19-2006; Rev 0; 5/01 Dual, 6-Bit, 800Msps ADC with On-Chip, Wideband Input Amplifier In addition, the MAX105 provides LVDS digital outputs with an internal 6:12 demultiplexer that reduces the output data rate to one-half the sample clock rate. Data is output in two's complement format. The MAX105 operates from a +5V analog supply and the LVDS output ports operate at +3.3V. The data converter's typical power dissipation is 2.6W. The device is packaged in an 80-pin, TQFP package with exposed paddle, and is specified for the extended (-40C to +85C) temperature range. For a lower-speed, 400Msps version of the MAX105, please refer to the MAX107 data sheet. Features Two Matched 6-Bit, 800Msps ADCs Excellent Dynamic Performance 36.4dB SINAD at fIN 200MHz and fCLK 800MHz Typical INL and DNL: 0.25LSB Channel-to-Channel Phase Matching: 0.2 Channel-to-Channel Gain Matching: 0.04dB 6:12 Demultiplexer reduces the Data Rates to 400MHz Low Error Rate: 1016 Metastable States at 800Msps LVDS Digital Outputs in Two's Complement Format Ordering Information PART MAX105ECS TEMP. RANGE PIN-PACKAGE -40C to +85C 80-Pin TQFP-EP Block Diagram Applications I PRIMARY PORT VSAT Receivers I ADC WLANs I AUXILIARY PORT Test Instrumentation Communications Systems MAX107 REF Q PRIMARY PORT Q ADC Pin Configuration appears at end of data sheet. Q AUXILIARY PORT ________________________________________________________________ Maxim Integrated Products For pricing, delivery, and ordering information, please contact Maxim/Dallas Direct! at 1-888-629-4642, or visit Maxim's website at www.maxim-ic.com. 1 MAX105 General Description The MAX105 is a dual, 6-bit, analog-to-digital converter (ADC) designed to allow fast and precise digitizing of in-phase (I) and quadrature (Q) baseband signals. The MAX105 converts the analog signals of both I and Q components to digital outputs at 800Msps while achieving a signal-to-noise ratio (SNR) of typically 37dB with an input frequency of 200MHz, and an integral nonlinearity (INL) and differential nonlinearity (DNL) of 0.25 LSB. The MAX105 analog input preamplifiers feature a 400MHz, -0.5dB, and a 1.5GHz, -3dB analog input bandwidth. Matching channel-to-channel performance is typically 0.04dB gain, 0.1LSB offset, and 0.2 degrees phase. Dynamic performance is 36.4dB signal-to-noise plus distortion (SINAD) with a 200MHz analog input signal and a sampling speed of 800MHz. A fully differential comparator design and encoding circuits reduce out-of-sequence errors, and ensure excellent metastable performance of only one error per 1016 clock cycles. MAX105 Dual, 6-Bit, 800Msps ADC with On-Chip, Wideband Input Amplifier ABSOLUTE MAXIMUM RATINGS AVCC, AVCCI, AVCCQ and AVCCR to AGND............-0.3V to +6V OVCCI and OVCCQ to OGND ...................................-0.3V to +4V AGND to OGND ................................................... -0.3V to +0.3V P0I to P5I and A0I to A5I DREADY+, DREADY- to OGNDI .............-0.3V to OVCCI+0.3V P0Q to P5Q, A0Q to A5Q DOR+ and DOR- to OGNDQ ................-0.3V to OVCCQ+0.3V REF to AGNDR...........................................-0.3V to AVCCR+0.3V Differential Voltage Between INI+ and INI- ....................-2V, +2V Differential Voltage Between INQ+ and INQ-.................-2V, +2V Differential Voltage Between CLK+ and CLK- ...............-2V, +2V Maximum Current Into Any Pin ...........................................50mA Continuous Power Dissipation (TA = +70C) 80-Pin TQFP (derate 44mW/C above +70C)..................3.5W Operating Temperature Range MAX105ECS .....................................................-40C to +85C Junction Temperature ......................................................+150C Storage Temperature Range .............................-60C to +150C Lead temperature (soldering, 10s) ..................................+300C 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 (AVCC = AVCCI = AVCCQ = AVCCR = +5V, OVCCI = OVCCQ = +3.3V, AGND = AGNDI = AGNDQ = AGNDR = 0, OGNDI = OGNDQ = 0, fCLK = 802.816MHz, CL = 1F to AGND at REF, RL = 100 1% applied to digital LVDS outputs, TA = TMIN to TMAX, unless otherwise noted. Typical values are at TA = +25C) PARAMETER SYMBOL CONDITIONS MIN TYP MAX UNITS DC ACCURACY Resolution RES 6 Integral Nonlinearity (Note 1) INL -1 0.2 1 LSB Differential Nonlinearity (Note 1) DNL -1 0.25 1 LSB Offset Voltage VOS (Note 2) -1 0.25 1 LSB Offset Matching Between ADCs OM (Note 2) -0.5 0.1 0.5 LSB 2.4 2.5 2.6 V 7.5 mV 3.05 V 0.84 Vp-p No missing codes guaranteed Bits ANALOG INPUTS (INI+, INI-, INQ+, INQ-) Input Open-Circuit Voltage VAOC Input Open-Circuit Voltage Matching (VINI+ - VIN-) - (VINQ+ - VINQ-) Common Mode Input Voltage Range (Note 3) VCM Full-Scale Analog Input Voltage Range (Note 4) VFSR 0.76 Input Resistance RIN 1.7 2 k Input Capacitance CIN 1.5 pF TCRIN 150 ppm/C FPBW-0.5dB 400 MHz Input Resistance Temperature Coefficient Full-Power Analog Input BW Signal + Offset w.r.t. AGND 1.85 0.8 REFERENCE OUTPUT 2 Reference Output Resistance RREF Referenced to AGNDR Reference Output Voltage REF ISOURCE = 500A 5 2.45 2.50 _______________________________________________________________________________________ 2.55 V Dual, 6-Bit, 800Msps ADC with On-Chip, Wideband Input Amplifier (AVCC = AVCCI = AVCCQ = AVCCR = +5V, OVCCI = OVCCQ = +3.3V, AGND = AGNDI = AGNDQ = AGNDR = 0, OGNDI = OGNDQ = 0, fCLK = 802.816MHz, CL = 1F to AGND at REF, RL = 100 1% applied to digital LVDS outputs, TA = TMIN to TMAX, unless otherwise noted. Typical values are at TA = +25C) PARAMETER SYMBOL CONDITIONS