PRELIMINARY Data Sheet A m p l i fy t h e H u m a n E x p e r i e n c e CDK8307 FEATURES n 20/40/50/65MSPS maximum sampling rate n Low Power Dissipation – 22mW/channel at 20MSPS – 34mW/channel at 40MSPS – 40mW/channel at 50MSPS – 50mW/channel at 65MSPS n 72.2dB SNR at 8MHz FIN n 0.5μs startup time from Sleep n 15μs startup time from Power Down n Internal reference circuitry requires no external components n Internal offset correction n Reduced power dissipation modes available – 32mW/channel at 50MSPS – 71.5dB SNR at 8MHz FIN n Coarse and fine gain control n 1.8V supply voltage n Serial LVDS output General Description The CDK8307 is a high performance low power octal analog-to-digital converter (ADC). The ADC employs internal reference circuitry, a serial control interface and serial LVDS output data, and is based on a proprietary structure. An integrated PLL multiplies the input sampling clock by a factor of 12 or 14, according to the LVDS output setting. The multiplied clock is used for data serialization and data output. Data and frame synchronization output clocks are supplied for data capture at the receiver. Various modes and configuration settings can be applied to the ADC through the serial control interface (SPI). Each channel can be powered down independently and data format can be selected through this interface. A full chip idle mode can be set by a single external pin. Register settings determines the exact function of this external pin. The CDK8307 is designed to easily interface with field-programmable gate arrays (FPGAs) from several vendors. The very low startup times of the CDK8307 allow significant power reduction in duty-cycled systems, by utilizing the Sleep Mode or Power Down Mode when the receive path is idle. – 12- and 14-bit output available Block Diagram n Medical Imaging n Wireless Infrastructure n Test and Measurement IP1 n Instrumentation IN1 IP2 IN2 ©2009 CADEKA Microcircuits LLC Clock Input PLL LVDS FCLKP FCLKN LCLKP LCLKN ADC Digital Gain LVDS D1N D1P ADC Digital Gain LVDS D2N D2P • • • • • • • • • ADC Digital Gain LVDS D8N D8P www.cadeka.com Rev 0.4.0 IP8 IN8 Serial Control Interface AVDD AVSS DVDD DVSS APPLICATIONS PD – QFN-64 CLKP CLKN RESETN – TQFP-80 SCLK SDATA Package alternatives CSN n CDK8307 12/13-bit, 20/40/50/65MSPS, Eight Channel, Ultra Low Power ADC with LVDS 12/13-bit, 20/40/50/65MSPS, Eight Channel, Ultra Low Power ADC with LVDS PRELIMINARY Data Sheet Table of Contents Features................................................................... 1 Table 6. LVDS Output Drive Strength for Applications............................................................. 1 General Description................................................. 1 Table 7. LVDS Internal Termination Block Diagram......................................................... 1 Table of Contents.................................................... 2 Table 8. Bit Clock Internal Termination..................... 19 Ordering Information.............................................. 3 Table 9. Analog Input Invert.................................... 19 Pin Configurations................................................... 4 Table 10. LVDS Test Patterns................................... 20 Pin Assignments................................................... 5-8 Table 11. Programmable Gain.................................. 20 Absolute Maximum Ratings.................................... 9 Table 12. Gain Setting for Channels 1-8................... 21 Reliability Information............................................ 9 Table 13. LVDS Clock Programmability and ESD Protection......................................................... 9 Data Output Modes.................................. 21 Electrical Characteristics....................................... 10 Electrical Characteristics – CDK8307A................. 10 Electrical Characteristics – CDK8307B................. 11 Electrical Characteristics – CDK8307C................. 11 Electrical Characteristics – CDK8307C (Continued)........................................................... 12 Electrical Characteristics – CDK8307D................. 12 Digital and Timing Electrical Characteristics....... 13 LVDS Timing Diagrams.......................................... 14 Figure 1. 12-bit Output, DDR Mode.......................... 14 Figure 2. 14-bit Output, DDR Mode.......................... 14 Figure 3. 12-bit Output, SDR Mode.......................... 14 Figure 4. Data Timing............................................. 14 Serial Interface...................................................... 15 Timing Diagram..................................................... 15 Figure 5. Serial Port Interface Timing Diagram...... 15 Programmability........................................ 19 Figure 6. Phase Programmability Modes for LCLK...... 22 Figure 7. SDR Interface Modes................................ 22 Table 14. Number of Serial Output Bits.................... 22 Table 15. Full Scale Control..................................... 23 Table 16. Register Values with Corresponding Charge in Full-Scale Range....................... 23 Table 17. Clock Frequency....................................... 23 Table 18. Clock Frequency Settings.......................... 23 Table 19. Performance Control................................ 24 Table 20. Performance Control Settings.................... 24 Table 21. External Common Mode Voltage Buffer Driving Strength............................ 24 Theory of Operation.............................................. 25 Recommended Usage............................................ 25 Analog Input.......................................................... 25 Figure 8. Input Configuration Diagram................. 25 DC-Coupling........................................................... 25 Figure 9. DC-Coupled Input................................. 25 AC-Coupling........................................................... 26 Register Initialization.............................................. 15 Figure 10. Transformer Coupled Input.................. 26 Serial Register Map...........................................16-17 Figure 11. AC-Coupled Input............................... 26 Table 2. Summary of Functions Supported Figure 12. Alternative Input Network.................... 26 by Serial Interface.................................16-17 Clock Input and Jitter Considerations....................... 27 Description of Serial Registers.........................17-24 Mechanical Dimensions . ..................................28-29 Table 3. Software Reset.......................................... 17 QFN-64 Package.................................................... 28 Table 4. Power-Down Modes................................... 17 TQFP-80 Package................................................... 