MAX19192ETI+T

19-5098; Rev 0; 1/10 Ultra-Low-Power, 10Msps, Dual 8-Bit ADC Features The MAX19192 is an ultra-low-power, dual, 8-bit, 10Msps analog-to-digital converter (ADC). The device features two fully differential wideband track-and-hold (T/H) inputs. These inputs have a 440MHz bandwidth and accept fully differential or single-ended signals. The MAX19192 delivers a typical signal-to-noise and distortion (SINAD) of 48.6dB at an input frequency of 1.875MHz and a sampling rate of 10Msps while consuming only 15.3mW. This ADC operates from a 2.7V to 3.6V analog power supply. A separate 1.8V to 3.6V supply powers the digital output driver. In addition to ultra-low operating power, the MAX19192 features three powerdown modes to conserve power during idle periods. Excellent dynamic performance, ultra-low power, and small size make the MAX19192 ideal for applications in imaging, instrumentation, and digital communications. An internal 1.024V precision bandgap reference sets the full-scale range of the ADC to ±0.512V. A flexible reference structure allows the MAX19192 to use its internal reference or accept an externally applied reference for applications requiring increased accuracy. The MAX19192 features parallel, multiplexed, CMOScompatible three-state outputs. The digital output format is offset binary. A separate digital power input accepts a voltage from 1.8V to 3.6V for flexible interfacing to different logic levels. The MAX19192 is available in a 5mm × 5mm, 28-pin thin QFN package, and is specified for the extended industrial (-40°C to +85°C) temperature range. o Ultra-Low Power 15.3mW (Normal Operation: 10Msps) 2µW (Shutdown Mode) o Excellent Dynamic Performance 48.6dB SNR at fIN = 1.875MHz 70dBc SFDR at fIN = 1.875MHz o 2.7V to 3.6V Single Analog Supply o 1.8V to 3.6V TTL/CMOS-Compatible Digital Outputs o Fully Differential or Single-Ended Analog Inputs o Internal/External Reference Option o Multiplexed CMOS-Compatible Three-State Outputs o 28-Pin Thin QFN Package o Evaluation Kit Available (Order MAX19192EVKIT+) +Denotes a lead(Pb)-free/RoHS-compliant package. *EP = Exposed pad. /V denotes an automotive qualified part. **Future product—contact factory for availability. Pin Configuration VDD REFP REFN COM REFIN PD0 PD1 27 26 25 24 23 22 TOP VIEW 21 D0 2 20 D1 GND 3 19 D2 CLK 4 18 D3 GND 5 17 A/B INB+ 6 16 D4 15 D5 VDD 14 7 D6 EXPOSED PAD 13 INB- MAX19192 D7 INA+ + 12 1 OVDD INA- 8 Digital Audio Receiver Front-End 28 Thin QFN-EP* 11 WLAN, Mobile DSL, WLL Receiver 28 Thin QFN-EP* -40°C to +85°C OGND Low-Power Video -40°C to +85°C MAX19192ETI/V+** 10 Battery-Powered Portable Instruments MAX19192ETI+ GND IQ Baseband Sampling PIN-PACKAGE 9 Ultrasound and Medical Imaging TEMP RANGE VDD Applications PART 28 For higher sampling frequency applications, refer to the MAX1195–MAX1198 dual 8-bit ADCs. Pin-compatible versions of the MAX19192 are also available. Refer to the MAX1191 data sheet for 7.5Msps, the MAX1192 data sheet for 22Msps, and the MAX1193 data sheet for 45Msps. Ordering Information 5mm x 5mm THIN QFN ________________________________________________________________ Maxim Integrated Products For pricing, delivery, and ordering information, please contact Maxim Direct at 1-888-629-4642, or visit Maxim’s website at www.maxim-ic.com. 1 MAX19192 General Description MAX19192 Ultra-Low-Power, 10Msps, Dual 8-Bit ADC ABSOLUTE MAXIMUM RATINGS VDD, OVDD to GND ...............................................-0.3V to +3.9V OGND to GND.......................................................-0.3V to +0.3V INA+, INA-, INB+, INB- to GND.............-0.3V to the lesser of (VDD + 0.3V or + 3.9V) CLK, REFIN, REFP, REFN, COM to GND ....-0.3V to the lesser of (VDD + 0.3V or + 3.9V) PD0, PD1 to OGND ...........-0.3V to the lesser of (OVDD + 0.3V or + 3.9V) Digital Outputs to OGND.............................-0.3V to the lesser of (OVDD + 0.3V or + 3.9V) Continuous Power Dissipation (TA = +70°C) 28-Pin Thin QFN (derated 20.8mW/°C above +70°C) ...1667mW Operating Temperature Range ...........................-40°C to +85°C Junction Temperature ......................................................+150°C Storage Temperature Range .............................-65°C to +150°C Lead Temperature (soldering, 10s) .................................+300°C Stresses beyond those listed under “Absolute Maximum Ratings” may cause permanent damage to the device. These are stress ratings only, and functional operation of the device at these or any other conditions beyond those indicated in the operational sections of the specifications is not implied. Exposure to absolute maximum rating conditions for extended periods may affect device reliability. ELECTRICAL CHARACTERISTICS (VDD = 3.0V, OVDD = 1.8V, VREFIN = VDD (internal reference), CL ≈ 10pF at digital outputs, fCLK = 10MHz, CREFP = CREFN = CCOM = 0.33µF, TA = -40°C to +85°C, unless otherwise noted. Typical values are at TA = +25°C.) (Note 1) PARAMETER SYMBOL CONDITIONS MIN TYP MAX UNITS ±0.14 ±1.00 LSB ±0.12 ±1.00 LSB DC ACCURACY Resolution 8 Integral Nonlinearity INL Differential Nonlinearity DNL Offset Error Gain Error No missing codes over temperature Bits ≥ +25°C ±4 < +25°C ±6 Excludes REFP - REFN error ±2 DC Gain Matching ±0.01 Gain Temperature Coefficient ±30 Power-Supply Rejection ±0.2 %FS %FS dB ppm/°C Offset (VDD ±5%) ±0.2 Gain (VDD ±5%) ±0.05 Differential or single-ended inputs ±0.512 V VDD/2 V 540 kΩ 5 pF LSB ANALOG INPUT Differential Input Voltage Range VDIFF Common-Mode Input Voltage Range VCOM Input Resistance RIN Input Capacitance CIN Switched capacitor load CONVERSION RATE Maximum Clock Frequency fCLK Data Latency 10 MHz Channel A 5.0 Channel B 5.5 Clock cycles DYNAMIC CHARACTERISTICS (Differential Inputs, 4096-Point FFT) Signal-to-Noise Ratio (Note 2) Signal-to-Noise and Distortion (Note 2) 2 SNR SINAD fIN = 1.875MHz 47 fIN = 3.0MHz fIN = 1.875MHz fIN = 3.0MHz 48.6 48.6 47 48.6 48.5 _______________________________________________________________________________________ dB dB Ultra-Low-Power, 10Msps, Dual 8-Bit ADC (VDD = 3.0V, OVDD = 1.8V, VREFIN = VDD (internal reference), CL ≈ 10pF at digital outputs, fCLK = 10MHz, CREFP = CREFN = CCOM = 0.33µF, TA = -40°C to +85°C, unless otherwise noted. Typical values are at TA = +25°C.) (Note 1) PARAMETER SYMBOL Spurious-Free Dynamic Range (Note 2) SFDR Third-Harmonic Distortion (Note 2) HD3 Intermodulation Distortion CONDITIONS fIN = 1.875MHz MIN TYP 59 70 fIN = 3.0MHz MAX UNITS dBc 70 fIN = 1.875MHz -71 fIN = 3.0MHz -71 IMD fIN1 = 1.8MHz at -7dBFS, fIN2 = 3.0MHz at -7dBFS -64 dBc Third-Order Intermodulation IM3 fIN1 = 1.8MHz at -7dBFS, fIN2 = 3.0MHz at -7dBFS -64 dBc Total Harmonic Distortion (Note 2) THD fIN = 1.875MHz -69 fIN = 3.0MHz dBc -57.0 -67.0 dBc Small-Signal Bandwidth SSBW Input at -20dBFS 440 MHz Full-Power Bandwidth FPBW Input at -0.5dBFS 440 MHz 1.5 ns 2 psRMS 2 ns Aperture Delay tAD Aperture Jitter tAJ 1.5 × full-scale input Overdrive Recovery Time INTERNAL REFERENCE (REFIN = VDD; VREFP, VREFN, and VCOM are Generated Internally) REFP Output Voltage VREFP - VCOM 0.256 V REFN Output Voltage VREFN - VCOM -0.256 V COM Output Voltage VCOM Differential Reference Output VREF Differential Reference Output Temperature Coefficient Maximum REFP/REFN/COM Source Current Maximum REFP/REFN/COM Sink Current VDD/2 - 0.15 VREFP - VREFN VDD/2 VDD/2 + 0.15 V 0.512 V VREFTC ±30 ppm/°C ISOURCE 2 mA ISINK 2 mA BUFFERED EXTERNAL REFERENCE (VREFIN = 1.024V, VREFP, VREFN, and VCOM are Generated Internally) REFIN Input Voltage VREFIN COM Output Voltage VCOM Differential Reference Output VREF Maximum REFP/REFN/COM Source Current Maximum REFP/REFN/COM Sink Current 1.024 VDD/2 - 0.15 VREFP - VREFN VDD/2 V VDD/2 + 0.15 V 0.512 V ISOURCE 2 mA ISINK 2 mA _______________________________________________________________________________________ 3 MAX19192 ELECTRICAL CHARACTERISTICS (continued) MAX19192 Ultra-Low-Power, 10Msps, Dual 8-Bit ADC ELECTRICAL CHARACTERISTICS (continued) (VDD = 3.0V, OVDD = 1.8V, VREFIN = VDD (internal reference), CL ≈ 10pF at digital outputs, fCLK = 10MHz, CREFP = CREFN = CCOM = 0.33µF, TA = -40°C to +85°C, unless otherwise noted. Typical values are at TA = +25°C.) (Note 1) PARAMETER SYMBOL CONDITIONS MIN REFIN Input Resistance REFIN Input Current TYP MAX UNITS > 500 kΩ -0.7 µA UNBUFFERED EXTERNAL REFERENCE (REFIN = GND, VREFP, VREFN, and VCOM are Applied Externally) REFP Input Voltage VREFP - VCOM 0.256 V REFN Input Voltage VREFN - VCOM -0.256 V VDD/2 V 0.512 V COM Input Voltage VCOM Differential Reference Input Voltage VREF VREFP - VREFN REFP Input Resistance RREFP Measured between REFP and COM 4 kΩ REFN Input Resistance RREFN Measured between REFN and COM 4 kΩ DIGITAL INPUTS (CLK, PD0, PD1) Input High Threshold VIH Input Low Threshold VIL Input Hysteresis CLK 0.7 x VDD PD0, PD1 0.7 x OVDD CLK 0.3 x VDD PD0, PD1 0.3 x OVDD VHYST Digital Input Leakage Current DIIN Digital Input Capacitance DCIN V 0.1 V V CLK at GND or VDD ±5 PD0 and PD1 at OGND or OVDD ±5 5 µA pF DIGITAL OUTPUTS (D7–D0, A/B) Output-Voltage Low VOL ISINK = 200µA Output-Voltage High VOH ISOURCE = 200µA Three-State Leakage Current ILEAK Three-State Output Capacitance COUT 0.2 x OVDD 0.8 x OVDD V V ±5 5 µA pF POWER REQUIREMENTS Analog Supply Voltage Digital Output Supply Voltage Analog Supply Current 4 VDD 2.7 OVDD 1.8 IDD 3.0 Normal operating mode, fIN = 1.875MHz at -0.5dBFS, CLK input from GND to VDD 5.1 Idle mode (three-state), fIN = 1.875MHz at -0.5dBFS, CLK input from GND to VDD 5.1 Standby mode, CLK input from GND to VDD, PD0 = OGND, PD1 = OVDD 2.9 Shutdown mode, CLK = GND or VDD, PD0 = PD1 = OGND 0.6 _______________________________________________________________________________________ 3.6 V VDD V 5.8 mA 5.0 µA Ultra-Low-Power, 10Msps, Dual 8-Bit ADC (VDD = 3.0V, OVDD = 1.8V, VREFIN = VDD (internal reference), CL ≈ 10pF at digital outputs, fCLK = 10MHz, CREFP = CREFN = CCOM = 0.33µF, TA = -40°C to +85°C, unless otherwise noted. Typical values are at TA = +25°C.) (Note 1) PARAMETER Digital Output Supply Current (Note 3) SYMBOL IODD CONDITIONS MIN TYP MAX Normal operating mode, fIN = 1.875MHz at -0.5dBFS, CL ≈ 10pF 1.6 Idle mode (three-state), DC input, CLK = GND or VDD, PD0 = OVDD, PD1 = OGND 0.1 Standby mode, DC input, CLK = GND or VDD, PD0 = OGND, PD1 = OVDD 0.1 Shutdown mode, CLK = GND or VDD, PD0 = PD1 = OGND 0.1 5.0 UNITS mA 5.0 µA TIMING CHARACTERISTICS CLK Rise to CHA Output Data Valid tDOA 50% of CLK to 50% of data, Figure 5 (Note 4) 1 6 8.5 ns CLK Fall to CHB Output Data Valid tDOB 50% of CLK to 50% of data, Figure 5 (Note 4) 1 6 8.5 ns CLK Rise/Fall to A/B Rise/Fall Time tDA/B 50% of CLK to 50% of A/B, Figure 5 (Note 4) 1 6 8.5 ns PD1 Rise to Output Enable tEN PD0 = OVDD 5 ns PD1 Fall to Output Disable tDIS PD0 = OVDD 5 ns CLK Duty Cycle CLK Duty-Cycle Variation 50 % ±10 % Wake-Up Time from Shutdown Mode tWAKE, SD (Note 5) 20 µs Wake-Up Time from Standby Mode tWAKE, ST (Note 5) 5.5 µs 2 ns -75 dB Digital Output Rise/Fall Time 20% to 80% INTERCHANNEL CHARACTERISTICS Crosstalk Rejection fIN,X = 1.875MHz at -0.5dBFS, fIN,Y = 3.0MHz at -0.5dBFS Amplitude Matching fIN = 1.875MHz at -0.5dBFS (Note 6) ±0.03 dB Phase Matching fIN = 1.875MHz at -0.5dBFS (Note 6) ±0.03 Degrees Note 1: Specifications ≥ +25°C guaranteed by production test, < +25°C guaranteed by design and characterization. Note 2: SNR, SINAD, SFDR, HD3, and THD are based on a differential analog input voltage of -0.5dBFS referenced to the amplitude of the digital output. SNR and THD are calculated using HD2 through HD6. Note 3: The power consumption of the output driver is proportional to the load capacitance (CL). Note 4: Guaranteed by design and characterization. Not production tested. Note 5: SINAD settles to within 0.5dB of its typical value. Note 6: Amplitude/phase matching is measured by applying the same signal to each channel, and comparing the magnitude and phase of the fundamental bin on the calculated FFT. _______________________________________________________________________________________ 5 MAX19192 ELECTRICAL CHARACTERISTICS (continued) Typical Operating Characteristics HD3 fINB HD2 MAX19192 toc02 -50 -60 fINA HD2 -30 -40 -50 -70 -80 -80 -80 -90 0.5 1.0 1.5 2.0 2.5 3.0 3.5 4.0 4.5 5.0 TWO-TONE IMD PLOT (DIFFERENTIAL INPUTS, 8192-POINT DATA RECORD) FFT PLOT CHANNEL A (SINGLE-ENDED