MIN TYP MAX UNITS CLOCK INPUTS (CLK+, CLK-) Clock Input Resistance RCLK Clock Input Resistance Temperature Coefficient TCRCLK CLK+ and CLK- to AGND Minimum Clock Input Amplitude 5 k 150 ppm/C 500 mVp-p LVDS OUTPUTS (P0I TO P5I, P0Q TO P5Q, A0I TO A5I, A0Q TO A5Q, DREADY+, DREADY-, DOR+, DOR-) Differential Output Voltage VOD Change in Magnitude of VOD Between "0" and "1" States VOD Steady-State Common Mode Output Voltage VOC(SS) Change in Magnitude of VOC Between "0" and "1" States VOC 247 1.125 Differential Output Resistance 80 Output Current Short output together 2.5 Short to OGNDI = OGNDQ 25 400 mV 25 mV 1.375 V 25 mV 160 mA DYNAMIC SPECIFICATION Effective Number of Bits (Note 8) Signal-to-Noise Ratio (Notes 10, 11) Total Harmonic Distortion (Note 11) fIN = 200.018MHz at -0.5dB FS (Note 9) ENOB fIN = 400.134MHz at -0.5dB FS fIN = 200.018MHz at -0.5dB FS (Note 9) SNR fIN = 400.134MHz at -0.5dB FS fIN = 200.018MHz at -0.5dB FS (Note 9) THD fIN = 400.134MHz at -0.5dB FS fIN = 200.018MHz at -0.5dB FS (Note 9) Spurious-Free Dynamic Range SFDR fIN = 400.134MHz at -0.5dB FS Differential 5.4 5.8 Single-ended 5.75 Differential 5.65 Differential 35 37 Single-ended 36.7 Differential 36.5 Differential -44.5 Single-ended -44.5 Differential Differential Single-ended Differential Bits dB -41 dBc -41 41 45 45 dB 41.5 _______________________________________________________________________________________ 3 MAX105 ELECTRICAL CHARACTERISTICS (continued) MAX105 Dual, 6-Bit, 800Msps ADC with On-Chip, Wideband Input Amplifier ELECTRICAL CHARACTERISTICS (continued) (AVCC = AVCCI = AVCCQ = AVCCR = +5V, OVCCI = OVCCQ = +3.3V, AGND = AGNDI = AGNDQ = AGNDR = 0, OGNDI = OGNDQ = 0, fCLK = 802.816MHz, CL = 1F to AGND at REF, RL = 100 1% applied to digital LVDS outputs, TA = TMIN to TMAX, unless otherwise noted. Typical values are at TA = +25C) PARAMETER Signal-to-Noise Plus Distortion Ratio SYMBOL CONDITIONS fIN = 200.018MHz at -0.5dB FS (Note 9) SINAD fIN = 400.134MHz at -0.5dB FS Differential MIN TYP 34 36.4 Single-ended 36.1 Differential 35.2 MAX UNITS dB Two-Tone Intermodulation TTIMD fIN1 = 124.1660MHz, fIN2 = 126.1260MHz at -7dBFS -52 dBc Crosstalk Between ADCs XTLK fINI = 200.0180MHz, fINQ = 210.0140MHz at -0.5dB FS -70 dB Gain Match Between ADCs GM (Note 12) -0.3 0.04 +0.3 dB Phase Match Between ADCs PM (Note 12) -2 0.2 +2 deg Metastable Error Rate Less than 1 in 1016 Clock Cycles 5 5% V POWER REQUIREMENTS Analog Supply Voltage AVCC_ AVCC = AVCCI = AVCCQ = AVCCR Digital Supply Voltage OVCC_ OVCC I = OVCC Q Analog Supply Current ICC 3.3 10% V ICC = AICCR + AICCI + AICCQ + AICC 250 320 mA OICC = OICC I + OICC Q 400 510 mA Output Supply Current OICC Analog Power Dissipation PDISS Common-Mode Rejection Ratio CMRR VIN_+ = VIN_- = 0.1V (Note 6) Power-Supply Rejection Ratio PSRR AVCC = AVCC I = AVCC Q = AVCC R = +4.75V to +5.25V (Note 7) 2.6 W 40 60 dB 40 57 dB TIMING CHARACTERISTICS 4 Maximum Sample Rate fMAX 800 Msps Clock Pulse Width Low tPWL 0.56 ns Clock Pulse Width High tPWH 0.56 ns Aperture Delay tAD 100 ps Aperture Jitter tAJ 1.5 psRMS 1.5 ns CLK-to-DREADY Propagation Delay tPD1 (Note 13) DREADY-to-DATA Propagation Delay tPD2 (Notes 5, 13) 0 120 _______________________________________________________________________________________ 300 ps Dual, 6-Bit, 800Msps ADC with On-Chip, Wideband Input Amplifier (AVCC = AVCCI = AVCCQ = AVCCR = +5V, OVCCI = OVCCQ = +3.3V, AGND = AGNDI = AGNDQ = AGNDR = 0, OGNDI = OGNDQ = 0, fCLK = 802.816MHz, CL= 1F to AGND at REF, RL = 100 1% applied to digital LVDS outputs, TA = TMIN to TMAX, unless otherwise noted. Typical values are at TA = +25C) PARAMETER SYMBOL DREADY Duty Cycle MAX UNITS (Notes 5, 13) CONDITIONS MIN 47 TYP 53 % ps LVDS Output Rise-Time tRDATA 20% to 80% (Notes 5, 13) 200 500 LVDS Output Fall-Time tFDATA 20% to 80% (Notes 5, 13) 200 500 LVDS Differential Skew tSKEW1 Any differential pair <65 Any two LVDS output signals except DREADY ps ps <100 ps DREADY Rise-Time tRDREADY 20% to 80% (Notes 5, 13) 200 500 ps DREADY Fall-Time tFDREADY 20% to 80% (Notes 5, 13) 200 500 ps Primary Port Pipeline Delay tPDP 5 Clock Cycles Auxiliary Port Pipeline Delay tPDA 6 Clock Cycles Note 1: Note 2: Note 3: Note 4: Note 5: Note 6: Note 7: Note 8: Note 9: Note 10: Note 11: Note 12: Note 13: NL and DNL is measured using a sine-histogram method. Input offset is the voltage required to cause a transition between codes 0 and -1. Numbers provided are for DC-coupled case. The user has the choice of AC-coupling, in which case, the DC input voltage level does not matter. The peak-to-peak input voltage required, causing a full-scale digitized output when using a trigonometric curve-fitting algorithm (e.g. FFT). Guaranteed by design and characterization. Common-mode rejection ratio is defined as the ratio of the change in the offset voltage to the change in the commonmode voltage expressed in dB. Measured with analog power supplies tied to the same potential. Effective number of bits (ENOB) is computed from a curve-fit referenced to the theoretical full-scale range. The clock and input frequencies are chosen so that there are 2041 cycles in an 8,192-long record. Signal-to-noise-ratio (SNR) is measured both with the other channel idling and converting an out-of-phase signal. The worst case number is presented. Harmonic distortion components two through five are excluded from the noise. Harmonic distortion components two through five are included in the total harmonic distortion specification. Both I and Q inputs are effectively tied together (e.g. driven by