29 Table 5. LVDS Drive Strength Programmability.......... 18 ©2009 CADEKA Microcircuits LLC www.cadeka.com 2 Rev 0.4.0 Table 1. Serial Port Interface Timing Definitions.... 15 CDK8307 12/13-bit, 20/40/50/65MSPS, Eight Channel, Ultra Low Power ADC with LVDS Recommended Operating Conditions..................... 9 LCLK, FCLK, and Data................................ 18 PRELIMINARY Data Sheet Ordering Information Speed Package Pb-Free RoHS Compliant Operating Temperature Range Packaging Method CDK8307AITQ80* 20MSPS TQFP-80 Yes Yes -40°C to +85°C Tray CDK8307AILP64* 20MSPS QFN-64 Yes Yes -40°C to +85°C Tray CDK8307AILP64B2** 20MSPS QFN-64 Yes Yes -40°C to +85°C Tray CDK8307BITQ80* 40MSPS TQFP-80 Yes Yes -40°C to +85°C Tray CDK8307BILP64* 40MSPS QFN-64 Yes Yes -40°C to +85°C Tray CDK8307BILP64B2** 40MSPS QFN-64 Yes Yes -40°C to +85°C Tray CDK8307CITQ80* 50MSPS TQFP-80 Yes Yes -40°C to +85°C Tray CDK8307CILP64* 50MSPS QFN-64 Yes Yes -40°C to +85°C Tray CDK8307CILP64B2** 50MSPS QFN-64 Yes Yes -40°C to +85°C Tray CDK8307DITQ80* 65MSPS TQFP-80 Yes Yes -40°C to +85°C Tray CDK8307DILP64* 65MSPS QFN-64 Yes Yes -40°C to +85°C Tray CDK8307DILP64B2** 65MSPS QFN-64 Yes Yes -40°C to +85°C Tray CDK8307 12/13-bit, 20/40/50/65MSPS, Eight Channel, Ultra Low Power ADC with LVDS Part Number Moisture sensitivity level for all parts is MSL-3. *Preliminary. **Preliminary, pinout matches AD9222. Rev 0.4.0 ©2009 CADEKA Microcircuits LLC www.cadeka.com 3 PRELIMINARY Data Sheet Pin Configurations NC VCM NC NC IP8 IN8 AVDD IN7 IP7 55 54 53 52 51 50 49 AVDD 49 56 AVDD 50 NC NC 51 57 AVSS 52 AVDD VCM 53 58 NC 54 IP1 NC 55 59 NC 56 IN1 AVDD 57 60 CLKP 58 ACDD CLKN 59 61 OVDD 60 IN2 CSN 61 62 SDATA 62 IP2 SCLK 63 63 RESETN 64 IP1 1 48 IN8 AVDD 1 48 AVDD IN1 2 47 IP8 IP3 2 47 IP6 AVSS 3 46 AVSS IN3 3 46 IN6 IP2 4 45 IN7 AVDD 4 45 AVDD IN2 5 44 IP7 IN4 5 44 IN5 AVSS 6 43 AVSS IP4 6 43 IP5 IP3 7 42 IN6 AVDD 7 42 AVDD IN3 8 41 IP6 AVDD 8 41 PD AVSS 9 40 AVSS CLKN 9 40 CSN IP4 10 39 IN5 CLKP 10 39 SDATA IN4 11 38 IP5 AVDD 11 38 SCLK DVSS 12 37 AVSS AVDD 12 37 AVDD PD 13 36 DVSS DVSS 13 36 DCVSS DVSS 14 35 DVDD DVDD 14 35 DVDD D1P 15 34 D8N D4N 15 34 D5P D1N 16 33 D8P D4P 16 33 D5N NC AVDD NC AVSS 64 63 62 61 26 27 28 29 30 31 32 FCLKP D8N D8P D7N D7P D6N D6P 25 VCM 65 FCLKN NC 66 24 NC 67 LCLKP AVSS 68 23 NC 69 LCLKN AVDD 70 22 CLKP 71 D1P 21 CLKN 72 D1N 20 AVSS 73 D2P 19 AVSS 74 D2N 18 17 OVDD 75 D3P CSN 76 32 D7N SDATA 77 31 D7P SCLK 78 30 D6N AVSS 79 29 D6P AVDD 1 60 AVDD IP1 2 59 IN8 IN1 3 58 IP8 AVSS 4 57 AVSS IP2 5 56 IN7 IN2 6 55 IP7 AVDD 7 54 AVDD AVSS 8 53 AVSS IP3 9 52 IN6 IN3 10 51 IP6 AVSS 11 50 AVSS IP4 12 49 IN5 IN4 13 48 IP5 AVDD 14 47 AVDD DVSS 15 46 DVSS PD 16 45 RESETN DVSS 17 44 DVSS DVSS 18 43 DVSS LCLKP 19 42 FCLKN LCLKN 20 41 FCLKP CDK8307 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 D1P D1N D2P D2N DVDD DVSS D3P D3N D4P D4N D5P D5N D6P D6N DVDD DVSS D7P D7N D8P D8N TQFP-80 Rev 0.4.0 ©2009 CADEKA Microcircuits LLC AVSS 28 D5N TQFP-80 QFN-64 80 27 D5P 23 FCLKP 26 22 D4N LCLKN 21 D4P 25 20 D3N LCLKP 19 D3P 24 18 FCLKN 17 D2P D2N QFN-64 CDK8307 D3N CDK8307 CDK8307 12/13-bit, 20/40/50/65MSPS, Eight Channel, Ultra Low Power ADC with LVDS 64 QFN-64 (B2 Version: AD9222 Pinout Option) QFN-64 www.cadeka.com 4 PRELIMINARY Data Sheet Pin Assignments Pin No. Pin Name Description 49, 50, 57 AVDD Analog power supply, 1.8V 3, 6, 9, 37, 40, 43, 46, 52 AVSS Analog ground 1 IP1 Positive differential input signal, channel 1 2 IN1 Negative differential input signal, channel 1 4 IP2 Positive differential input signal, channel 2 QFN-64 IN2 Negative differential input signal, channel 2 IP3 Positive differential input signal, channel 3 8 IN3 Negative differential input signal, channel 3 10 IP4 Positive differential input signal, channel 4 11 IN4 Negative differential input signal, channel 4 38 IP5 Positive differential input signal, channel 5 39 IN5 Negative differential input signal, channel 5 41 IP6 Positive differential input signal, channel 6 42 IN6 Negative differential input signal, channel 6 44 IP7 Positive differential input signal, channel 7 45 IN7 Negative differential input signal, channel 7 47 IP8 Positive differential input signal, channel 8 48 IN8 Negative differential input signal, channel 8 12, 14, 36 DVSS Digital ground Digital and I/O power supply, 1.8V 35 DVDD 13 PD Power-down input 15 D1P LVDS channel 1, positive output 16 D1N LVDS channel 1, negative output 17 D2P LVDS channel 2, positive output 18 D2N LVDS channel 2, negative output 19 D3P LVDS channel 3, positive output 20 D3N LVDS channel 3, negative output 21 D4P LVDS channel 4, positive output 22 D4N LVDS channel 4, negative output 27 D5P LVDS channel 5, positive output 28 D5N LVDS channel 5, negative output 29 D6P LVDS channel 6, positive output 30 D6N LVDS channel 6, negative output 31 D7P LVDS channel 7, positive output 32 D7N LVDS channel 7, negative output 33 D8P LVDS channel 8, positive output 34 D8N LVDS channel 8, negative output FCLKP LVDS frame clock (1x), positive output FCLKN LVDS frame clock (1x), negative output 25 LCLKP LVDS bit clock, positive output 26 LCLKN LVDS bit clock, negative output ©2009 CADEKA Microcircuits LLC Rev 0.4.0 23 24 CDK8307 12/13-bit, 20/40/50/65MSPS, Eight Channel, Ultra Low Power ADC with LVDS 5 7 www.cadeka.com 5 PRELIMINARY Data Sheet Pin Assignments (Continued) Pin No. Pin Name Description NC 53 VCM Not connected Common mode output pin, 0.5 AVDD 58 CLKP Positive differential input clock 59 CLKN Negative differential input clock. 60 OVDD 61 CSN 62 SDATA Serial data input 63 SCLK Serial clock input 64 RESETN CDK8307 12/13-bit, 20/40/50/65MSPS, Eight Channel, Ultra Low Power ADC with LVDS 51, 54, 55, 56 Digital CMOS inputs supply voltage (1.7V to 3.6V) Chip select enable. Active low. Reset SPI interface QFN-64 (B2 version: AD9222 pinout option) 1, 4, 7, 8, 11, 12, 37, 42, 45, 48, 51, 59, 62 AVDD Analog power supply, 1.8V Analog ground (Exposed paddle, Pin 0, bottom of package) AVSS IP1 Positive differential input signal, channel 1 61 IN1 Negative differential input signal, channel 1 64 IP2 Positive differential input signal, channel 2 63 IN2 Negative differential input signal, channel 2 2 IP3 Positive differential input signal, channel 3 3 IN3 Negative differential input signal, channel 3 6 IP4 Positive differential input signal, channel 4 5 IN4 Negative differential input signal, channel 4 43 IP5 Positive differential input signal, channel 5 44 IN5 Negative differential input signal, channel 5 47 IP6 Positive differential input signal, channel 6 46 IN6 Negative differential input signal, channel 6 49 IP7 Positive differential input signal, channel 7 50 IN7 Negative differential input signal, channel 7 53 IP8 Positive differential input signal, channel 8 52 IN8 Negative differential input signal, channel 8 13, 36 DVSS Digital ground 14, 35 