INPUTS, 8192-POINT DATA RECORD) FFT PLOT (8192 SAMPLES) -40 -50 HD3 -60 fINA -70 HD2 -20 -80 -40 -20 -50 -60 -30 -40 -50 -60 -70 -70 -80 -80 0 -90 0.5 1.0 1.5 2.0 2.5 3.0 3.5 4.0 4.5 5.0 fINB 0 HD2 HD3 0.5 1.0 1.5 2.0 2.5 3.0 3.5 4.0 4.5 5.0 FREQUENCY (MHz) FFT PLOT CHANNEL B (SINGLE-ENDED INPUTS, 8192-POINT DATA RECORD) FFT PLOT (8192 SAMPLES) FFT PLOT CHANNEL A (SINGLE-ENDED INPUTS, 8192-POINT DATA RECORD) FFT PLOT (8192 SAMPLES) FFT PLOT CHANNEL B (SINGLE-ENDED INPUTS, 8192-POINT DATA RECORD) FFT PLOT (8192 SAMPLES) HD2 -30 -40 -50 -60 -70 -70 -80 -80 0.5 1.0 1.5 2.0 2.5 3.0 3.5 4.0 4.5 5.0 FREQUENCY (MHz) MAX19192 toc08 -20 -90 HD3 fINB 0 HD2 fCLK = 10.000000MHz fINA = 2.9870605MHz fINB = 1.7956543MHz AINA = AINB = -0.5dBFS -10 -20 AMPLITUDE (dBFS) fINA fCLK = 10.000000MHz fINA = 2.9870605MHz fINB = 1.7956543MHz AINA = AINB = -0.5dBFS -10 AMPLITUDE (dBFS) HD3 0 MAX19192 toc07 -50 0 fIN2 fCLK = 10.000000MHz fINA = 1.7956543MHz fINB = 2.9870605MHz AINA = AINB = -0.5dBFS ANALOG INPUT FREQUENCY (MHz) -40 -90 fIN1 0 -10 FREQUENCY (MHz) -30 -60 -30 -90 0.5 1.0 1.5 2.0 2.5 3.0 3.5 4.0 4.5 5.0 fCLK = 10.000000MHz fINA = 1.7956543MHz fINB = 2.9870605MHz AINA = AINB = -0.5dBFS -20 fCLK = 10.000000MHz fIN1 = 1.7956543MHz fIN2 = 3.001709MHz AIN1 = AIN2 = -7dBFS MAX19192 toc05 0 -10 AMPLITUDE (dBFS) -30 0 0.5 1.0 1.5 2.0 2.5 3.0 3.5 4.0 4.5 5.0 FFT PLOT CHANNEL B (DIFFERENTIAL INPUTS, 8192-POINT DATA RECORD) FFT PLOT (8192 SAMPLES) -20 -10 0 FREQUENCY (MHz) fCLK = 10.000000MHz fINA = 2.9870605MHz fINB = 1.7956543MHz AINA = AINB = -0.5dBFS 0 -90 0.5 1.0 1.5 2.0 2.5 3.0 3.5 4.0 4.5 5.0 HD2 FREQUENCY (MHz) 0 -90 0 fINB FREQUENCY (MHz) AMPLITUDE (dBFS) 0 HD3 -60 -70 -10 AMPLITUDE (dBFS) -40 HD3 -20 -70 -90 6 -30 fCLK = 10.000000MHz fINA = 2.9870605MHz fINB = 1.7956543MHz AINA = AINB = -0.5dBFS MAX19192 toc06 -50 -60 -20 0 -10 MAX19192 toc09 -40 fCLK = 10.000000MHz fINA = 1.7956543MHz fINB = 2.9870605MHz AINA = AINB = -0.5dBFS AMPLITUDE (dBFS) -30 MAX19192 toc04 AMPLITUDE (dBFS) -20 0 -10 AMPLITUDE (dBFS) fCLK = 10.000000MHz fINA = 1.7956543MHz fINB = 2.9870605MHz AINA = AINB = -0.5dBFS MAX19192 toc01 0 -10 MAX19192 toc03 (VDD = 3.0V, OVDD = 2.5V, VREFIN = VDD (internal reference), CL ≈ 10pF at digital outputs, differential input at -0.5dBFS, fCLK = 10MHz at 50% duty cycle, TA = +25°C, unless otherwise noted.) FFT PLOT CHANNEL A (DIFFERENTIAL FFT PLOT CHANNEL A (DIFFERENTIAL FFT PLOT CHANNEL B (DIFFERENTIAL INPUTS, 8192-POINT DATA RECORD) INPUTS, 8192-POINT DATA RECORD) INPUTS, 8192-POINT DATA RECORD) FFT PLOT (8192 SAMPLES) FFT PLOT (8192 SAMPLES) FFT PLOT (8192 SAMPLES) AMPLITUDE (dBFS) MAX19192 Ultra-Low-Power, 10Msps, Dual 8-Bit ADC -30 -40 -50 -60 fINA -70 HD2 HD3 -80 0 0.5 1.0 1.5 2.0 2.5 3.0 3.5 4.0 4.5 5.0 FREQUENCY (MHz) -90 0 0.5 1.0 1.5 2.0 2.5 3.0 3.5 4.0 4.5 5.0 FREQUENCY (MHz) _______________________________________________________________________________________ Ultra-Low-Power, 10Msps, Dual 8-Bit ADC 49 -55 MAX19192 toc11 50 MAX19192 toc10 50 TOTAL HARMONIC DISTORTION vs. ANALOG INPUT FREQUENCY SIGNAL-TO-NOISE AND DISTORTION vs. ANALOG INPUT FREQUENCY 49 MAX19192 toc12 SIGNAL-TO-NOISE RATIO vs. ANALOG INPUT FREQUENCY -60 47 46 48 THD (dBc) SINAD (dB) SNR (dB) 48 47 -65 46 -70 45 20 40 60 80 100 80 100 0 20 40 60 80 100 SIGNAL-TO-NOISE AND DISTORTION vs. ANALOG INPUT POWER fIN = 2.9902649MHz 40 60 80 100 fIN = 2.9902649MHz 50 SINAD (dB) 50 40 30 10 120 40 30 20 20 CHANNEL A CHANNEL B 20 60 -30 -25 -20 -15 -10 -5 10 0 -30 -25 -20 -15 -10 fIN (MHz) ANALOG INPUT POWER (dBFS) ANALOG INPUT POWER (dBFS) TOTAL HARMONIC DISTORTION vs. ANALOG INPUT POWER SPURIOUS-FREE DYNAMIC RANGE vs. ANALOG INPUT POWER SIGNAL-TO-NOISE RATIO vs. SAMPLING RATE fIN = 2.9902649MHz 70 SFDR (dBc) -40 -50 -60 60 -20 -15 -10 ANALOG INPUT POWER (dBFS) -5 0 0 fIN = 2.9902649MHz 50 48 50 46 40 -25 52 SNR (dB) fIN = 2.9902649MHz -5 MAX19192 toc18 80 MAX19192 toc16 -30 120 MAX19192 toc15 60 MAX19192 toc13 65 -30 -75 120 SIGNAL-TO-NOISE RATIO vs. ANALOG INPUT POWER SNR (dB) SFDR (dBc) 60 SPURIOUS-FREE DYNAMIC RANGE vs. ANALOG INPUT FREQUENCY 60 THD (dBc) 40 fIN (MHz) 70 -70 20 fIN (MHz) 75 0 0 fIN (MHz) 80 55 44 120 CHANNEL A CHANNEL B MAX19192 toc14 0 CHANNEL A CHANNEL B MAX19192 toc17 44 45 CHANNEL A CHANNEL B 30 44 -30 -25 -20 -15 -10 ANALOG INPUT POWER (dBFS) -5 0 6 8 10 12 14 16 18 20 fCLK (MHz) _______________________________________________________________________________________ 7 MAX19192 Typical Operating Characteristics (continued) (VDD = 3.0V, OVDD = 2.5V, VREFIN = VDD (internal reference), CL ≈ 10pF at digital outputs, differential input at -0.5dBFS, fCLK = 10MHz at 50% duty cycle, TA = +25°C, unless otherwise noted.) Typical Operating Characteristics (continued) (VDD = 3.0V, OVDD = 2.5V, VREFIN = VDD (internal reference), CL ≈ 10pF at digital outputs, differential input at -0.5dBFS, fCLK = 10MHz at 50% duty cycle, TA = +25°C, unless otherwise noted.) fIN = 2.9902649MHz fIN = 2.9902649MHz 46 10 12 14 16 18 -75 20 6 8 10 12 14 16 18 60 20 10 12 14 16 18 fCLK (MHz) SIGNAL-TO-NOISE RATIO vs. DUTY CYCLE SIGNAL-TO-NOISE AND DISTORTION vs. DUTY CYCLE TOTAL HARMONIC DISTORTION vs. DUTY CYCLE fIN = 2.9902649MHz 50 SINAD (dB) -55 49 48 fIN = 2.9902649MHz -60 50 55 46 60 -65 -70 -75 47 45 40 45 50 55 -80 60 40 45 50 60 55 DUTY CYCLE (%) DUTY CYCLE (%) DUTY CYCLE (%) SPURIOUS-FREE DYNAMIC RANGE vs. DUTY CYCLE INTEGRAL NONLINEARITY vs. DIGITAL OUTPUT CODE DIFFERENTIAL NONLINEARITY vs. DIGITAL OUTPUT CODE 80 0.3 0.2 0.2 0.1 INL (LSB) 70 65 0 50 DUTY CYCLE (%) 55 60 0 -0.1 -0.1 -0.2 -0.2 -0.3 45 DNL (LSB) 0.1 75 MAX19192 toc27 fIN = 2.9902649MHz MAX19192 toc26 0.3 MAX19192 toc25 85 20 MAX19192 toc24 MAX19192 toc22 51 47 40 8 fCLK (MHz) 48 60 6 fCLK (MHz) 49 40 70 65 THD (dBc) 8 50 SNR (dB) -65 MAX19192 toc23 6 fIN = 2.9902649MHz 8 75 -70 51 46 fIN = 2.9902649MHz SFDR (dBc) 48 44 80 -60 THD (dBc) SINAD (dB) 50 SPURIOUS-FREE DYNAMIC RANGE vs. SAMPLING RATE MAX19192 toc20 -55 MAX19192 toc19 52 TOTAL HARMONIC DISTORTION vs. SAMPLING RATE MAX19192 toc21 SIGNAL-TO-NOISE AND DISTORTION vs. SAMPLING RATE SFDR (dBc) MAX19192 Ultra-Low-Power, 10Msps, Dual 8-Bit ADC 0 32 64 96 128 160 192 DIGITAL