power splitter). Signal amplitude is -0.5dB FS at an input frequency of fIN = 200.0180 MHz. Measured with a differential probe, 1pF capacitance. _______________________________________________________________________________________ 5 MAX105 ELECTRICAL CHARACTERISTICS (continued) Typical Operating Characteristics (AVCC = AVCCI = AVCCQ = AVCCR = +5V, OVCCI = OVCCQ = +3.3V, AGND = AGNDI = AGNDQ = AGNDR = 0, OGNDI = OGNDQ = 0, fCLK = 802.816MHz, differential input at -0.5dB FS, CL = 1F to AGND at REF, RL = 100 1% applied to digital LVDS outputs, TA = TMIN to TMAX, unless otherwise noted. Typical values are at TA = +25C) -50 -60 -70 -20 -50 -60 -70 -30 -40 -50 -60 -70 -80 -80 -80 -90 -90 -90 -100 -100 -100 0 20 40 60 80 100 120 140 0 40 80 120 160 0 200 70 140 210 280 350 420 ANALOG INPUT FREQUENCY (MHz) ANALOG INPUT FREQUENCY (MHz) TWO-TONE IMD (8192-POINT RECORD), DIFFERENTIAL INPUT SNR vs. ANALOG INPUT FREQUENCY, DIFFERENTIAL INPUT SINAD vs. ANALOG INPUT FREQUENCY, DIFFERENTIAL INPUT fIN1 -40 fIN2 -50 -60 MAX105 toc05 35 -70 -80 -90 -100 30 -6dB FS 25 -12dB FS 40 80 160 240 320 20 15 25 -12dB FS 20 15 10 10 5 5 400 -6dB FS 30 0 0 0 -1dB FS 35 AMPLITUDE (dB) -30 -1dB FS AMPLITUDE (dB) -20 40 MAX105 toc04 fN1 = 124.166MHz fIN2 = 126.126MHz AIN = -7dB FS -10 10M 1G 100M 10M 10G 100M 1G ANALOG INPUT FREQUENCY (MHz) ANALOG INPUT FREQUENCY (Hz) ANALOG INPUT FREQUENCY (Hz) THD vs. ANALOG INPUT FREQUENCY, DIFFERENTIAL INPUT SFDR vs. ANALOG INPUT FREQUENCY, DIFFERENTIAL INPUT FULL-POWER INPUT BANDWIDTH SINGLE-ENDED INPUT AMPLITUDE (dB) -12dB FS -40 -45 -1dB FS 0 -6dB FS 45 40 -12dB FS 35 30 -1 -2 25 -50 20 -6dB FS -55 1 10G MAX105 toc09 50 -30 -35 -1dB FS GAIN (dB) -25 55 MAX105 toc08 60 MAX105 toc07 -20 MAX105 toc06 ANALOG INPUT FREQUENCY (MHz) 0 -3 15 -60 10 10M 100M 1G ANALOG INPUT FREQUENCY (Hz) 6 -40 fIN = 400.124MHz AIN = -0.5dB FS -10 AMPLITUDE (dB FS) -40 -30 MAX105 toc03 -20 AMPLITUDE (dB FS) AMPLITUDE (dB FS) -30 fIN = 124.999MHz AIN = -0.5dB FS -10 0 MAX105 toc02 fIN = 125.146MHz AIN = -0.5dB FS -20 AMPLITUDE (dB FS) 0 MAX105 toc01 0 -10 8192-POINT FFT, DIFFERENTIAL INPUT 8192-POINT FFT, DIFFERENTIAL INPUT 8192-POINT FFT, DIFFERENTIAL INPUT AMPLITUDE (dB) MAX105 Dual, 6-Bit, 800Msps ADC with On-Chip, Wideband Input Amplifier 10G -4 10M 100M 1G ANALOG INPUT FREQUENCY (Hz) 10G 10M 100M 1G ANALOG INPUT FREQUENCY (Hz) _______________________________________________________________________________________ 10G Dual, 6-Bit, 800Msps ADC with On-Chip, Wideband Input Amplifier 40 fIN = 199.8535MHz 36 -34 MAX105 toc11 fIN = 199.8535MHz fIN = 199.8535MHz -38 32 28 THD (dB) SINAD (dB) 36 32 -46 28 24 -8 -7 -6 -5 -4 -3 -2 -1 -50 24 0 -10 -9 ANALOG INPUT POWER (dB FS) -8 -7 -6 -5 -4 -3 -2 -1 -10 -9 0 SFDR vs. ANALOG INPUT POWER, DIFFERENTIAL INPUT SNR vs. TEMPERATURE 45 MAX105 toc13 50 fIN = 199.8535MHz 48 fIN = 199.8535MHz 41 -8 -7 -6 -5 -4 -3 -2 -1 0 ANALOG INPUT POWER (dB FS) ANALOG INPUT POWER (dB FS) SINAD vs. TEMPERATURE 42 MAX105 toc14 -10 -9 -42 MAX105 toc15 MAX105 toc10 40 SNR (dB) THD vs. ANALOG INPUT POWER, DIFFERENTIAL INPUT SINAD vs. ANALOG INPUT POWER, DIFFERENTIAL INPUT MAX105 toc12 SNR vs. ANALOG INPUT POWER, DIFFERENTIAL INPUT fIN = 199.8535MHz 40 44 SINAD (dB) SNR (dB) SFDR (dB) 46 37 33 38 36 42 29 40 38 25 -8 -7 -6 -5 -4 -3 -2 -1 0 32 -40 -15 10 35 60 85 -15 10 35 60 TEMPERATURE (C) TEMPERATURE (C) THD vs. TEMPERATURE SFDR vs. TEMPERATURE SNR vs. CLOCK FREQUENCY, DIFFERENTIAL INPUT (-1dB FS) fIN = 199.8535MHz fIN = 199.8535MHz SFDR (dB) -46 -50 47 43 10 35 TEMPERATURE (C) 60 85 36 34 30 35 -15 38 32 39 -54 fIN = 202.346MHz AMPLITUDE (dB) 51 -42 40 85 MAX105 toc18 55 MAX toc16 -38 -40 -40 ANALOG INPUT POWER (dB FS) MAX105 toc17 -10 -9 THD (dB) 34 -40 -15 10 35 TEMPERATURE (C) 60 85 400 500 600 700 800 900 CLOCK FREQUENCY (MHz) _______________________________________________________________________________________ 7 MAX105 Typical Operating Characteristics (continued) (AVCC = AVCCI = AVCCQ = AVCCR = +5V, OVCCI = OVCCQ = +3.3V, AGND = AGNDI = AGNDQ = AGNDR = 0, OGNDI = OGNDQ = 0, fCLK = 802.816MHz, differential input at -0.5dB FS, CL = 1F to AGND at REF, RL = 100 1% applied to digital LVDS outputs, TA = TMIN to TMAX, unless otherwise noted. Typical values are at TA = +25C) MAX105 Dual, 6-Bit, 800Msps ADC with On-Chip, Wideband Input Amplifier Typical Operating Characteristics (continued) (AVCC = AVCCI = AVCCQ = AVCCR = +5V, OVCCI = OVCCQ = +3.3V, AGND = AGNDI = AGNDQ = AGNDR = 0, OGNDI = OGNDQ = 0, fCLK = 802.816MHz, differential input at -0.5dB FS, CL = 1F to AGND at REF, RL = 100 1% applied to digital LVDS outputs, TA = TMIN to TMAX, unless otherwise noted. Typical values are at TA = +25C) -43 AMPLITUDE (dB) 38 fIN = 202.346MHz 36 34 32 6.0 fIN = 202.0761MHz 5.9 ENOB (Bits) fIN = 202.346MHz MAX105 toc20 -40 MAX105 toc19 40 -46 -49 5.5 -55 400 500 600 700 800 900 5.7 5.6 -52 30 5.8 400 500 CLOCK FREQUENCY (MHz) 600 700 800 4.5 900 4.7 SFDR vs. ANALOG SUPPLY VOLTAGE, DIFFERENTIAL INPUT (-1dB FS) INL vs. DIGITAL OUTPUT CODE fIN = 202.0761MHz 49 5.1 5.3 5.5 DNL vs. DIGITAL OUTPUT CODE 0.40 MAX105 toc23 0.30 MAX105 toc22 50 4.9 ANALOG SUPPLY VOLTAGE (V) CLOCK FREQUENCY (MHz) 0.20 MAX105 toc24 AMPLITUDE (dB) ENOB vs. ANALOG SUPPLY VOLTAGE, DIFFERENTIAL INPUT (-1dB FS) THD vs. CLOCK FREQUENCY, DIFFERENTIAL INPUT (-1dB FS) MAX105 toc21 SINAD vs. CLOCK FREQUENCY, DIFFERENTIAL INPUT (-1dB FS) 0.20 INL (LSB) 48 47 DNL (LSB) SFDR (dB) 0.10 0 0 -0.10 -0.20 46 -0.20 -0.30 4.7 4.9 5.1 5.3 5.5 -0.40 0 8 16 ANALOG SUPPLY VOLTAGE (V) REFERENCE VOLTAGE vs. ANALOG SUPPLY VOLTAGE 2.502 2.498 2.494 2.490 48 56 64 4.7 4.9 5.1 5.3 ANALOG SUPPLY VOLTAGE (V) 5.5 0 8 16 24 32 40 48 56 DIGITAL OUTPUT CODE DIGITAL OUTPUT CODE ANALOG SUPPLY CURRENT vs. ANALOG SUPPLY VOLTAGE ANALOG SUPPLY CURRENT vs. TEMPERATURE 280 260 240 220 300 64 280 260 240 220 200 200 4.5 8 40 MAX105 toc26 MAX toc25 2.506 32 300 ANALOG SUPPLY CURRENT (mA) REFERENCE VOLTAGE (V) 2.510 24 MAX105 toc27 4.5 ANALOG SUPPLY CURRENT (mA) 45 4.5 4.7 4.9 5.1 5.3 ANALOG SUPPLY VOLTAGE (V) 5.5 -40 -15 10 35 TEMPERATURE (C) _______________________________________________________________________________________ 60 85 Dual, 6-Bit, 800Msps ADC with On-Chip, Wideband Input Amplifier PIN NAME FUNCTION 1, 20 T.P. Test Point. Do not connect. 