DVDD Digital and I/O power supply, 1.8V 41 PD Power-down input 22 D1P LVDS channel 1, positive output 21 D1N LVDS channel 1, negative output 20 D2P LVDS channel 2, positive output 19 D2N LVDS channel 2, negative output 18 D3P LVDS channel 3, positive output 17 D3N LVDS channel 3, negative output 16 D4P LVDS channel 4, positive output 15 D4N LVDS channel 4, negative output 34 D5P LVDS channel 5, positive output 33 D5N LVDS channel 5, negative output ©2009 CADEKA Microcircuits LLC Rev 0.4.0 0 60 www.cadeka.com 6 PRELIMINARY Data Sheet Pin Assignments (Continued) Pin No. Pin Name Description D6P LVDS channel 6, positive output D6N LVDS channel 6, negative output 30 D7P LVDS channel 7, positive output 29 D7N LVDS channel 7, negative output 28 D8P LVDS channel 8, positive output 27 D8N LVDS channel 8, negative output 26 FCLKP LVDS frame clock (1X), positive output 25 FCLKN LVDS frame clock (1X), negative output 24 LCKP LVDS bit clock, positive output 23 LCKN LVDS bit clock, negative output 54 NC Not connected Not connected 55 NC 56 VCM 57 NC Not connected Not connected CDK8307 12/13-bit, 20/40/50/65MSPS, Eight Channel, Ultra Low Power ADC with LVDS 32 31 Common mode output pin, 0.5*AVDD 58 NC 10 CLKP Positive differential input clock 9 CLKN Negative differential input clock. 40 CSN Chip select enable. Active Low 39 SDATA Serial data input 38 SCLK Serial clock input 1, 7, 14, 47, 54, 60, 63, 70 AVDD Analog power supply, 1.8V 4, 8, 11, 50, 53, 57, 61, 68, 73, 74, 79, 80 AVSS Analog ground TQFP 2 IP1 Positive differential input signal, channel 1 3 IN1 Negative differential input signal, channel 1 5 IP2 Positive differential input signal, channel 2 IN2 Negative differential input signal, channel 2 IP3 Positive differential input signal, channel 3 10 IN3 Negative differential input signal, channel 3 12 IP4 Positive differential input signal, channel 4 13 IN4 Negative differential input signal, channel 4 48 IP5 Positive differential input signal, channel 5 49 IN5 Negative differential input signal, channel 5 51 IP6 Positive differential input signal, channel 6 52 IN6 Negative differential input signal, channel 6 55 IP7 Positive differential input signal, channel 7 56 IN7 Negative differential input signal, channel 7 58 IP8 Positive differential input signal, channel 8 59 IN8 Negative differential input signal, channel 8 15, 17, 18, 26, 36, 43, 44, 46 DVSS Digital ground 25, 35 DVDD Digital and I/O power supply, 1.8V ©2009 CADEKA Microcircuits LLC Rev 0.4.0 6 9 www.cadeka.com 7 PRELIMINARY Data Sheet Pin Assignments (Continued) Pin No. Pin Name Description PD 19 LCKP Power-down input LVDS bit clock, positive output 20 LCKN LVDS bit clock, negative output 21 D1P LVDS channel 1, positive output 22 D1N LVDS channel 1, negative output 23 D2P LVDS channel 2, positive output 24 D2N LVDS channel 2, negative output 27 D3P LVDS channel 3, positive output 28 D3N LVDS channel 3, negative output 29 D4P LVDS channel 4, positive output 30 D4N LVDS channel 4, negative output 31 D5P LVDS channel 5, positive output 32 D5N LVDS channel 5, negative output 33 D6P LVDS channel 6, positive output 34 D6N LVDS channel 6, negative output 37 D7P LVDS channel 7, positive output 38 D7N LVDS channel 7, negative output 39 D8P LVDS channel 8, positive output 40 D8N LVDS channel 8, negative output 41 FCLKP LVDS frame clock (1x), positive output 42 FCLKN LVDS frame clock (1x), negative output 45 RESETN 62, 64, 66, 67, 69 NC 65 VCM Common mode output pin, 0.5 AVDD 71 CLKP Positive differential input clock 72 CLKN Negative differential input clock. 75 OVDD Digital CMOS inputs supply voltage (1.7V to 3.6V) 76 CSN 77 SDATA Serial data input 78 SCLK Serial clock input CDK8307 12/13-bit, 20/40/50/65MSPS, Eight Channel, Ultra Low Power ADC with LVDS 16 Reset SPI interface Not connected Chip select enable. Active low. Rev 0.4.0 ©2009 CADEKA Microcircuits LLC www.cadeka.com 8 PRELIMINARY Data Sheet Absolute Maximum Ratings The safety of the device is not guaranteed when it is operated above the “Absolute Maximum Ratings”. The device should not be operated at these “absolute” limits. Adhere to the “Recommended Operating Conditions” for proper device function. The information contained in the Electrical Characteristics tables and Typical Performance plots reflect the operating conditions noted on the tables and plots. Reference Pin Min Max Unit AVDD DVDD OVDD AVSS, DVSS Analog inputs and outpts (IPx, INx) CLKx LVDS outputs Digital inputs AVSS DVSS AVSS DVSS / AVSS AVSS AVSS DVSS DVSS -0.3 -0.3 -0.3 -0.3 -0.3 -0.3 -0.3 -0.3 +2.3 +2.3 +3.9 +0.3 +2.3 +2.3 +2.3 +3.9 V V V V V V V V Max Unit TBD +150 °C °C Reliability Information Parameter Min Junction Temperature Storage Temperature Range Lead Temperature (Soldering, 10s) Typ -60 J-STD-020 ESD Protection Product Human Body Model (HBM) Charged Device Model (CDM) QFN-64 TQFP-80 TBD TBD TBD TBD Recommended Operating Conditions Parameter Min Operating Temperature Range -40 Typ Max Unit +85 °C This device can be damaged by ESD. Even though this product is protected with state-of-the-art ESD protection circuitry, damage may occur if the device is not handled with appropriate precautions. ESD damage may range from device failure to performance degradation. Analog circuitry may be more susceptible to damage as vary small parametric changes can result in specification noncompliance. CDK8307 12/13-bit, 20/40/50/65MSPS, Eight Channel, Ultra Low Power ADC with LVDS Parameter Rev 0.4.0 ©2009 CADEKA Microcircuits LLC www.cadeka.com 9 PRELIMINARY Data Sheet Electrical Characteristics (AVDD = 1.8V, DVDD = 1.8V, OVDD = 1.8V, 50MSPS clock, 50% clock duty cycle, -1dBFS 8MHz input signal, 14-bit output, unless otherwise noted) Symbol Parameter Conditions Min Typ Max Units -6 6 %FS -0.5 0.5 %FS DC Accuracy No Missing Codes Offset error after digital offset cancellation Gain Error Gain Matching Gain matching between channels. ±3sigma value at worst case conditions. 