state the digital outputs to a high impedance state. Set the OE input to logic low for normal operation. OE INPUT DIGITAL DATA OUTPUTS 0 Active 1 High Impedance Supply and Ground Considerations The HI5766 has separate analog and digital supply and ground pins to keep digital noise out of the analog signal path. The digital data outputs also have a separate supply pin, DVCC2 , which can be powered from a 3V or 5V supply. This allows the outputs to interface with 3V logic if so desired. The part should be mounted on a board that provides separate low impedance connections for the analog and digital supplies and grounds. For best performance, the supplies to the HI5766 should be driven by clean, linear regulated supplies. The board should also have good high frequency decoupling capacitors mounted as close as possible to the converter. If the part is powered off a single supply then the analog supply should be isolated with a ferrite bead from the digital supply. Refer to the application note “Using Harris High Speed A/D Converters” (AN9214) for additional considerations when using high speed converters. Static Performance Definitions Offset Error (VOS) The midscale code transition should occur at a level 1/4 LSB above half-scale. Offset is defined as the deviation of the actual code transition from this point. Full-Scale Error (FSE) The last code transition should occur for an analog input that is 3/4 LSBs below positive Full Scale (+FS) with the offset 3-113 error removed. Full Scale error is defined as the deviation of the actual code transition from this point. Differential Linearity Error (DNL) DNL is the worst case deviation of a code width from the ideal value of 1 LSB. Integral Linearity Error (INL) INL is the worst case deviation of a code center from a best fit straight line calculated from the measured data. Power Supply Sensitivity Each of the power supplies are moved plus and minus 5% and the shift in the offset and full scale error (in LSBs) is noted. Dynamic Performance Definitions Fast Fourier Transform (FFT) techniques are used to evaluate the dynamic performance of the HI5766. A low distortion sine wave is applied to the input, it is coherently sampled, and the output is stored in RAM. The data is then transformed into the frequency domain with an FFT and analyzed to evaluate the dynamic performance of the A/D. The sine wave input to the part is -0.5dB down from Full scale for all these tests. SNR and SINAD are quoted in dB. The distortion numbers are quoted in dBc (decibels with respect to carrier) and DO NOT include any correction factors for normalizing to full scale. Effective Number Of Bits (ENOB) The effective number of bits (ENOB) is calculated from the SINAD data by: ENOB = (SINAD - 1.76 + VCORR) / 6.02 where: VCORR = 0.5 dB. VCORR adjusts the SINAD, and hence the ENOB, for the amount the analog input signal is below full scale. HI5766 Signal To Noise and Distortion Ratio (SINAD) Video Definitions SINAD is the ratio of the measured RMS signal to RMS sum of all the other spectral components below the Nyquist frequency, fS/2, excluding DC. Differential Gain and Differential Phase are two commonly found video specifications for characterizing the distortion of a chrominance signal as it is offset through the input voltage range of an ADC. Signal To Noise Ratio (SNR) SNR is the ratio of the measured RMS signal to RMS noise at a specified input and sampling frequency. The noise is the RMS sum of all of the spectral components below fS/2 excluding the fundamental, the first five harmonics and DC. Differential Gain (DG) Total Harmonic Distortion (THD) Differential Phase is the peak difference in chrominance phase (in degrees) relative to the reference burst. THD is the ratio of the RMS sum of the first 5 harmonic components to the RMS value of the fundamental input signal. 2nd and 3rd Harmonic Distortion This is the ratio of the RMS value of the applicable harmonic component to the RMS value of the fundamental input signal. Spurious Free Dynamic Range (SFDR) SFDR is the ratio of the fundamental RMS amplitude to the RMS amplitude of the next largest spectral component in the spectrum below fS/2. Intermodulation Distortion (IMD) Nonlinearities in the signal path will tend to generate intermodulation products when two tones, f1 and f2 , are present at the inputs. The ratio of the measured signal to the distortion terms is calculated. The terms included in the calculation are (f1+f2), (f1-f2), (2f1), (2f2), (2f1+f2), (2f1-f2), (f1+2f2), (f1-2f2). The ADC is tested with each tone 6dB below full scale. Differential Gain is the peak difference in chrominance amplitude (in percent) relative to the reference burst. Differential Phase (DP) Timing Definitions Refer to Figure 1 and Figure 2 for these definitions. Aperture Delay (tAP) Aperture delay is the time delay between the external sample command (the falling edge of the clock) and the time at which the signal is actually sampled. This delay is due to internal clock path propagation delays. Aperture Jitter (tAJ) Aperture jitter is the RMS variation in the aperture delay due to variation of internal clock path delays. Data Hold Time (tH) Data hold time is the time to where the previous data (N - 1) is no longer valid. Data Output Delay Time (tOD) Data output delay time is the time to where the new data (N) is valid. Transient Response Transient response is measured by providing a full scale transition to the analog input of the ADC and measuring the number of cycles it takes for the output code to settle within 10-bit accuracy. Over-Voltage Recovery Over-Voltage Recovery is measured by providing a full scale transition to the analog input of the ADC which overdrives the input by 200mV, and measuring the number of cycles it takes for the output code to settle within 10-bit accuracy. Full Power Input Bandwidth (FPBW) Full power input bandwidth is the analog input frequency at which the amplitude of the digitally reconstructed output has decreased 3dB below the amplitude of the input sine wave. The input sine wave has an amplitude which swings from -FS to +FS. The bandwidth given is measured at the specified sampling frequency. 3-114 Data Latency (tLAT) After the analog sample is taken, the digital data representing an analog input sample is output to the digital data bus on the 7th cycle of the clock after the analog sample is taken. This is due to the pipeline nature of the converter where the analog sample has to ripple through the internal subconverter stages. This delay is specified as the data latency. After the data latency time, the digital data representing each succeeding analog sample is output during the following clock cycle. The digital data lags the analog input sample by 7 sample clock cycles. Power-Up Initialization This time is defined as the maximum number of clock cycles that are required to initialize the converter at power-up. The requirement arises from the need to initialize the dynamic circuits within the converter.
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