2 REF Reference Output 3 AVCCR Analog Reference Supply. Supply voltage for the internal bandgap reference. Bypass to AGNDR with 0.01F in parallel with 47pF for proper operation. 4 AGNDR Reference, Analog Ground. Connect to AGND for proper operation. 5, 8 AGNDI I-Channel, Analog Ground. Connect to AGND for proper operation. 6 INI- I-Channel, Differential Input. Negative terminal. 7 INI+ I Channel, Differential Input. Positive terminal. 9 AVCCI I-Channel, Analog Supply. Supplies I-channel common-mode buffer, pre-amplifier and quantizer. Bypass to AGNDI with 0.01F in parallel with 47pF for proper operation. 10 CLK+ Sampling Clock Input 11 CLK- Complementary Sampling Clock Input 12 AVCCQ Q-Channel, Analog Supply. Supplies Q-channel common-mode buffer, pre-amplifier and quantizer. Bypass to AGNDQ with 0.01F in parallel with 47pF for proper operation. 13, 16 AGNDQ Q-Channel, Analog Ground. Connect to AGND for proper operation. 14 INQ+ Q-Channel, Differential Input. Positive terminal. 15 INQ- Q-Channel, Differential Input. Negative terminal. 17, 18 AGND Analog Ground 19 AVCC Analog Supply. Bypass to AGND with 0.01F in parallel with 47pF for proper operation. 21 A5Q+ Auxiliary Output Data Bit 5 (MSB), Q-Channel 22 A5Q- Complementary Auxiliary Output Data Bit 5 (MSB), Q-Channel 23 P5Q+ Primary Output Data Bit 5 (MSB), Q-Channel 24 P5Q- Complementary Primary Output Data Bit 5 (MSB), Q-Channel 25 A4Q+ Auxiliary Output Data Bit 4, Q-Channel 26 A4Q- Complementary Auxiliary Output Data Bit 4, Q-Channel 27 P4Q+ Primary Output Data Bit 4, Q-Channel 28 P4Q- Complementary Primary Output Data Bit 4, Q-Channel 29, 35 OVCCQ Q-Channel Outputs, Digital Supply. Supplies Q-channel output drivers and DOR logic. Bypass to OGND with 0.01F in parallel with 47pF for proper operation. 30, 36 OGNDQ Q-Channel Outputs, Digital Ground. Connect to designated digital ground (OGND) on PC board for proper operation. _______________________________________________________________________________________ 9 MAX105 Pin Description Dual, 6-Bit, 800Msps ADC with On-Chip, Wideband Input Amplifier MAX105 Pin Description (continued) 10 PIN NAME FUNCTION 31 A3Q+ Auxiliary Output Data Bit 3, Q-Channel 32 A3Q- Complementary Auxiliary Output Data Bit 3, Q-Channel 33 P3Q+ Primary Output Data Bit 3, Q-Channel 34 P3Q- Complementary Primary Output Data Bit 3, Q-Channel 37 A2Q+ Auxiliary Output Data Bit 2, Q-Channel 38 A2Q- Complementary Auxiliary Output Data Bit 2, Q-Channel 39 P2Q+ Primary Output Data Bit 2, Q-Channel 40 P2Q- Complementary Primary Output Data Bit 2, Q-Channel 41 A1Q+ Auxiliary Output Data Bit 1, Q-Channel 42 A1Q- Complementary Auxiliary Output Data Bit 1, Q-Channel 43 P1Q+ Primary Output Data Bit 1, Q-Channel 44 P1Q- Complementary Primary Output Data Bit 1, Q-Channel 45 A0Q+ Auxiliary Output Data Bit 0 (LSB), Q-Channel 46 A0Q- Complementary Auxiliary Output Data Bit 0 (LSB), Q-Channel 47 P0Q+ Primary Output Data Bit 0 (LSB), Q-Channel 48 P0Q- Complementary Primary Output Data Bit 0 (LSB), Q-Channel 49 DOR+ Complementary LVDS Out-Of-Range Bit 50 DOR- LVDS Out-of-Range Bit 51 DREADY- Complementary Data-Ready Clock 52 DREADY+ Data Ready Clock 53 P0I- Complementary Primary Output Data Bit 0 (LSB), I-Channel 54 P0I+ Primary Output Data Bit 0 (LSB), I-Channel 55 A0I- Complementary Auxiliary Output Data Bit 0 (LSB), I-Channel 56 A0I+ Auxiliary Output Data Bit 0 (LSB), I-Channel 57 P1I- Complementary Primary Output Data Bit 1, I-Channel 58 P1I+ Primary Output Data Bit 1, I-Channel 59 A1I- Complementary Auxiliary Output Data Bit 1, I-Channel 60 A1I+ Auxiliary Output Data Bit 1, I-Channel 61 P2I- Complementary Primary Output Data Bit 2, I-Channel ______________________________________________________________________________________ Dual, 6-Bit, 800Msps ADC with On-Chip, Wideband Input Amplifier PIN NAME FUNCTION 62 P2I+ Primary Output Data Bit 2, I-Channel 63 A2I- Complementary Auxiliary Output Data Bit 2, I-Channel 64 A2I+ Auxiliary Output Data Bit 2, I-Channel 65, 72 OVCCI I-Channel Outputs, Digital Supply. Supplies I-channel output drivers and DREADY circuit. Bypass to OGND with 0.01F in parallel with 47pF for proper operation. 66, 71 OGNDI I-Channel Outputs, Digital Ground. Connect to designated digital ground (OGND) on PC board for proper operation. 