1 LSB DNL Differential Non-Linearity 12-bit level ±0.2 LSB INL Integral Non-Linearity 12-bit level ±0.6 LSB VCMO Common Mode Voltage Output VAVDD/2 V Analog Input VCMI VFSR Input Common Mode Analog input common mode voltage Full Scale Range Differential input voltage range Input Capacitance Differential input capacitance Bandwidth Input bandwidth VCM -0.1 VCM +0.2 2.0 V Vpp 2 pF 500 MHz Power Supply AVDD Analog Supply Voltage DVDD Digital Supply Voltage OVDD Digital CMOS Input Supply Voltage Digital and output driver supply voltage 1.7 1.8 2.0 V 1.7 1.8 2.0 V 1.7 1.8 3.6 V Electrical Characteristics - CDK8307A (AVDD = 1.8V, DVDD = 1.8V, OVDD = 1.8V, 20MSPS clock, 50% clock duty cycle, -1dBFS 8MHz input signal, 14-bit output, unless otherwise noted) Symbol Parameter Conditions Min Typ Max Units Performance SNR Signal to Noise Ratio FIN = 8MHz 72.2 dBFS SINAD Signal to Noise and Distortion Ratio FIN = 8MHz 71.5 dBFS SFDR Spurious Free Dynamic Range FIN = 8MHz 82 dBc HD2 Second order Harmonic Distortion FIN = 8MHz 95 dBc HD3 Third order Harmonic Distortion FIN = 8MHz 82 dBc ENOB Effective number of Bits 11.6 bits Signal applied to 7 channels (FIN0). Measurement taken on one channel with full scale at FIN1. FIN1 = 8MHz, FIN0 = 9.9MHz 95 dBc 47 mA Digital and output driver supply 50 mA Analog power Dissipation 85 mW Digital power Dissipation 90 mW Total power Dissipation 175 mW Power Down Dissipation 10 µW Crosstalk Power Supply Analog supply current Digital supply current 43 mW Sleep Channel Mode Dissipation Power dissipation with all chs in sleep mode 44 mW Sleep Channel Mode Savings Power dissipation savings per channel off 16 mW Sleep Mode Dissipation Maximum Conversion Rate Minimum Conversion Rate ©2009 CADEKA Microcircuits LLC 20 MSPS 15 MSPS www.cadeka.com 10 Rev 0.4.0 Clock Inputs CDK8307 12/13-bit, 20/40/50/65MSPS, Eight Channel, Ultra Low Power ADC with LVDS Offset Error Guaranteed PRELIMINARY Data Sheet Electrical Characteristics - CDK8307B (AVDD = 1.8V, DVDD = 1.8V, OVDD = 1.8V, 40MSPS clock, 50% clock duty cycle, -1dBFS 8MHz input signal, 14-bit output, unless otherwise noted) Symbol Parameter Conditions Min Typ Max Units Performance Signal to Noise Ratio FIN = 8MHz 72.2 dBFS SINAD Signal to Noise and Distortion Ratio FIN = 8MHz 71.5 dBFS SFDR Spurious Free Dynamic Range FIN = 8MHz 82 dBc HD2 Second order Harmonic Distortion FIN = 8MHz 95 dBc HD3 Third order Harmonic Distortion FIN = 8MHz ENOB Effective number of Bits Signal applied to 7 channels (FIN0). Measurement taken on one channel with full scale at FIN1. FIN1 = 8MHz, FIN0 = 9.9MHz Crosstalk 82 dBc 11.6 bits 95 dBc 91 mA Power Supply Analog supply current 60 mA Analog power Dissipation 164 mW Digital power Dissipation 108 mW Total power Dissipation 272 mW Power Down Dissipation 10 µW Sleep Mode Dissipation 67 mW Digital supply current Digital and output driver supply Sleep Channel Mode Dissipation Power dissipation with all chs in sleep mode 72 mW Sleep Channel Mode Savings Power dissipation savings per channel off 23 mW Clock Inputs 40 Maximum Conversion Rate MSPS 20 Minimum Conversion Rate MSPS Electrical Characteristics - CDK8307C (AVDD = 1.8V, DVDD = 1.8V, OVDD = 1.8V, 50MSPS clock, 50% clock duty cycle, -1dBFS 8MHz input signal, 14-bit output, unless otherwise noted) Symbol Parameter Conditions Min Typ Max Units Performance SNR Signal to Noise Ratio FIN = 8MHz 72.2 dBFS SINAD Signal to Noise and Distortion Ratio FIN = 8MHz 71.5 dBFS SFDR Spurious Free Dynamic Range FIN = 8MHz 82 dBc HD2 Second order Harmonic Distortion FIN = 8MHz 95 dBc HD3 Third order Harmonic Distortion FIN = 8MHz ENOB Effective number of Bits Signal applied to 7 channels (FIN0). Measurement taken on one channel with full scale at FIN1. FIN1 = 8MHz, FIN0 = 9.9MHz Crosstalk 82 dBc 11.6 bits 95 dBc 112 mA Power Supply Analog supply current mA Analog power Dissipation 202 mW Digital power Dissipation 119 mW Total power Dissipation 321 mW Power Down Dissipation 10 µW Sleep Mode Dissipation 78 mW ©2009 CADEKA Microcircuits LLC Digital and output driver supply www.cadeka.com 11 Rev 0.4.0 66 Digital supply current CDK8307 12/13-bit, 20/40/50/65MSPS, Eight Channel, Ultra Low Power ADC with LVDS SNR PRELIMINARY Data Sheet Electrical Characteristics - CDK8307C Continued Symbol Parameter Conditions Min Typ Max Units Sleep Channel Mode Dissipation Power dissipation with all chs in sleep mode 80 mW Sleep Channel Mode Savings Power dissipation savings per channel off 28 mW Clock Inputs MSPS 20 Minimum Conversion Rate MSPS Electrical Characteristics - CDK8307D (AVDD = 1.8V, DVDD = 1.8V, OVDD = 1.8V, 65MSPS clock, 50% clock duty cycle, -1dBFS 8MHz input signal, 14-bit output, unless otherwise noted) Symbol Parameter Conditions Min Typ Max Units Performance SNR Signal to Noise Ratio FIN = 8MHz 72.2 dBFS SINAD Signal to Noise and Distortion Ratio FIN = 8MHz 71.5 dBFS SFDR Spurious Free Dynamic Range FIN = 8MHz 82 dBc HD2 Second order Harmonic Distortion FIN = 8MHz 95 dBc HD3 Third order Harmonic Distortion FIN = 8MHz ENOB Effective number of Bits Signal applied to 7 chs (FIN0). Measurement taken on one ch, full scale at FIN1. FIN1 = 8MHz, FIN0 = 9.9MHz Crosstalk 82 dBc 11.6 bits 95 dBc Power Supply 145 mA 67 mA Analog power Dissipation 261 mW Digital power Dissipation 121 mW Total power Dissipation 382 mW Power Down Dissipation 10 µW Sleep Mode Dissipation 96 mW Analog supply current Digital supply current Digital and output driver supply Sleep Channel Mode Dissipation Power dissipation with all chs in sleep mode 98 mW Sleep Channel Mode Savings Power dissipation savings per channel off 38 mW Clock Inputs Maximum Conversion Rate Minimum Conversion Rate 65 MSPS 20 MSPS CDK8307 12/13-bit, 20/40/50/65MSPS, Eight Channel, Ultra Low Power ADC with LVDS 50 Maximum Conversion Rate Rev 0.4.0 ©2009 CADEKA Microcircuits LLC www.cadeka.com 12 PRELIMINARY Data Sheet Digital and Timing Electrical Characteristics (AVDD = 1.8V, DVDD = 1.8V, OVDD = 1.8V, unless otherwise noted) Symbol Parameter Conditions Min Typ Max Units 80 %high Clock Inputs 20 CMOS, LVDS, LVPECL Input range Differential input swing 200 200 mVpp Input range Differential input swing, sine wave clock input Input common mode voltage Keep voltages within gnd and voltage of AVDD 800 800 mVpp 0.3 VAVDD -0.3 Input capacitance Differential V 2 pF Logic Inputs (CMOS) VIH High Level Input Voltage VIL Low Level Input Voltage IIH VOVDD ≥ 3.0V VOVDD = 1.7V – 3.0V 2 V 0.8 • VOVDD V VOVDD ≥ 3.0V 0 0.8 V VOVDD = 1.7V – 3.0V 0 0.2 • VOVDD V High Level Input Leakage Current -10 10 µA IIL Low Level Input Leakage Current -10 10 µA CI Input Capacitance 3 pF Data Outputs (LVDS) Compliance VOUT Digital Output Voltage VCM Output Common Mode Voltage Output Coding LVDS Default/Optional 247 454 mV 1.125 1.375 V Offset Binary/2‘s Complement Timing Characteristics TAP Aperture Delay 0.8 ns εRMS Aperture Jitter <0.5 ps TPD Power Down Start up time from Power Down to Active Mode. References have reached 99% of final value. (See section Clock Frequency) TSLP Sleep Mode Start up time from Sleep Mode to Active Mode TOVR TLAT 350 900 clock cycles 0.5 µs Out Of Range Recovery Time 1 clk cycles Pipeline Delay 14 clk cycles LVDS Output Timing Characterisctics tdata LCLK to Data Delay Time TPROP Clock Propagation Delay Excluding programmable phase shift LVDS Bit-Clock Duty-Cycle 50 ps TBD ns 45 Frame clock cycle-to-cycle jitter 55 % LCLK cycle 2.5 % LCLK cycle TEDGE Data Rise- and Fall Time Calculated from -100mV to +100mV, and vice-versa TBD ns TCLKEDGE Clock Rise- and Fall Time Calculated from -100mV to +100mV, and vice-versa TBD ns Note: ©2009 CADEKA Microcircuits LLC www.cadeka.com Rev 0.4.0 (1) The outputs will be functional with higher loads. However, it is recommended to keep the load on output data bits as low as possible to keep dynamic currents and resulting switching noise at a minimum. CDK8307 12/13-bit, 20/40/50/65MSPS, Eight Channel, Ultra Low Power ADC with LVDS Duty Cycle Compliance 13 PRELIMINARY Data Sheet LVDS Timing Diagrams Analog Input CDK8307 12/13-bit, 20/40/50/65MSPS, Eight Channel, Ultra Low Power ADC with LVDS ADC Clock TLVDS LCLKP LCLKN FCLKN FCLKP Dxx<1:0> D10 N-2 D11 N-2 D0 N-1 D1 N-1 D2 N-1 D3 N-1 D4 N-1 D5 N-1 D6 N-1 D7 N-1 D8 N-1 D9 N-1 D10 N-1 D11 N-1 D0 N D1 N D2 N D3 N D4 N D5 N D4 N D5 N D6 N D6 N D7 N D8 N D9 N D10 N TPROP Figure 1. 