OUTPUT CODE 224 256 -0.3 0 32 64 96 128 160 192 DIGITAL OUTPUT CODE _______________________________________________________________________________________ 224 256 Ultra-Low-Power, 10Msps, Dual 8-Bit ADC GAIN ERROR vs. TEMPERATURE 0.2 0.30 0.20 0.10 2 0.1 0 0 FULL-POWER BANDWIDTH -0.5dBFS -2 -4 -0.1 -6 -0.2 CHANNEL A CHANNEL B 0 -15 10 35 60 -0.3 85 CHANNEL A CHANNEL B -8 -10 -40 -15 10 TEMPERATURE (°C) 35 85 60 100 10 1000 ANALOG INPUT FREQUENCY (MHz) REFERENCE VOLTAGE vs. TEMPERATURE REFERENCE VOLTAGE vs. ANALOG SUPPLY VOLTAGE 0.5140 VREFP - VREFN (V) 0.5120 MAX19192 toc32 0.5160 MAX19192 toc31 0.5130 0.5110 0.5100 0.5090 0.5120 0.5100 0.5080 0.5060 0.5040 2.7 2.8 2.9 3.0 3.1 3.2 3.3 3.4 3.5 3.6 -40 -15 ANALOG SUPPLY VOLTAGE (V) 10 35 60 85 TEMPERATURE (°C) SUPPLY CURRENT vs. SAMPLING RATE 10 MAX19192 toc33 0.5080 1 TEMPERATURE (°C) fIN = 2.9902649MHz 8 SUPPLY CURRENT (mA) -40 VREFP - VREFN (V) -0.10 SMALL-SIGNAL BANDWIDTH -20dBFS 4 GAIN (dB) GAIN ERROR (%FS) 0.40 6 MAX19192 toc29 0.50 OFFSET ERROR (%FS) 0.3 MAX19192 toc28 0.60 INPUT BANDWIDTH vs. ANALOG INPUT FREQUENCY MAX19192 toc30 OFFSET ERROR vs. TEMPERATURE 6 A B 4 C 2 0 0 5 10 15 20 fCLK (MHz) A: ANALOG SUPPLY CURRENT (IVDD) - INTERNAL AND BUFFERED EXTERNAL REFERENCE MODES B: ANALOG SUPPLY CURRENT (IVDD) - UNBUFFERED EXTERNAL REFERENCE MODE C: DIGITAL SUPPLY CURRENT (IOVDD) - OVDD = 2.5V, ALL REFERENCE MODES _______________________________________________________________________________________ 9 MAX19192 Typical Operating Characteristics (continued) (VDD = 3.0V, OVDD = 2.5V, VREFIN = VDD (internal reference), CL ≈ 10pF at digital outputs, differential input at -0.5dBFS, fCLK = 10MHz at 50% duty cycle, TA = +25°C, unless otherwise noted.) Ultra-Low-Power, 10Msps, Dual 8-Bit ADC MAX19192 Pin Description 10 PIN NAME 1 INA- Channel A Negative Analog Input. For single-ended operation, connect INA- to COM. FUNCTION 2 INA+ Channel A Positive Analog Input. For single-ended operation, connect signal source to INA+. 3, 5, 10 GND Analog Ground. Connect all GND pins together. 4 CLK Converter Clock Input 6 INB+ Channel B Positive Analog Input. For single-ended operation, connect signal source to INB+. 7 INB- Channel B Negative Analog Input. For single-ended operation, connect INB- to COM. 8, 9, 28 VDD Converter Power Input. Connect to a 2.7V to 3.6V power supply. Bypass VDD to GND with a combination of a 2.2μF capacitor in parallel with a 0.1μF capacitor. 11 OGND Output Driver Ground 12 OVDD Output Driver Power Input. Connect to a 1.8V to VDD power supply. Bypass OVDD to GND with a combination of a 2.2μF capacitor in parallel with a 0.1μF capacitor. 13 D7 Three-State Digital Output. D7 is the most significant bit (MSB). 14 D6 Three-State Digital Output 15 D5 Three-State Digital Output 16 D4 Three-State Digital Output 17 A/B Channel Data Indicator. This digital output indicates channel A data (A/B = 1) or channel B data (A/B = 0) is present on the output. 18 D3 Three-State Digital Output 19 D2 Three-State Digital Output 20 D1 Three-State Digital Output 21 D0 22 PD1 Three-State Digital Output. D0 is the least significant bit (LSB). Power-Down Digital Input 1. See Table 3. 23 PD0 24 REFIN Reference Input. Internally pulled up to VDD. Power-Down Digital Input 0. See Table 3. 25 COM Common-Mode Voltage I/O. Bypass COM to GND with a 0.33μF capacitor. 26 REFN Negative Reference I/O. Conversion range is ±(VREFP - VREFN). Bypass REFN to GND with a 0.33μF capacitor. 27 REFP Positive Reference I/O. Conversion range is ±(VREFP - VREFN). Bypass REFP to GND with a 0.33μF capacitor. — EP Exposed Pad. Internally connected to pin 3. Externally connect EP to GND. ______________________________________________________________________________________ Ultra-Low-Power, 10Msps, Dual 8-Bit ADC The MAX19192 uses a seven-stage, fully differential, pipelined architecture (Figure 1) that allows for highspeed conversion while minimizing power consumption. Samples taken at the inputs move progressively through the pipeline stages every half-clock cycle. Including the delay through the output latch, the total clock-cycle latency is 5 clock cycles for channel A and 5.5 clock cycles for channel B. At each stage, flash ADCs convert the held input voltages into a digital code. The following digital-to-analog converter (DAC) converts the digitized result back into an analog voltage, which is then subtracted from the original held input signal. The resulting error signal is then multiplied by two, and the product is passed along to the next pipeline stage where the process is repeated until the signal has been processed by all stages. Digital error correction compensates for ADC comparator offsets in each pipeline stage and ensures no missing codes. Figure 2 shows the MAX19192 functional diagram. x2 DAC 1.5 BITS INA+ STAGE 1 T/H STAGE 2 STAGE 7 INA- DIGITAL ERROR CORRECTION D0–D7 Figure 1. Pipeline Architecture—Stage Blocks INA+ T/H INA- REFIN REFP PIPELINE ADC A / DEC REFERENCE SYSTEM AND BIAS CIRCUITS COM REFN VDD GND MAX19192 POWER CONTROL PD0 PD1 OVDD D0–D7 MULTIPLEXER OUTPUT DRIVERS A/B OGND INB+ T/H INB- PIPELINE ADC B / DEC / FLASH ADC / T/H / + TIMING CLK Figure 2. MAX19192 Functional Diagram ______________________________________________________________________________________ 11 MAX19192 Detailed Description MAX19192 Ultra-Low-Power, 10Msps, Dual 8-Bit ADC INTERNAL BIAS COM S5a S2a C1a S3a S4a INA+ OUT C2a S4c S1 OUT INAS4b C2b C1b S3b S5b S2b INTERNAL BIAS COM HOLD INTERNAL BIAS TRACK COM CLK HOLD TRACK INTERNAL NONOVERLAPPING CLOCK SIGNALS S5a S2a C1a S3a S4a INB+ OUT C2a S4c S1 MAX19192 OUT INBS4b C2b C1b S3b S5b S2b INTERNAL BIAS COM Figure 3. Internal T/H Circuits Input Track-and-Hold (T/H) Circuits Figure 3 displays a simplified functional diagram of the input T/H circuits. In track mode, switches S1, S2a, S2b, S4a, S4b, S5a, and S5b are closed. The fully differential circuits sample the input signals onto the two capacitors (C2a and C2b) through switches S4a and S4b. S2a and S2b set the common mode for the ampli12 fier input, and open simultaneously with S1, sampling the input waveform. Switches S4a, S4b, S5a, and S5b are then opened before switches S3a and S3b connect capacitors C1a and C1b to the output of the amplifier and switch S4c is closed. The resulting differential voltages are held on capacitors C2a and C2b. The amplifiers charge capacitors C1a and C1b to the same ______________________________________________________________________________________ Ultra-Low-Power, 10Msps, Dual 8-Bit ADC VREFIN REFERENCE MODE > 0.8 x VDD Internal reference mode. VREF is internally generated to be 0.512V. Bypass REFP, REFN, and COM each with a 0.33μF capacitor. 