67 P3I- Complementary Primary Output Data Bit 3, I-Channel 68 P3I+ Primary Output Data Bit 3, I-Channel 69 A3I- Complementary Auxiliary Output Data Bit 3, I-Channel 70 A3I+ Auxiliary Output Data Bit 3, I-Channel 73 P4I- Complementary Primary Output Data Bit 4, I-Channel 74 P4I+ Primary Output Data Bit 4, I-Channel 75 A4I- Complementary Auxiliary Output Data Bit 4, I-Channel 76 A4I+ Auxiliary Output Data Bit 4, I-Channel 77 P5I- Complementary Primary Output Data Bit 5, I-Channel 78 P5I+ Primary Output Data Bit 5, I-Channel 79 A5I- Complementary Auxiliary Output Data Bit 5, I-Channel 80 A5I+ Auxiliary Output Data Bit 5, I-Channel Detailed Description The MAX105 is a dual, +5V, 6-bit, 800Msps flash analog-to-digital converter (ADC), designed for highspeed, high-bandwidth I&Q digitizing. Each ADC (Figure 1) employs a fully differential, wide bandwidth input stage, 6-bit quantizers and a unique encoding scheme to limit metastable states to typically one error per 1016 clock cycles, with no error exceeding a maximum of 1LSB. An integrated 6:12 output demultiplexer simplifies interfacing to the part by reducing the output data rate to one-half the sampling clock rate. The MAX105 outputs data in LVDS two's complement format. When clocked at 800Msps, the MAX105 provides a typical signal-to-noise plus distortion (SINAD) of 36.4dB with a 200MHz input tone. The analog input of the MAX105 is designed for differential or single-ended use with a 400mV full-scale input range. In addition, the MAX105 features an on-board +2.5V precision bandgap reference, which is scaled to meet the analog input full-scale range. Principle of Operation The MAX105 employs a flash or parallel architecture. The key to this high-speed flash architecture is the use of an innovative, high-performance comparator design. Each quantizer and downstream logic translates the comparator outputs into 6-bit, parallel codes in two's complement format and passes them on to the internal 6:12 demultiplexer. The demultiplexer enables the ADCs to provide their output data at half the sampling speed on primary and auxiliary ports. LVDS data is available at speeds of up to 400MHz per output port. Input Amplifier Circuits As with all ADCs, if the input waveform is changing rapidly during conversion, effective number of bits (ENOB), signal-to-noise plus distortion (SINAD), and ______________________________________________________________________________________ 11 MAX105 Pin Description (continued) MAX105 Dual, 6-Bit, 800Msps ADC with On-Chip, Wideband Input Amplifier DREADY+/DREADY- MAX105 INI+ I ADC PRE-AMP INI- REF 2k PRIMARY DATA PORT P0I-P5I P0I+/P0I- AUXILIARY DATA PORT A0I-A5I A0I+/A0I- P5I+/P5I- A5I+/A5IAVCC CM BUFFER 10k 1:2 CLK+ REFERENCE CLK10k DOR 2k CM BUFFER REF Q ADC INQ+ PRE-AMP PRIMARY DATA PORT P0Q-P5Q P0Q+/P0Q- AUXILIARY DATA PORT A0Q-A5Q A0Q+/A0Q- P5Q+/P5Q- INQ- REF A5Q+/A5Q- DOR+/DOR- Figure 1. MAX105 Flash Converter Architecture signal-to-noise ratio (SNR) specifications will degrade. The MAX105's on-board, wide-bandwidth input amplifiers (I&Q) reduce this effect significantly, allowing precise digitizing of fast analog data at high conversion rates. The input amplifiers buffer the input signal and allow a full-scale signal input range of 400mV (800mVp-p). OVCCI OVCCI Internal Reference The MAX105 features an integrated, buffered +2.5V precision bandgap reference. This reference is internally scaled to match the analog input range specification of 400mV. The data converter's reference output (REF) can source up to 500A. REF should be buffered, if used to supply external devices. P0I+ - P5I+ A0I+ - A5I+ 55 55 OVCCI P0I- - P5IA0I- - A5I- LVDS Digital Outputs The MAX105 provides data in two's complement format to differential LVDS outputs. A simplified circuit schematic of the LVDS output cells is shown in Figure 2. All LVDS outputs are powered from separate I-channel OVCCI and Q-channel OVCCQ (Q-channel) power supplies, which may be operated at +3.3V 10%. The 12 MAX105 Figure 2. Simplified LVDS Output Model ______________________________________________________________________________________ Dual, 6-Bit, 800Msps ADC with On-Chip, Wideband Input Amplifier IN-PHASE INPUTS (INI+, INQ+) INVERTED INPUTS (INI-, INQ-) OUT-OF-RANGE BIT (DOR+, DOR-) OUTPUT CODE > +400mV + VREF AC - Coupled to AGND_ 1 011111 +400mV - 0.5LSB + VREF AC - Coupled to AGND_ 0 011111 0V + VREF AC - Coupled to AGND_ 0 000000/111111 -400mV + 0.5LSB + VREF AC - Coupled to AGND_ 0 100000 < -400mV + VREF AC - Coupled to AGND_ 1 100000 MAX105 Table 1. Digital Output Codes Corresponding to a DC-Coupled Single-Ended Analog Input Table 2. Digital Output Codes Corresponding to a DC-Coupled Differential Analog Input IN-PHASE INPUTS (INI+, INQ+) INVERTED INPUTS (INI-, INQ-) OUT-OF-RANGE BIT (DOR+, DOR-) OUTPUT CODE >+200mV + VREF <-200mV + VREF 1 011111 +200mV - 0.25LSB + VREF -200mV + 0.25LSB + VREF 0 011111 0V + VREF 0V + VREF 0 000000/111111 -200mV + 0.25LSB + VREF +200mV - 0.25LSB + VREF 0 100000 <-200mV + VREF >+200mV + VREF 1 100000 MAX105 LVDS-outputs provide a typical 270mV voltage swing around a common mode voltage of roughly +1.2V, and must be differentially terminated at the far end of each transmission line pair (true and complementary) with 100. Out-Of-Range Operation A single output pair (DOR+, DOR-) is provided to flag an out-of-range condition, if either the I or Q channel is out-of-range, where out-of-range is above +FS or below -FS. It features the same latency as the ADCs output data and is demultiplexed in a similar fashion. With a 800MHz system clock, DOR+ and DOR- are clocked at up to 400MHz. Applications Information Single-Ended Analog Inputs The MAX105 is designed to work at full-speed for both single-ended and differential analog inputs without significant degradation in its dynamic performance. Both input channels I (INI+, INI-) and Q (INQ+, INQ-) have 2k impedance and allow for AC- and DC-coupled input signals. In a typical DC-coupled single-ended configuration (Table 1), the analog input signals enter the analog input amplifier stages at