12-bit Output, DDR Mode Analog Input ADC Clock TLVDS LCLKP LCLKN FCLKN FCLKP Dxx<1:0> D0 N-1 D1 N-1 D2 N-1 D3 N-1 D4 N-1 D5 N-1 D6 N-1 D7 N-1 D8 N-1 D9 D10 D11 D12 D13 N-1 N-1 N-1 N-1 N-1 D0 N D1 N D2 N D3 N D7 N D8 N D9 N D10 D11 D12 D13 N N N N TPROP Figure 2. 14-bit Output, DDR Mode Analog Input ADC Clock TLVDS LCLKP LCLKN FCLKN FCLKP Dxx<1:0> D10 D11 D0 D1 D2 D3 D4 D5 D6 D7 D8 D9 D10 D11 N-2 N-2 N-1 N-1 N-1 N-1 N-1 N-1 N-1 N-1 N-1 N-1 N-1 N-1 D0 N D1 N D2 N D3 N D4 N D5 N D6 N D7 N D8 N D9 N D10 N TPROP Figure 3. 12-bit Output, SDR Mode TLVDS LCLKP LCLKN TLVDS/2 Rev 0.4.0 Dxx<1:0> tdata Figure 4. Data Timing ©2009 CADEKA Microcircuits LLC www.cadeka.com 14 PRELIMINARY Data Sheet Serial Interface The CDK8307 configuration registers can be accessed through a serial interface formed by the pins SDATA (serial interface data), SCLK (serial interface clock) and CSN (chip select, active low). The following occurs when CSN is set low: Serial data are shifted into the chip n At every rising edge of SCLK, the value present at SDATA is latched n SDATA is loaded into the register every 24th rising edge of SCLK Multiples of 24-bit words data can be loaded within a single active CSN pulse. If more than 24 bits are loaded into SDATA during one active CSN pulse, only the first 24 bits are kept. The excess bits are ignored. Every 24-bit word is divided into two parts: n The first eight bits form the register address n The remaining 16 bits form the register data Acceptable SCLK frequencies are from 20MHz down to a few hertz. Duty-cycle does not have to be tightly controlled. Timing Diagram Figure 5 shows the timing of the serial port interface. Table 1 below explains the timing variables used in the Timing Diagram. tcs tlo CSN SCLK SDATA A7 A6 thi A5 A4 A3 A2 tclk A1 A0 D15 D14 D13 th D12 ts D11 D10 tch i tch D9 D8 D7 D6 D5 D4 D3 D2 D1 D0 Figure 5. Serial Port Interface Timing Diagram Table 1. Serial Port Interface Timing Definitions Parameter Minimum Value Unit tcs Setup time between CSN and SCLK Description 8 ns tch Hold time between CSN and SCLK 8 ns thi SCLK high time 20 ns tlo SCLK low time 20 ns tclk SCLK period 50 ns ts Data setup time 5 ns th Data hold time 5 ns Register Initialization Before CDK8307 can be used, the internal registers must be initialized to their default values. This can be done immediately after applying supply voltage to the circuit. Initialization can be done in one of two ways: Rev 0.4.0 1.By applying a low-going pulse on the RESET pin 2.By using the serial interface to set the RST bit high. Internal registers are reset to default values when this bit is set. The RST bit is self-reset to zero. When using this method, do not apply any low-going pulse on the RESETN pin. ©2009 CADEKA Microcircuits LLC www.cadeka.com CDK8307 12/13-bit, 20/40/50/65MSPS, Eight Channel, Ultra Low Power ADC with LVDS n 15 PRELIMINARY Data Sheet Serial Register Map Table 2. Summary of Functions Supported by the Serial Interface Name Description Default D 1 5 D 1 4 Software reset. This bit is self-clearing Inactive pd_ch<8:1> Channel-specific power-down Inactive sleep Go to sleep-mode Inactive pd Go to power-down Inactive pd_pin_cfg Configures the PD pin for sleep-mode PD pin configured for power-down mode ilvds_lclk<2:0> LVDS current drive programmability for LCLKP and LCLKN pins 3.5mA drive ilvds_ frame<2:0> LVDS current drive programmability for FCLKP and FCLKN pins 3.5mA drive ilvds_dat<2:0> LVDS current drive programmability for output data pins 3.5mA drive en_lvds_term Enables internal termination for LVDS buffers Termination disabled X term_lclk<2:0> Programmable termination for LCLKN and LCLKP buffers Termination disabled 1 term_ frame<2:0> Programmable termination for FCLKN and FCLKP buffers Termination disabled 1 term_dat<2:0> Programmable termination for output data buffers Termination disabled 1 invert_ch<8:1> Swaps the polarity of the analog input pins electrically IPx is positive input en_ramp Enables a repeating full-scale ramp pattern on the outputs dual_custom_pat Enable the mode wherein the output toggles between two defined codes D 1 2 D 1 1 D 1 0 D 9 D 8 D 7 X D 6 X D 5 X D 4 X D 3 X D 2 X D 1 X D 0 Address In Hex X 00 X X X 0F X X X X X X X X 11 X X X X X 12 X X X X X X Inactive X 0 0 Inactive 0 X 0 single_custom_ pat Enables the mode wherein the Inactive output is a constant specified code 0 0 X bits_custom1<13:0> Bits for the single custom pattern and for the first code of the dual Inactive custom pattern. <0> is the LSB X X X X X X X X X X X X X X 26 bits_custom2<13:0> Bits for the second code of the dual custom pattern X X X X X X X X X X X X X X 27 gain_ch1<3:0> Programmable gain for channel 1 0dB gain X X gain_ch2<3:0> Programmable gain for channel 2 0dB gain gain_ch3<3:0> Programmable gain for channel 3 0dB gain gain_ch4<3:0> Programmable gain for channel 4 0dB gain X X X X gain_ch5<3:0> Programmable gain for channel 5 0dB gain X X X X Inactive Programmable gain for channel 6 0dB gain gain_ch7<3:0> Programmable gain for channel 7 0dB gain gain_ch8<3:0> Programmable gain for channel 8 0dB gain ©2009 CADEKA Microcircuits LLC X X X X X X X X X X X X X X X X X X X X X X X X 24 25 X X 2A 2B X X X Rev 0.4.0 gain_ch6<3:0> CDK8307 12/13-bit, 20/40/50/65MSPS, Eight Channel, Ultra Low Power ADC with LVDS rst D 1 3 X www.cadeka.com 16 PRELIMINARY Data Sheet Table 2. Summary of Functions Supported by the Serial Interface (Continued) Name Description Default D 1 5 D 1 4 D 1 3 D 1 2 D 1 1 D 1 0 D 9 D 8 D 7 D 6 D 5 X X D 4 D 3 D 2 D 1 D 0 phase_ddr<1:0> Controls the phase of LCLK output relative to data 90 degrees pat_deskew Enable deskew pattern mode Inactive 0 X pat_sync Enable sync pattern mode Inactive X 0 btc_mode Binary two's complement format for ADC output data Straight offset binary msb_first Serialized ADC output data comes out with MSB first LSB-first output en_sdr Enable SDR output mode. LCLK becomes a 12x input clock DDR output mode fall_sdr Rising edge Controls whether the LCLK risof LCLK ing or falling edge comes in the comes in the middle of the data window when middle of the operating in SDR mode data window perfm_cntrl ADC performance control Nominal ext_vcm_bc VCM buffer driving strength control Nominal lvds_pd_mode