1.024V ±10% Buffered external reference mode. An external 1.024V ±10% reference voltage is applied to REFIN. VREF is internally generated to be VREFIN/2. Bypass REFP, REFN, and COM each with a 0.33μF capacitor. Bypass REFIN to GND with a 0.1μF capacitor. < 0.3V Unbuffered external reference mode. REFP, REFN, and COM are driven by external reference sources. VREF is the difference between the externally applied VREFP and VREFN. Bypass REFP, REFN, and COM each with a 0.33μF capacitor. values originally held on C2a and C2b. These values are then presented to the first stage quantizers and isolate the pipelines from the fast-changing inputs. The wide input bandwidth T/H amplifiers allow the MAX19192 to track and sample/hold analog inputs of high frequencies (> Nyquist). Both ADC inputs (INA+, INB+, INA-, and INB-) can be driven either differentially or single ended. Match the impedance of INA+ and INA-, as well as INB+ and INB-, and set the commonmode voltage to midsupply (VDD/2) for optimum performance. Analog Inputs and Reference Configurations The MAX19192 full-scale analog input range is ±VREF with a common-mode input range of VDD/2 ±0.2V. VREF is the difference between V REFP and V REFN . The MAX19192 provides three modes of reference operation. The voltage at REFIN (VREFIN) sets the reference operation mode (Table 1). In internal reference mode, connect REFIN to VDD or leave REFIN unconnected. VREF is internally generated to be 0.512V ±3%. COM, REFP, and REFN are lowimpedance outputs with VCOM = VDD/2, VREFP = VDD/2 + VREF/2, and VREFN = VDD/2 - VREF/2. Bypass REFP, REFN, and COM each with a 0.33µF capacitor. In buffered external reference mode, apply a 1.024V ±10% at REFIN. In this mode, COM, REFP, and REFN are low-impedance outputs with VCOM = VDD/2, VREFP = V DD /2 + V REFIN /4, and V REFN = V DD /2 - V REFIN /4. Bypass REFP, REFN, and COM each with a 0.33µF capacitor. Bypass REFIN to GND with a 0.1µF capacitor. In unbuffered external reference mode, connect REFIN to GND. This deactivates the on-chip reference buffers for COM, REFP, and REFN. With their buffers shut down, these nodes become high-impedance inputs (Figure 4) and can be driven through separate, external 62.5μA MAX19192 REFP 1.75V 4kΩ 0μA COM 1.5V 4kΩ 62.5μA REFN 1.25V Figure 4. Unbuffered External Reference Mode Impedance reference sources. Drive VCOM to VDD/2 ±10%, drive VREFP to (VDD/2 +0.256V) ±10%, and drive VREFN to (VDD/2 - 0.256V) ±10%. Bypass REFP, REFN, and COM each with a 0.33µF capacitor. For detailed circuit suggestions and how to drive this dual ADC in buffered/unbuffered external reference mode, see the Applications Information section. Clock Input (CLK) CLK accepts a CMOS-compatible signal level. Since the interstage conversion of the device depends on the repeatability of the rising and falling edges of the external clock, use a clock with low jitter and fast rise and fall times (< 2ns). In particular, sampling occurs on the ______________________________________________________________________________________ 13 MAX19192 Table 1. Reference Modes MAX19192 Ultra-Low-Power, 10Msps, Dual 8-Bit ADC 5 CLOCK-CYCLE LATENCY (CHA), 5.5 CLOCK-CYCLE LATENCY (CHB) CHA CHB tCLK tCL tCH CLK tDOB A/B tDOA CHB CHA CHB CHA CHB CHA CHB CHA CHB CHA CHB CHA CHB D0B D1A D1B D2A D2B D3A D3B D4A D4B D5A D5B D6A D6B tDA/B D0–D7 Figure 5. System Timing Diagram rising edge of the clock signal, requiring this edge to provide lowest possible jitter. Any significant aperture jitter would limit the SNR performance of the on-chip ADCs as follows: 2 x VREF 256 VREF 14 VREF VREF 1111 1111 1111 1110 1111 1101 1000 0001 1000 0000 0111 1111 (COM) 0000 0011 0000 0010 0000 0001 0000 0000 -128 -127 -126 -125 -1 0 +1 +125 +126 +127 +128 (COM) System Timing Requirements Figure 5 shows the relationship between the clock, analog inputs, A/B indicator, and the resulting output data. Channel A (CHA) and channel B (CHB) are simultaneously sampled on the rising edge of the clock signal (CLK) and the resulting data is multiplexed at the output. CHA data is updated on the rising edge and CHB data is updated on the falling edge of the CLK. The A/B indicator follows CLK with a typical delay time of 6ns and remains high when CHA data is updated and low when CHB data is updated. Including the delay through the output latch, the total clock-cycle latency is 5 clock cycles for CHA and 5.5 clock cycles for CHB. VREF = VREFP - VREFN VREF where fIN represents the analog input frequency and tAJ is the time of the aperture jitter. Clock jitter is especially critical for undersampling applications. The clock input should always be considered as an analog input and routed away from any analog input or other digital signal lines. The MAX19192 clock input operates with a VDD/2 voltage threshold and accepts a 50% ±10% duty cycle (see the Typical Operating Characteristics). OFFSET BINARY OUTPUT CODE (LSB) ⎛ ⎞ 1 SNR = 20 × log ⎜ ⎟ 2 × π × f × t ⎝ IN AJ ⎠ 1LSB = INPUT VOLTAGE (LSB) Figure 6. Transfer Function Digital Output Data (D0–D7), Channel Data Indicator (A/B) D0–D7 and A/B are TTL/CMOS-logic compatible. The digital output coding is offset binary (Table 2, Figure 6). The capacitive load on the digital outputs D0–D7 should be kept as low as possible (< 15pF) to avoid large digital currents feeding back into the analog portion of the MAX19192 and degrading its dynamic performance. Buffers on the digital outputs isolate them ______________________________________________________________________________________ Ultra-Low-Power, 10Msps, Dual 8-Bit ADC MAX19192 Table 2. Output Codes vs. Input Voltage DIFFERENTIAL