the in-phase-input pins INI+/INQ+, while the inverted phase input INI/INQ- pins are AC-coupled to AGNDI/AGNDQ. Single- ended operation allows for an input amplitude of 800mVp-p, centered around VREF. Differential Analog Inputs To obtain +FS digital outputs with differential input drive (Table 2), 400mV must be applied between INI+ (INQ+) and INI- (INQ-). Midscale digital output codes occur when there is no voltage difference between INI+ (INQ+) and INI- (INQ-). For a -FS digital output code both in-phase (INI+, INQ+) and inverted input (INI-, INQ-) must see -400mV. Single-Ended to Differential Conversion Using a Balun An RF balun (Figure 3) provides an excellent solution to convert a single-ended signal to a fully differential signal, required by the MAX105 for optimum performance. At higher frequencies, the MAX105 provides better SFDR and THD with fully differential input signals over single-ended input signals. In differential input mode, even-order harmonics are suppressed and each input requires only half the signal-swing compared to singleended mode. Clock Input The MAX105 features clock inputs designed for either single-ended or differential operation with very flexible input drive requirements. The clock inputs (AC- or DCcoupled) provide a 5k input impedance to AVCC/2 ______________________________________________________________________________________ 13 MAX105 Dual, 6-Bit, 800Msps ADC with On-Chip, Wideband Input Amplifier AGND 50 100pF CLK+, INI+, INQ+ D 0 Differential Clock (Sine-Wave Drive) The advantages of differential clock drive (Figure 5) can be obtained by using an appropriate balun or transformer to convert single-ended sine-wave sources into differential drives. Refer to Single-Ended Clock Inputs (Sine-Wave Drive) for proper input amplitude requirements. 0 SIGNAL SOURCE A 50 B 50* 0 180 tude) to +10dBm (2VP-P clock signal amplitude). The MAX105 dynamic performance specifications are determined by a single-ended clock drive of -2dBm (500mVp-p clock signal amplitude). To avoid saturation of the input amplifier stage, limit the clock power level to a maximum of +10dBm. AGND C 100pF CLK-, INI-, INQ- 50 TRANSMISSION LINES AGND 50 50 TO 50-TERMINATED SIGNAL SOURCE OR BALUM AGND 100pF CLK+, INI+, INQ+ 100pF CLK-, INI-, INQ- *TERMINATION OF THE UNUSED INPUT/OUTPUT (WITH 50 TO AGND) ON A BALUN IS RECOMMENDED IN ORDER TO AVOID UNWANTED REFLECTIONS. 50 Figure 3. Single-Ended to Differential Conversion Using a Balun and are internally buffered with a preamplifier to ensure proper operation of the converter even with smallamplitude sine-wave sources. The MAX105 was designed for single-ended, low-phase noise sine wave clock signals with as little as 500mV P-P amplitude (-2dBm). Single-Ended Clock (Sine-Wave Drive) Excellent performance is obtained by AC- or DC-coupling a low-phase noise sine-wave source into a single clock input (Figure 4). Essentially, the dynamic performance of the converter is unaffected by clock-drive power levels from -2dBm (500mVp-p clock signal ampli- AGND Figure 5. Differential AC-Coupled Input Drive (CLK, INI, INQ) LVDS, ECL and PECL Clock The innovative input architecture of the MAX105 clock also allows these inputs to be driven by LVDS-, ECL-, or PECL-compatible input levels, ranging from 500mVp-p to 2Vp-p (Figure 6). 50 TRANSMISSION LINES 100pF SIGNAL SOURCE INPUT 100 100pF AGND 50 100pF FROM SIGNAL SOURCE 100pF CLK+, INI+, INQ+ CLK-, INI-, INQ- AGND Figure 4. Single-Ended Clock Input With AC-Coupled Input Drive (CLK, INI, INQ) 14 CLK-, INI-, INQCLK+, INI+, INQ+ LVDS LINE DRIVER Figure 6. LVDS Input Drive (CLK, INI, INQ) Timing Requirements The MAX105 features a 6:12 demultiplexer, which reduces the output data rate (including DREADY and DOR signals) to one-half of the sample clock rate. The ______________________________________________________________________________________ Dual, 6-Bit, 800Msps ADC with On-Chip, Wideband Input Amplifier MAX105 ADC SAMPLE MAX105 ADCs SAMPLE ON THE RISING EDGE OF CLK+ CLK- N N+1 N+2 N+3 N+4 N+5 N+6 N+7 N+8 N+9 N+10 N+11 N+12 N+13 N+14 N+15 N+16 N+17 N+18 N+19 CLK CLK+ DREADYDREADY DREADY+ AUXILIARY DATA PORT N N+2 N+4 N+6 N+8 N+10 PRIMARY DATA PORT N+1 N+3 N+5 N+7 N+9 N+11 NOTE: THE LATENCY TO THE PRIMARY PORT IS FIVE CLOCK CYCLES, THE LATENCY TO THE AUXILIARY PORT IS SIX CLOCK CYCLES. BOTH PRIMARY AND AUXILIARY DATA PORTS ARE UPDATED ON THE RISING EDGE OF THE DREADY+ CLOCK. tPWH tPWL CLK+ CLKtPD1 DREADY + DREADY tPD2 AUXILIARY PORT DATA PRIMARY PORT DATA MAX105 Figure 7. Output Timing Relationship Between CLK and DREADY Signals and Primary/Auxiliary Output Ports demultiplexed outputs are presented in dual 6-bit two's complement format with two consecutive samples in the primary and auxiliary output ports on the rising edge of the data ready clock. The auxiliary data port always contains the older sample. The primary output always contains the most recent data sample, regardless of the DREADY clock phase. Figure 7 shows the timing and data alignment of the auxiliary and primary output ports in relationship with the CLK and DREADY signals. Data in the primary port is delayed by five clock cycles while data in the auxiliary port is delayed by six clock cycles. Typical I/Q Application Quadrature amplitude modulation (QAM) is frequently used in digital communication systems to increase channel capacity. A QAM signal is modulated in both amplitude and phase. With a demodulator, this QAM signal gets downconverted and separated in its inphase (I) and quadrature (Q) components. Both I&Q channels