Controls LVDS power down mode High z mode lvds_num_bits Sets the number of LVDS output bits 13-bit fs_cntrl Fine adjust ADC full scale range 0% change clk_freq Input clock frequency 65MHz Address In Hex 42 X X X X 46 1 X X X X X 50 X X X X X 52 X 0 53 X X 55 X X 56 D 1 D 0 Address In Hex X 00 Address In Hex Description of Serial Registers Table 3. Software Reset Name rst Description Self-clearing software reset Default D 1 5 D 1 4 D 1 3 D 1 2 D 1 1 D 1 0 D 9 D 8 D 7 D 6 D 5 D 4 D 3 D 2 Inactive Setting the rst register bit to '1', resets all internal registers including the rst register bit itself. Table 4. Power-Down Modes Name Description Default Channel-specific power-down Inactive sleep Go to sleep-mode Inactive pd Go to power-down Inactive pd_pin_cfg Configures the PD pin for sleep-mode PD pin configured for power-down mode. lvds_pd_mode Controls LVDS power down mode ©2009 CADEKA Microcircuits LLC High z mode D 1 4 D 1 3 D 1 2 D 1 1 D 1 0 D 9 D 8 D 7 D 6 D 5 D 4 D 3 D 2 D 1 D 0 X X X X X X X X X X 0F X X Rev 0.4.0 pd_ch<8:1> D 1 5 52 www.cadeka.com CDK8307 12/13-bit, 20/40/50/65MSPS, Eight Channel, Ultra Low Power ADC with LVDS 45 17 PRELIMINARY Data Sheet Setting pd_ch<n> = '1', powers down channel <n> of the ADC. Setting sleep = '1', powers down the entire chip, except the band-gap reference circuit. Setting pd = '1' completely powers down the chip, including the band-gap reference circuit. Start-up time from this mode is significantly longer than from the sleep and pd_ch<n> modes. The lvds_pd_mode register configures whether the LVDS data output drivers are powered down or not in sleep and sleep channel modes. LCLK and FCLK drivers are not affected by this register, and are always on in sleep and sleep channel modes. If lvds_pd_mode is set low (default), the LVDS output is put in high Z, and the driver is completely powered down. If lvds_pd_mode is set high, the LVDS output is set to constant 0, and the driver is still on during sleep and sleep channel modes. Table 5. LVDS Drive Strength Programmability Name Description Default ilvds_lclk<2:0> LVDS current drive programmability for LCLKP and LCLKN pins. 3.5mA drive ilvds_ frame<2:0> LVDS current drive programmability for FCLKP and FCLKN pins. 3.5mA drive ilvds_dat<2:0> LVDS current drive programmability for output data pins. 3.5mA drive D 1 5 D 1 4 D 1 3 D 1 2 D 1 1 D 1 0 D 9 D 8 D 7 D 6 X X X D 5 X D 4 X D 3 D 2 D 1 D 0 X X X Address In Hex 11 X The current delivered by the LVDS output drivers can be configured as shown in Table 6. The default current is 3.5mA, which is what the LVDS standard specifies. Setting the ilvds_lclk<2:0> register controls the current drive strength of the LVDS clock output on the LCLKP and LCLKN pins. Setting the ilvds_frame<2:0> register controls the current drive strength of the frame clock output on the FCLKP and FCLKN pins. Setting the ilvds_dat<2:0> register controls the current drive strength of the data outputs on the D[8:1]P and D[8:1] N pins. Table 6. LVDS Output Drive Strength for LCLK, FCLK, and Data ilvds_*<2:0> LVDS Drive Strength 000 3.5 mA (default) 001 2.5 mA 010 1.5 mA 011 0.5 mA 100 7.5 mA 101 6.5 mA 110 5.5 mA 111 4.5 mA CDK8307 12/13-bit, 20/40/50/65MSPS, Eight Channel, Ultra Low Power ADC with LVDS Setting pdn_pin_cfg = '1' configures the circuit to enter sleep mode when the PD pin is set high. When pdn_pin_cfg = '0', which is the default, the circuit enters power down mode when the PD pin is set high. Rev 0.4.0 ©2009 CADEKA Microcircuits LLC www.cadeka.com 18 PRELIMINARY Data Sheet Table 7. LVDS Internal Termination Programmability Name Description Default D 1 5 D 1 4 Enables internal termination for LVDS buffers Termination disabled X term_lclk<2:0> Programmable termination for LCLKN and LCLKP buffers Termination disabled 1 term_ frame<2:0> Programmable termination for FCLKN and FCLKP buffers Termination disabled 1 term_dat<2:0> Programmable termination for DxP and DxN buffers Termination disabled 1 D 1 2 D 1 1 D 1 0 D 9 D 8 D 7 D 6 X X X D 5 X D 4 D 3 D 2 D 1 D 0 X X X Address In Hex 12 X X The off-chip load on the LVDS buffers may represent a characteristic impedance that is not perfectly matched with the PCB traces. This may result in reflections back to the LVDS outputs and loss of signal integrity. This effect can be mitigated by enabling an internal termination between the positive and negative outputs of each LVDS buffer. Internal termination mode can be selected by setting the en_lvds_term bit to '1'. Once this bit is set, the internal termination values for the bit clock, frame clock, and data buffers can be independently programmed using sets of three bits. Table 8 shows how the internal termination of the LVDS buffers are programmed. The values are typical values and can vary by up to ±20% from device to device and across temperature. Table 8. Bit Clock Internal Termination term_*<2:0> LVDS Internal Termination 000 Termination Disabled 001 260Ω 010 150Ω 011 94Ω 100 125Ω 101 80Ω 110 66Ω 111 55Ω Table 9. Analog Input Invert Name invert_ch<8:1> Description Default Swaps the polarity of the analog input pins electrically IPx is positive input D 1 5 D 1 4 D 1 3 D 1 2 D 1 1 D 1 0 D 9 D 8 D 7 D 6 D 5 D 4 D 3 D 2 D 1 D 0 Address In Hex X X X X X X X X 24 The IPx pin represents the positive analog input pin, and INx represents the negative (complementary) input. Setting the bits marked invert_ch <8:1> (individual control for each channel) causes the inputs to be swapped. INx would then represent the positive input, and IPx the negative input. CDK8307 12/13-bit, 20/40/50/65MSPS, Eight Channel, Ultra Low Power ADC with LVDS en_lvds_term D 1 3 Rev 0.4.0 ©2009 CADEKA Microcircuits LLC www.cadeka.com 19 PRELIMINARY Data Sheet Table 10. LVDS Test Patterns Name Description Default D 1 5 D 1 4 D 1 3 D 1 2 D 1 1 D 1 0 D 9 D 8 D 7 D 6 D 5 D 4 Enables a repeating full-scale ramp pattern on the outputs Inactive X 0 0 dual_custom_pat Enable the mode wherein the output toggles between two defined codes Inactive 0 X 0 D 2 D 1 D 0 Address In Hex 25 single_custom_ pat Enables the mode wherein the Inactive output is a constant specified code bits_custom1<13:0> Bits for the single custom pattern Inactive and for the first code of the dual custom pattern. <0> is the LSB X X X X X X X X bits_custom2<13:0> Bits for the second code of the dual custom pattern Inactive X X X X X X X X pat_deskew Enable deskew pattern mode Inactive 0 X pat_sync Enable sync pattern mode Inactive X 0 0 0 X X X X X X X 26 X X X X X X 27 45 To ease the LVDS synchronization setup of CDK8307, several test patterns can be set up on the outputs. Normal ADC data are replaced by the test pattern in these modes. Setting en_ramp to '1' sets up a repeating full-scale ramp pattern on all data outputs. The ramp starts at code zero and is increased 1LSB every clock cycle. It returns to zero code and starts the ramp again after reaching the full-scale code. A constant value can be set up on the outputs by setting single_custom_pat to '1', and programming the desired value in bits_custom1<13:0>. In this mode, bits_custom1<13:0> replaces the ADC data at the output, and is controlled by LSB-first and MSB-first modes in the same way as normal ADC data are. The device may also be made to alternate between two codes by programming dual_custom_pat to '1'. The two codes are the contents of bits_custom1<13:0> and bits_custom2<13:0>. Two preset patterns can also be selected: 1. Deskew pattern: Set using pat_deskew, this mode replaces the ADC output with '01010101010101' (two LSBs removed in 12 bit mode). 