INPUT VOLTAGE (IN+ - IN-) DIFFERENTIAL INPUT (LSB) OFFSET BINARY (D7–D0) OUTPUT DECIMAL CODE VREF × 127 128 +127 (+ full scale - 1 LSB) 1111 1111 255 VREF × 126 128 +126 (+ full scale - 2 LSB) 1111 1110 254 VREF × 1 128 +1 1000 0001 129 VREF × 0 128 0 (bipolar zero) 1000 0000 128 - VREF × 1 128 -1 0111 1111 127 - VREF × 127 128 -127 (- full scale + 1 LSB) 0000 0001 1 - VREF × 128 128 -128 (- full scale) 0000 0000 0 Table 3. Power Logic PD0 PD1 POWER MODE 0 0 Shutdown 0 1 Standby 1 0 Idle 1 1 Normal operating INTERNAL REFERENCE CLOCK DISTRIBUTION OUTPUTS Off Off Off Three-state Off On On Three-state On On On Three-state On On On On ADC from heavy capacitive loads. To improve the dynamic performance of the MAX19192, add 100Ω resistors in series with the digital outputs close to the MAX19192. Refer to the MAX19192 evaluation kit schematic for an example of the digital outputs driving a digital buffer through 100Ω series resistors. Power Modes (PD0, PD1) The MAX19192 has four power modes that are controlled with PD0 and PD1. Four power modes allow the MAX19192 to efficiently use power by transitioning to a low-power state when conversions are not required (Table 3). Shutdown mode offers the most dramatic power savings by shutting down all the analog sections of the MAX19192 and placing the outputs in three-state. The wake-up time from shutdown mode is dominated by the time required to charge the capacitors at REFP, REFN, and COM. In internal reference mode and buffered external reference mode, the wake-up time is typically 20µs. When operating in the unbuffered external reference mode, the wake-up time is dependent on the external reference drivers. When the outputs transition from three-state to on, the last converted word is placed on the digital outputs. In standby mode, the reference and clock distribution circuits are powered up, but the pipeline ADCs are unpowered and the outputs are in three-state. The wake-up time from standby mode is dominated by the 5.5µs required to activate the pipeline ADCs. When the outputs transition from three-state to on, the last converted word is placed on the digital outputs. ______________________________________________________________________________________ 15 MAX19192 Ultra-Low-Power, 10Msps, Dual 8-Bit ADC R4 600Ω R5 600Ω MAX19192 RISO 22Ω R1 600Ω VCOM = 0.5V TO 1.5V VSIG = ±85mVP-P R2 300Ω R3 600Ω INACIN 5pF R6 600Ω R7 600Ω COM AV = 6V/V VCOM = VDD/2 R8 600Ω R9 600Ω RISO 22Ω CIN 5pF R10 600Ω OPERATIONAL AMPLIFIERS CHOOSE EITHER OF THE MAX4452/MAX4453/MAX4454 SINGLE/ DUAL/QUAD 3V, 200MHz OP AMPS FOR USE WITH THIS CIRCUIT. CONNECT THE POSITIVE SUPPLY RAIL (VCC) TO 3V. CONNECT THE NEGATIVE SUPPLY RAIL (VEE) TO GROUND. DECOUPLE VCC WITH A 0.1μF CAPACITOR TO GROUND. INA+ R11 600Ω RESISTOR NETWORKS RESISTOR NETWORKS ENSURE PROPER THERMAL AND TOLERANCE MATCHING. FOR R1, R2, AND R3 USE A NETWORK SUCH AS VISHAY'S 3R MODEL NUMBER 300192. FOR R4–R11, USE A NETWORK SUCH AS VISHAY'S 4R MODEL NUMBER 300197. Figure 7. DC-Coupled Differential Input Driver In idle mode, the pipeline ADCs, reference, and clock distribution circuits are powered, but the outputs are forced to three-state. The wake-up time from idle mode is dominated by the 5ns required for the output drivers to start from three-state. When the outputs transition from three-state to on, the last converted word is placed on the digital outputs. In the normal operating mode, all sections of the MAX19192 are powered. 16 Applications Information The circuit of Figure 7 operates from a single 3V supply and accommodates a wide 0.5V to 1.5V input commonmode voltage range for the analog interface between an RF quadrature demodulator (differential, DC-coupled signal source) and a high-speed ADC. Furthermore, the circuit provides required SINAD and SFDR to demodulate a wideband (BW = 3.84MHz), QAM-16 communication link. RISO isolates the op amp output from the ADC capacitive input to prevent ringing and oscillation. CIN filters high-frequency noise. ______________________________________________________________________________________ Ultra-Low-Power, 10Msps, Dual 8-Bit ADC MAX19192 REFP 25Ω INA+ 22pF 1kΩ VIN 0.1μF 1 VIN T1 RISO 50Ω 6 INA+ MAX4108 2 5 3 4 N.C. 0.1μF 100Ω 1kΩ COM 2.2μF CIN 22pF 0.1μF COM REFN MINICIRCUITS TT1-6-KK81 0.1μF RISO 50Ω 25Ω INA- INA- 100Ω CIN 22pF 22pF MAX19192 REFP 25Ω MAX19192 INB+ 22pF VIN 0.1μF 1 VIN N.C. T1 0.1μF 1kΩ RISO 50Ω 6 INB+ MAX4108 2 5 3 4 100Ω 2.2μF 1kΩ CIN 22pF 0.1μF REFN MINICIRCUITS TT1-6-KK81 0.1μF RISO 50Ω 25Ω INB22pF Figure 8. Transformer-Coupled Input Drive Using Transformer Coupling An RF transformer (Figure 8) provides an excellent solution to convert a single-ended source signal to a fully differential signal, required by the MAX19192 for optimum performance. Connecting the center tap of the transformer to COM provides a VDD/2 DC level shift to the input. Although a 1:1 transformer is shown, a stepup transformer can be selected to reduce the drive requirements. A reduced signal swing from the input driver, such as an op amp, can also improve the overall distortion. In general, the MAX19192 provides better SFDR and THD with fully differential input signals than singleended drive, especially for high input frequencies. In differential input mode, even-order harmonics are lower as both inputs (INA+, INA- and/or INB+, INB-) are bal- 100Ω INBCIN 22pF Figure 9. Using an Op Amp for Single-Ended, AC-Coupled Input Drive anced, and each of the ADC inputs only requires half the signal swing compared to single-ended mode. Single-Ended AC-Coupled Input Signal Figure 9 shows an AC-coupled, single-ended application. Amplifiers such as the MAX4108 provide high speed, high bandwidth, low noise, and low distortion to maintain the input signal integrity. Buffered External Reference Drives Multiple ADCs The buffered external reference mode allows for more control over the MAX19192 reference voltage and allows multiple converters to use a common reference. To drive one MAX19192 in buffered external reference mode, the external circuit must sink 0.7µA, allowing one reference circuit to easily drive the REFIN of multiple converters to 1.024V ±10%. ______________________________________________________________________________________ 17 MAX19192 Ultra-Low-Power, 10Msps, Dual 8-Bit ADC 3V 24 0.1μF 1.248V VDD REFIN 0.1μF 1 2 27 MAX6061 3 10Hz LOWPASS FILTER N=1 REFP 0.33μF 1% 20kΩ MAX19192 26 REFN 0.33μF 1μF 1% 90.9kΩ 25 3V 5 3 NOTE: ONE FRONT-END REFERENCE CIRCUIT PROVIDES ±15mA OF OUTPUT DRIVE AND SUPPORTS OVER 1000 MAX19192s. MAX4250 4 COM GND 0.33μF 0.1μF 1 15Ω 2 1.023V 24 VDD REFIN 0.1μF 2.2μF 0.1μF 27 REFP N = 1000 0.33μF MAX19192 26 REFN 0.33μF 25 COM 0.33μF GND Figure 10. External Buffered (MAX4250) Reference Drive Using a MAX6061 Bandgap Reference Figure 10 shows the MAX6061 precision bandgap reference used as a common reference for multiple converters. The 1.248V output of the MAX6061 is divided down to 1.023V as it passes through a one-pole, 10Hz, lowpass filter to the MAX4250. The MAX4250 buffers the 1.023V reference before its output is applied to the MAX19192. The MAX4250 provides a low offset voltage (for high gain accuracy) and a low noise level. 18 Unbuffered External Reference Drives Multiple ADCs The unbuffered external reference mode allows for precise control over the MAX19192 reference and allows multiple converters to use a common reference. Connecting REFIN to GND disables the internal reference, allowing REFP, REFN, and COM to be driven directly by a set of external reference sources. ______________________________________________________________________________________ Ultra-Low-Power, 10Msps, Dual 8-Bit ADC MAX19192 3V 2.500V 1 0.1μF 2 27 MAX6066 1% 30.1kΩ 3 3 10μF 6V 0.1μF 12 1MΩ 13 14 MAX4254 10μF 6V 24 COM GND 0.33μF 0.1μF 27 330μF 6V 1.47kΩ VDD REFP N = 160 0.33μF 47Ω 8 MAX4254 10μF 6V 2.2μF 1.47kΩ 1.248V 1/4 11 25 330μF 6V 10 9 REFIN 47Ω 7 1% 10.0kΩ 4 1/4 1.47kΩ MAX4254 3V UNCOMMITTED MAX19192 1.498V 1/4 1MΩ REFN 0.33μF 330μF 6V 1% 10.0kΩ 5 6 26 47Ω 1 MAX4254 1μF NOTE: ONE FRONT-END REFERENCE CIRCUIT SUPPORTS UP TO 160 MAX19192s. N=1 0.33μF 1.748V 1/4 2 VDD REFP 26 REFN MAX19192 REFIN 24 0.33μF 1% 49.9kΩ 25 0.33μF COM GND Figure 11. External Unbuffered Reference Driving 160 ADCs with the MAX4254 and MAX6066 Figure 11 shows the MAX6066 precision bandgap reference used as a common reference for multiple converters. The 2.500V output of the MAX6066 is followed by a 10Hz lowpass filter and precision voltage-divider. The MAX4254 buffers the taps of this divider to provide the 1.75V, 1.5V, and 1.25V sources to drive REFP, REFN, and COM. The MAX4254 provides a low offset voltage and low noise level. The individual voltage followers are connected to 10Hz lowpass filters, which filter both the reference-voltage and amplifier noise to a level of 3nV/√Hz. The 1.75V and 1.25V reference volt- ages set the differential full-scale range of the associated ADCs at ±0.5V. The common power supply for all active components removes any concern regarding power-supply sequencing when powering up or down. With the outputs of the MAX4252 matching better than 0.1%, the buffers and subsequent lowpass filters support as many as 160 MAX19192s. ______________________________________________________________________________________ 19 MAX19192 Ultra-Low-Power, 10Msps, Dual 8-Bit ADC A/B MAX2451 INA+ INA0° 90° MAX19192 DSP POSTPROCESSING INB+ INBDOWNCONVERTER ÷8 Figure 12. Typical QAM Receiver Application Typical QAM Demodulation Application Quadrature amplitude modulation (QAM) is frequently used in digital communications. Typically found in spread-spectrum-based systems, a QAM signal represents a carrier frequency modulated in both amplitude and phase. At the transmitter, modulating the baseband signal with quadrature outputs, a local oscillator followed by subsequent upconversion can generate the QAM signal. The result is an in-phase (I) and a quadrature (Q) carrier component, where the Q component is 90° phase shifted with respect to the in-phase component. At the receiver, the QAM signal is demodulated into analog I and Q components. Figure 12 displays the demodulation process performed in the analog domain using the MAX19192 dual-matched, 3V, 8-bit ADC and the MAX2451 quadrature demodulator to recover and digitize the I and Q baseband signals. Before being digitized by the MAX19192, the mixed-down signal components can be filtered by matched analog filters, such as Nyquist or pulse-shaping filters. The filters remove unwanted images from the mixing process, thereby enhancing the overall signal-to-noise (SNR) performance and minimizing intersymbol interference. Grounding, Bypassing, and Board Layout The MAX19192 requires high-speed board layout design techniques. Refer to the MAX19192 evaluation kit data sheet for a board layout reference. Locate all bypass capacitors as close as possible to the device, 20 preferably on the same side as the ADC, using surfacemount devices for minimum inductance. Bypass VDD to GND with a 0.1µF ceramic capacitor in parallel with a 2.2µF bipolar capacitor. Bypass OVDD to OGND with a 0.1µF ceramic capacitor in parallel with a 2.2µF bipolar capacitor. Bypass REFP, REFN, and COM each to GND with a 0.33µF ceramic capacitor. Multilayer boards with separated ground and power planes produce the highest level of signal integrity. Use a split ground plane arranged to match the physical location of the analog ground (GND) and the digital output driver ground (OGND) on the ADC’s package. Connect the MAX19192 exposed backside pad to GND. Join the two ground planes at a single point so that the noisy digital ground currents do not interfere with the analog ground plane. The ideal location of this connection can be determined experimentally at a point along the gap between the two ground planes, which produces optimum results. Make this connection with a low-value, surface-mount resistor (1Ω to 5Ω), a ferrite bead, or a direct short. Alternatively, all ground pins could share the same ground plane, if the ground plane is sufficiently isolated from any noisy, digital systems ground plane (e.g., downstream output buffer or DSP ground plane). Route high-speed digital signal traces away from the sensitive analog traces of either channel. Make sure to isolate the analog input lines to each