are digitized by an ADC at the baseband level in order to recover the transmitted information. Figure 8 shows a typical application circuit to directly tune L-band signals to baseband, incorporating a direct conversion tuner (MAX2108) and the MAX105 to digitize I&Q channels with excellent phase- and gainmatching. A front-end L-C filter is required for anti-aliasing purposes. ______________________________________________________________________________________ 15 MAX105 Dual, 6-Bit, 800Msps ADC with On-Chip, Wideband Input Amplifier DREADY+/DREADYFROM PREVIOUS STAGE MAX2108 PRIMARY DATA PORT P0I-P5I QUADRATURE DEMODULATOR NYQUIST FILTER I ADC PRE-AMP AUXILIARY DATA PORT A0I-A5I REF 2k AVCC CM BUFFER 10k 1:2 LO D S P REFERENCE 90 10k DOR 2k NYQUIST FILTER CM BUFFER PRE-AMP PRIMARY DATA PORT P0Q-P5Q REF Q ADC AUXILIARY DATA PORT A0Q-A5Q DOR+/DOR- Figure 8. Typical I/Q Application Grounding, Bypassing, and Board Layout Grounding and power supply decoupling strongly influence the MAX105's performance. At 800MHz clock frequency and 6-bit resolution, unwanted digital crosstalk may couple through the input, reference, power supply, ground connections, and adversely influence the dynamic performance of the ADC. In addition, the I&Q inputs may crosstalk through poorly designed decoupling circuits. Therefore, closely follow the grounding and power-supply decoupling guidelines in Figure 9. Maxim strongly recommends using a multilayer printed circuit board (PC board) with separate ground and power supply planes. Since the MAX105 has separate analog and digital ground connections (AGND, AGNDI, AGNDQ, AGNDR, OGNDI, and OGNDQ, respectively). The PC board should feature separate sections designated to analog (AGND) and digital (OGND), connected at only one point. Digital signals should run above the digital ground plane and analog signals should run above the analog ground plane. Keep digital signals far away from the sensitive analog inputs, reference inputs, 16 and clock inputs. High-speed signals, including clocks, analog inputs, and digital outputs, should be routed on 50 microstrip lines, such as those employed on the MAX105EV kit. The MAX105 has separate analog and digital powersupply inputs: * AV CC = +5V 5%: Power supply for the analog input section of the clock circuit. * AVCCI = +5V 5%: Power supply for the I-channel common-mode buffer, pre-amp and quantizer. * AVCCQ = +5V 5%: Power supply for the Q-channel common-mode buffer, pre-amp and quantizer. * AVCCR = +5V 5%: Power supply for the on-chip bandgap reference. * OVCCI = +3.3V 10%: Power supply for the I-channel output drivers and DREADY circuitry. * OV CC Q = +3.3V 10%: Power supply for the Q-channel output drivers and DOR circuitry. All supplies should be decoupled with large tantalum or electrolytic capacitors at the point they enter the PC board. For best performance, bypass all power sup- ______________________________________________________________________________________ Dual, 6-Bit, 800Msps ADC with On-Chip, Wideband Input Amplifier MAX105 PC BOARD AVCC 10F 10nF PC BOARD AGND FERRITE-BEAD SUPPRESSORS PC BOARD OVCC OVCCI, OVCCQ 10F 10nF 10nF 47pF 4 x 10nF PC BOARD OGND AVCCR OVCCI AVCCR OVCCI 47pF AGNDR 10nF OGNDI AGNDR OGNDI AVCCI AVCCI 10nF MAX105 OVCCI OVCCI 47pF 47pF AGNDI 10nF OGNDI OGNDI AGNDI AVCCQ AVCCQ 10nF OVCCQ 47pF OVCCQ 47pF AGNDQ OGNDQ AVCC OVCCQ 10nF AGNDQ OGNDQ AVCC 10nF 47pF OVCCQ 47pF AGND AGND 10nF OGNDQ OGNDQ NOTE: LOCATE ALL 47pF AND 10nF CAPACITORS, WHICH DECOUPLE AVCCI, AVCCQ, AVCCR, OVCCI, AND OVCCQ AS CLOSE AS POSSIBLE TO THE CHIP. IT IS ALSO RECOMMENDED TO CONNECT ALL ANALOG GROUND CONNECTIONS TO A COMMON ANALOG GROUND PLANE AND ALL DIGITAL GROUND CONNECTIONS TO ONE COMMON DIGITAL GROUND PLANE ON THE PC BOARD. A SIMILAR TECHNIQUE CAN BE USED FOR ALL ANALOG AND DIGITAL POWER SUPPLIES. AVCC = AVCCI = AVCCQ = AVCCR = +5V5% OVCCI = OVCCQ = +3.3V10% Figure 9. MAX105 Decoupling, Bypassing and Grounding plies to the appropriate ground with a 10F tantalum capacitor, to filter power supply noise, in parallel with a 0.1F capacitor. A combination of 0.01F in parallel with high quality 47pF ceramic chip capacitor located very close to the MAX105 device filters high frequency noise. A properly designed PC board (see MAX105EV Kit data sheet) allows the user to connect all analog supplies and all digital supplies together thereby requiring only two separate power sources. Decoupling AV CC, AV CCI, AV CCQ and AV CCR with ferrite-bead suppressors prevents further crosstalk between the individual analog supply pins Thermal Management The MAX105 is designed for a thermally enhanced 80pin TQFP package, providing greater design flexibility, increased thermal efficiency and a low thermal junction-case (jc) resistance of 1.26C/W. In this pack- ______________________________________________________________________________________ 17 MAX105 Dual, 6-Bit, 800Msps ADC with On-Chip, Wideband Input Amplifier DIE 80-PIN TQFP PACKAGE WITH EXPOSED PAD BONDING WIRE EXPOXY THERMAL LAND COPPER PLANE, 1oz. EXPOSED PAD COPPER TRACE, 1oz. PC BOARD COPPER TRACE, 1oz. TOP LAYER GROUND PLANE AGND, DGND POWER PLANE GROUND PLANE (AGND) 6 x 6 ARRAY OF THERMAL VIAS THERMAL LAND COPPER PLANE, 1oz. MAX105 Figure 10. MAX105 Exposed Pad Package Cross-Section age, the data converter die is attached to an exposed pad (EP) leadframe using a thermally conductive epoxy. The package is molded in a way, that this leadframe is exposed at the surface, facing the printed circuit board (PC board) side of the package (Figure 10). This