2. Sync pattern: Set using pat_sync, the normal ADC word is replaced by a fixed 1111110000000 word. Note: Only one of the above patterns should be selected at the same time. Table 11. Programmable Gain Name Description Default D 1 5 D 1 4 D 1 3 D 1 2 Programmable gain for channel 1 0dB gain gain_ch2<3:0> Programmable gain for channel 2 0dB gain gain_ch3<3:0> Programmable gain for channel 3 0dB gain gain_ch4<3:0> Programmable gain for channel 4 0dB gain X X X X gain_ch5<3:0> Programmable gain for channel 5 0dB gain X X X X gain_ch6<3:0> Programmable gain for channel 6 0dB gain gain_ch7<3:0> Programmable gain for channel 7 0dB gain gain_ch8<3:0> Programmable gain for channel 8 0dB gain D 1 0 D 9 D 8 X X X X X X X X D 7 D 6 D 5 D 4 X X X X X X X X D 3 D 2 D 1 D 0 X X X X Address In Hex 2A 2B X X X X CDK8307 includes a purely digital programmable gain option in addition to the Full-scale Control. The programmable gain of each channel can be individually set using a set of four bits, indicated as gain_chn<3:0> for Channel x. The gain setting is coded in binary from 0dB to 12dB, as shown in Table 12 on the following page. ©2009 CADEKA Microcircuits LLC www.cadeka.com 20 Rev 0.4.0 gain_ch1<3:0> D 1 1 CDK8307 12/13-bit, 20/40/50/65MSPS, Eight Channel, Ultra Low Power ADC with LVDS en_ramp D 3 PRELIMINARY Data Sheet Table 12. Gain Setting for Channels 1-8 Channel x Gain Setting 0000 0dB 0001 1dB 0010 2dB 0011 3dB 0100 4dB 0101 5dB 0110 6dB 0111 7dB 1000 8dB 1001 9dB 1010 10dB 1011 11dB 1100 12dB 1101 Do not use 1110 Do not use 1111 Do not use Table 13. LVDS Clock Programmability and Data Output Modes Name Description Default phase_ddr<1:0> Controls the phase of LCLK output relative to data 90 degrees btc_mode Binary two's complement format for ADC output data Straight offset binary msb_first Serialized ADC output data comes out with MSB first LSB-first output en_sdr Enable SDR output mode. LCLK becomes a 12x input clock DDR output mode fall_sdr Rising edge Controls whether the LCLK risof LCLK ing or falling edge comes in the comes in the middle of the data window when middle of the operating in SDR mode data window D 1 5 D 1 4 D 1 3 D 1 2 D 1 1 D 1 0 D 9 D 8 D 7 D 6 D 5 X X D 4 D 3 D 2 D 1 D 0 Address In Hex 42 X X X X 46 X The output interface of CDK8307 is normally a DDR interface, with the LCLK rising and falling edge transitions in the middle of alternate data windows. The phase for LCLK can be programmed relative to the output frame clock and data using bits phase_ddr<1:0>. The LCLK phase modes are shown in Figure 6. The default timing is identical to setting phase_ddr<1:0> = '10'. CDK8307 12/13-bit, 20/40/50/65MSPS, Eight Channel, Ultra Low Power ADC with LVDS gain_chx<3:0> Rev 0.4.0 ©2009 CADEKA Microcircuits LLC www.cadeka.com 21 PRELIMINARY Data Sheet PHASE_DDR<1:0>=’00’ PHASE_DDR<1:0>=’10’ FCLKN FCLKP LCLKN LCLKP Dxx<1:0> Dxx<1:0> PHASE_DDR<1:0>=’01’ PHASE_DDR<1:0>=’11’ FCLKN FCLKP LCLKN LCLKP FCLKN FCLKP LCLKP LCLKN Dxx<1:0> Dxx<1:0> Figure 6. Phase Programmability Modes for LCLK The device can also be made to operate in SDR mode by setting the en_sdr bit to '1'. The bit clock (LCLK) is output at 12x times the input clock in this mode, two times the rate in DDR mode. Depending on the state of fall_sdr, LCLK may be output in either of the two manners shown in Figure 7. As can be seen in Figure 7, only the LCLK rising (or falling) edge is used to capture the output data in SDR mode. The SDR mode is not recommended beyond 40MSPS because the LCLK frequency becomes very high. EN_SDR=’1’, FALL_SDR_’0’ FCLKN FCLKP LCLKP LCLKN Dxx<1:0> EN_SDR=’1’, FALL_SDR_’1’ FCLKN FCLKP LCLKN LCLKP Dxx<1:0> Figure 7. SDR Interface Modes The default data output format is offset binary. Two's complement mode can be selected by setting the btc_mode bit to '1' which inverts the MSB. The first bit of the frame (following the rising edge of FCLKP) is the LSB of the ADC output for default settings. Programming the msb_first mode results in reverse bit order, and the MSB is output as the first bit following the FCLKP rising edge. Table 14. Number of Serial Output Bits Name lvds_num_bits Description Default Sets the number if LVDS output bits 12-bit D 1 5 D 1 4 D 1 3 D 1 2 D 1 1 D 1 0 D 9 D 8 D 7 D 6 D 5 D 4 D 3 D 2 D 1 D 0 Address In Hex X 0 53 ©2009 CADEKA Microcircuits LLC www.cadeka.com 22 Rev 0.4.0 The ADCs have 13-bit resolution. There are two options for the serial LVDS outputs, 12 bits or 14 bits, selected by register values '00' and '10', respectively. In 12-bit mode, the LSB bit from the ADCs are removed in the output stream. In 14-bit mode, a '0' is added in the LSB position. Power down mode must be activated after or during a change in the number of output bits. CDK8307 12/13-bit, 20/40/50/65MSPS, Eight Channel, Ultra Low Power ADC with LVDS FCLKN FCLKP LCLKP LCLKN PRELIMINARY Data Sheet Table 15. Full Scale Control Name Description fs_cntrl<5:0> Default Fine adjust ADC full scale range D 1 5 D 1 4 D 1 3 D 1 2 D 1 1 D 1 0 D 9 D 8 D 7 D 6 0% change D 5 D 4 D 3 D 2 D 1 D 0 Address In Hex X X X X X X 55 The full-scale control and the programmable gain features differ in two major ways: 1. The full-scale control feature controls the full-scale voltage range in an analog fashion, whereas the programmable gain is a digital feature. 2. The programmable gain feature has much coarser gain steps and larger range than the full-scale control. Table 16. Register Values with Corresponding Change in Full-Scale Range fs_cntrl <5:0> Full-Scale Range Adjustment 111111 +9.7% ... ... 100001 +0.3% 100000 +0% 011111 -0.3% ... ... 