respective converter to minimize channel-to-channel crosstalk. Keep all signal lines short and free of 90° turns. ______________________________________________________________________________________ Ultra-Low-Power, 10Msps, Dual 8-Bit ADC CLK ANALOG INPUT tAD tAJ SAMPLED DATA (T/H) T/H TRACK HOLD TRACK Figure 13. T/H Aperture Timing Signal-to-Noise Plus Distortion (SINAD) Static Parameter Definitions Integral Nonlinearity (INL) Integral nonlinearity is the deviation of the values on an actual transfer function from a straight line. This straight line can be either a best-straight-line fit or a line drawn between the end points of the transfer function, once offset and gain errors have been nullified. The static linearity parameters for the MAX19192 are measured using the end-point method. Differential Nonlinearity (DNL) Differential nonlinearity is the difference between an actual step width and the ideal value of 1LSB. A DNL error specification of less than 1LSB guarantees no missing codes and a monotonic transfer function. Offset Error Ideally, the midscale MAX19192 transition occurs at 0.5 LSB above midscale. The offset error is the amount of deviation between the measured transition point and the ideal transition point. Gain Error Ideally, the full-scale MAX19192 transition occurs at 1.5 LSB below full-scale. The gain error is the amount of deviation between the measured transition point and the ideal transition point with the offset error removed. Dynamic Parameter Definitions Aperture Jitter Figure 13 depicts the aperture jitter (tAJ), which is the sample-to-sample variation in the aperture delay. Aperture Delay Aperture delay (tAD) is the time defined between the rising edge of the sampling clock and the instant when an actual sample is taken (Figure 13). SINAD is computed by taking the ratio of the RMS signal to the RMS noise. RMS noise includes all spectral components to the Nyquist frequency excluding the the fundamental and the DC offset. Effective Number of Bits (ENOB) ENOB specifies the dynamic performance of an ADC at a specific input frequency and sampling rate. An ideal ADC’s error consists of quantization noise only. ENOB for a full-scale sinusoidal input waveform is computed from: ENOB = SINAD - 1.76 6.02 Total Harmonic Distortion (THD) THD is typically the ratio of the RMS sum of the first five harmonics of the input signal to the fundamental itself. This is expressed as: ⎡ 2 2 2 2 2 ⎢ V2 + V3 + V4 + V5 + V6 THD = 20 × log ⎢ V1 ⎢⎣ ⎤ ⎥ ⎥ ⎥⎦ where V1 is the fundamental amplitude, and V2–V6 are the amplitudes of the 2nd- through 6th-order harmonics. Third Harmonic Distortion (HD3) HD3 is defined as the ratio of the RMS value of the third harmonic component to the fundamental input signal. Spurious-Free Dynamic Range (SFDR) SFDR is the ratio expressed in decibels of the RMS amplitude of the fundamental (maximum signal component) to the RMS value of the next-largest spurious component, excluding DC offset. ______________________________________________________________________________________ 21 MAX19192 Signal-to-Noise Ratio (SNR) For a waveform perfectly reconstructed from digital samples, the theoretical maximum SNR is the ratio of the full-scale analog input (RMS value) to the RMS quantization error (residual error). The ideal, theoretical minimum analog-to-digital noise is caused by quantization error only and results directly from the ADC’s resolution (N bits): SNRdB[max] = 6.02 × N + 1.76 In reality, there are other noise sources besides quantization noise: thermal noise, reference noise, clock jitter, etc. SNR is computed by taking the ratio of the RMS signal to the RMS noise. RMS noise includes all spectral components to the Nyquist frequency excluding the fundamental, the first five harmonics, and the DC offset. MAX19192 Ultra-Low-Power, 10Msps, Dual 8-Bit ADC Intermodulation Distortion (IMD) Small-Signal Bandwidth IMD is the total power of the intermodulation products relative to the total input power when two tones, f1 and f2, are present at the inputs. The intermodulation products are (f1 ± f2), (2 x f1), (2 x f2), (2 x f1 ± f2), (2 x f2 ± f1). The individual input tone levels are at -7dBFS. A small -20dBFS analog input signal is applied to an ADC in such a way that the signal’s slew rate does not limit the ADC’s performance. The input frequency is then swept up to the point where the amplitude of the digitized conversion result has decreased by -3dB. Note that the track/hold (T/H) performance is usually the limiting factor for the small-signal input bandwidth. Third-Order Intermodulation (IM3) IM3 is the power of the worst third-order intermodulation product relative to the input power of either input tone when two tones, f1 and f2, are present at the inputs. The third-order intermodulation products are (2 x f1 ± f2), (2 x f2 ± f1). The individual input tone levels are at -7dBFS. Power-Supply Rejection Power-supply rejection is defined as the shift in offset and gain error when the power supplies are moved ±5%. Full-Power Bandwidth A large -0.5dBFS analog input signal is applied to an ADC, and the input frequency is swept up to the point where the amplitude of the digitized conversion result has decreased by -3dB. This point is defined as fullpower input bandwidth frequency. Chip Information PROCESS: CMOS Package Information For the latest package outline information and land patterns, go to www.maxim-ic.com/packages. Note that a “+”, “#”, or “-” in the package code indicates RoHS status only. Package drawings may show a different suffix character, but the drawing pertains to the package regardless of RoHS status. PACKAGE TYPE PACKAGE CODE DOCUMENT NO. 28 TQFN-EP T2855+8 21-0140 Maxim cannot assume responsibility for use of any circuitry other than circuitry entirely embodied in a Maxim product. No circuit patent licenses are implied. Maxim reserves the right to change the circuitry and specifications without notice at any time. 22 ____________________Maxim Integrated Products, 120 San Gabriel Drive, Sunnyvale, CA 94086 408-737-7600 © 2010 Maxim Integrated Products Maxim is a registered trademark of Maxim Integrated Products, Inc.