allows the package to be attached to the PC board with standard infrared (IR) flow soldering techniques. A specially created land pattern on the PC board, matching the size of the EP (7.5mm x 7.5mm) does not only guarantee proper attachment of the chip, but can also be used for heat-sinking purposes. Designing thermal vias* into the land area and implementing large ground planes in the PC board design, further enhance the thermal conductivity between board and package. To remove heat from an 80-pin TQFP package efficiently, an array of 6 x 6 vias ( 0.3mm diameter per via hole and 1.2mm pitch between via holes) is required. Note: Efficient thermal management for the MAX105 is strongly depending on PC board and circuit design, component placement, and installation. Therefore, exact performance figures cannot be provided. However, the MAX105EV kit exhibits a typical ja of 18C/W. For more information on proper design techniques and recommendations to enhance the thermal performance of parts such as the MAX105, please refer to Amkor Technology's website at www.amkor.com. *Connects the land pattern to internal or external copper planes. 18 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 is drawn between the endpoints of the transfer function, once offset and gain errors have been nullified. The static linearity parameters for the MAX105 are measured using the sine-histogram 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 greater than -1LSB guarantees no missing codes and a monotonic transfer function. Dynamic Parameter Definitions Aperture Jitter and Delay Aperture uncertainties affect the dynamic performance of high-speed converters. Aperture jitter, in particular, directly influences SNR and limits the maximum slew rate (dV/dt) that can be digitized without significant error. Aperture jitter limits the SNR performance of the ADC, according to the following relationship: SNRdB = 20 x log10 [1 / (2 x x fIN x tAJ[RMS])], where fIN represents the analog input frequency and tAJ is the RMS aperture jitter. The MAX105's innovative ______________________________________________________________________________________ Dual, 6-Bit, 800Msps ADC with On-Chip, Wideband Input Amplifier CLK+ tAW MAX105 ANALOG INPUT THD = 20 x log (V22 + V32 + V4 2 + V52 ) / V12 ) tAD tAJ SAMPLING INSTANT tAW: APERTURE WIDTH tAJ: APERTURE JITTER tAD: APERTURE DELAY Figure 11. Aperture Timing clock design limits aperture jitter to typically 1.5psRMS. Figure 11 depicts the aperture jitter (tAJ), which is the sample-to-sample variation in the 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 11). 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): where V1 is the fundamental amplitude, and V2 through V5 are the amplitudes of the 2nd- through 5th-order harmonics. Spurious-Free Dynamic Range (SFDR) SFDR is the ratio expressed in decibels of the RMS amplitude of the fundamental to the RMS value of the next largest spurious component, excluding DC offset. Two-Tone Intermodulation Distortion (IMD) The two-tone IMD is the ratio expressed in decibels of either input tone to the worst 3rd-order (or higher) intermodulation products. The individual input tone levels are at -7dB full-scale and their envelope peaks at -1dB full-scale. Chip Information TRANSISTOR COUNT: 12,286 SNRMAX[dB] = 6.02dB x N + 1.76dB In reality, there are other noise sources besides quantization noise: thermal noise, reference noise, clock jitter (see Aperture Uncertainties). SNR is computed by taking the ratio of the RMS signal to the RMS noise, which includes all spectral components minus the fundamental, the first four harmonics, and the DC offset. Signal-to-Noise Plus Distortion (SINAD) SINAD is computed by taking the ratio of the RMS signal to all spectral components minus the fundamental and the DC offset. Effective Number of Bits (ENOB) ENOB specifies the dynamic performance of an ADC at a specific input frequency, amplitude, and sampling rate relative to an ideal ADC's quantization noise. For a full-scale input ENOB is computed from: ENOB = (SINAD - 1.76dB) / 6.02dB ______________________________________________________________________________________ 19 MAX105 Total Harmonic Distortion (THD) THD is typically the ratio of the RMS sum of the first four harmonics of the input signal to the fundamental itself. This is expressed as: CLK- Dual, 6-Bit, 800Msps ADC with On-Chip, Wideband Input Amplifier 20 61 P2I- 62 P2I+ 63 A2I- 64 A2I+ 65 OVCCI 66 OGNDI 67 P3I- 68 P3I+ 69 A3I- 70 A3I+ 71 OGNDI 72 OVCCI 73 P4I- 74 P4I+ 75 A4I- 76 A4I+ 77 P5I- 78 P5I+ 79 A5I- 80 A5I+ MAX105 Pin Configuration T.P. 1 60 A1I+ REF 2 59 A1I- AVCCR 3 58 P1I+ AGNDR 4 57 P1I- AGNDI 5 56 A0I+ INI- 6 55 A0I- INI+ 7 54 P01+ AGNDI 8 53 P01- AVCCI 9 52 DREADY+ CLK+ 10 51 DREADY- CLK- 11 50 DOR- AVCCQ 12 49 DOR+ AGNDQ 13 48 P0Q- INQ+ 14 47 P0Q+ INQ- 15 46 A0Q- AGNDQ 16 45 A0Q+ AGND 17 44 P1Q- AGND 18 43 P1Q+ AVCC 19 42 A1Q- T.P. 20 41 A1Q+ 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 A5Q+ A5Q- P5Q+ P5Q- A4Q+ A4Q- P4Q+ P4Q- OVCCQ OGNDQ A3Q+ A3Q- P3Q+ P3Q- OVCCQ OGNDQ A2Q+ A2Q- P2Q+ P2Q- MAX105 ______________________________________________________________________________________ Dual, 6-Bit, 800Msps ADC with On-Chip, Wideband Input Amplifier 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. Maxim Integrated Products, 120 San Gabriel Drive, Sunnyvale, CA 94086 408-737-7600 ____________________ 21 (c) 2001 Maxim Integrated Products Printed USA is a registered trademark of Maxim Integrated Products. MAX105 Package Information