000000 -10% Table 17. Clock Frequency Name Description clk_freq<1:0> Input clock frequency Default D 1 5 D 1 4 65MHz D 1 3 D 1 2 D 1 1 D 1 0 D 9 D 8 D 7 D 6 D 5 D 4 D 3 D 2 D 1 D 0 Address In Hex X X 56 To optimize startup time a register is provided where the input clock frequency can be set. Some internal circuitry has startup times that are frequency independent. Default counter values are set to accommodate these startup times at the maximum clock frequency. This will lead to increased startup times at low clock frequency. Setting the value of this register to the nearest higher clock frequency will reduce the count values of the internal counters, to better fit the actual startup time, such that the startup time will be reduced. Table 18. Clock Frequency Settings clk_freq <1:0> Clock Frequency (MHz) 00 65 01 45 10 30 11 20 CDK8307 12/13-bit, 20/40/50/65MSPS, Eight Channel, Ultra Low Power ADC with LVDS The full-scale voltage range of CDK8307 can be adjusted using an internal 6-bit DAC controlled by the fs_cntrl register. Changing the value in the register by one step, adjusts the full-scale range approximately 0.3%. This leads to a maximum range of ±10% adjustment. Table 16 shows how the register settings correspond to the full-scale range. Note that the values for full-scale range adjustment are approximate. The DAC is, however, guaranteed to be monotonous. Rev 0.4.0 ©2009 CADEKA Microcircuits LLC www.cadeka.com 23 PRELIMINARY Data Sheet Table 19. Performance Control Name Description D 1 5 Default ADC performance control Nominal ext_vcm_ bc<1:0> VCM buffer driving strength control Nominal D 1 3 D 1 2 D 1 1 D 1 0 D 9 D 8 D 7 D 6 D 5 X D 4 D 3 D 2 D 1 D 0 X X X Address In Hex 50 X There are two registers that impact performance and power dissipation. The perfm_cntrl register adjusts the performance level of the ADC core. If full performance is required, the nominal setting must be used. The lowest code can be used in situations where power dissipation is critical and performance is less important. For most conditions the performance at the minimum setting will be similar to nominal setting. However, only 10-bit performance can be expected at worst case conditions. The power dissipation savings shown in Table 20 are only approximate numbers for the ADC current alone. Table 20. Performance Control Settings performance_control <2:0> Power Dissipation 100 -40% (lower performance) 101 -30% 110 -20% 111 -10% 000 (default) Nominal 001 Do not use 010 Do not use 011 Do not use The ext_vcm_bc register controls the driving strength in the buffer supplying the voltage on the VCM pin. If this pin is not in use, the buffer can be switched off. If current is drawn from the VCM pin, the driving strength can be increased to keep the voltage on this pin at the correct level. Table 21. External Common Mode Voltage Buffer Driving Strength ext_vcm_bc <1:0> VCM Buffer Driving Strength 00 Off (VCM floating) 01 (default) Low 10 High 11 Max CDK8307 12/13-bit, 20/40/50/65MSPS, Eight Channel, Ultra Low Power ADC with LVDS perfm_ cntrl<2:0> D 1 4 Rev 0.4.0 ©2009 CADEKA Microcircuits LLC www.cadeka.com 24 PRELIMINARY Data Sheet Therory of Operation The ADC employs a pipelined converter architecture. Each stage feeds its output data into the digital error correction logic, ensuring excellent differential linearity and no missing codes at 13-bit level. The CDK8307 operates from two sets of supplies and grounds. The analog supply and ground set is identified as AVDD and AVSS, while the digital set is identified by DVDD and DVSS. Recommended Usage Analog Input The analog input to the CDK8307 is a switched capacitor track-and-hold amplifier optimized for differential operation. Operation at common mode voltages at mid supply is recommended even if performance will be good for the ranges specified. The VCM pin provides a voltage suitable as common mode voltage reference. The internal buffer for the VCM voltage can be switched off, and driving capabilities can be changed programming the ext_vcm_ bc<1:0> register. ©2009 CADEKA Microcircuits LLC DC-Coupling Figure 9 shows a recommended configuration for DCcoupling. Note that the common mode input voltage must be controlled according to specified values. Preferably, the CM_EXT output should be used as a reference to set the common mode voltage. The input amplifier could be inside a companion chip or it could be a dedicated amplifier. Several suitable single ended to differential driver amplifiers exist in the market. The system designer should make sure the specifications of the selected amplifier is adequate for the total system, and that driving capabilities comply with the CDK8307 input specifications. Detailed configuration and usage instructions must be found in the documentation of the selected driver, and the values given in Figure 10 must be varied according to the recommendations for the driver. 43Ω 33pF 43Ω Rev 0.4.0 Figure 8 shows a simplified drawing of the input network. The signal source must have sufficiently low output impedance to charge the sampling capacitors within one clock cycle. A small external resistor (e.g. 22Ω) in series with each input is recommended as it helps reducing transient currents and dampens ringing behavior. A small Figure 8. Input Configuration Diagram CDK8307 12/13-bit, 20/40/50/65MSPS, Eight Channel, Ultra Low Power ADC with LVDS The CDK8307 is an 8-channel, high-speed, CMOS ADC. The 13-bits given out by each channel are serialized to 12, 13 or 14-bits and sent out on a single pair of pins in LVDS format. All eight channels of the CDK8307 operate from a single differential or single ended clock. The sampling clocks for each of the eight channels are generated from the clock input using a carefully matched clock buffer tree. The 12x/13x/14x clock required for the serializer is generated internally from FCLK using a phase-locked loop (PLL). A 6x/6.5x/7x and 1x clock are also output in LVDS format, along with the data to enable easy data capture. The CDK8307 uses internally generated references that can be shorted across several devices to improve gain-matching. The differential reference value is 1V. This results in a differential input of -1V to correspond to the zero code of the ADC, and a differential input of +1V to correspond to the full-scale code (code 8191). differential shunt capacitor at the chip side of the resistors may be used to provide dynamic charging currents and may improve performance. The resistors form a low pass filter with the capacitor, and values must therefore be determined by requirements for the application. Figure 9. DC-Coupled Input www.cadeka.com 25 PRELIMINARY Data Sheet AC-Coupling 33Ω RT 47Ω 33Ω Figure 10. Transformer Coupled Input If the input signal is traveling a long physical distance from the signal source to the transformer (for example a long cable), kick-backs from the ADC will also travel along this distance. If these kick-backs are not terminated properly at the source side, they are reflected and will add to the input signal at the ADC input. This could reduce the ADC performance. To avoid this effect, the source must effectively terminate the ADC kick-backs, or the traveling distance should be very short. If this problem could not be avoided, the circuit in Figure 10 can be used. ©2009 CADEKA Microcircuits LLC pF Ω Figure 11. AC-Coupled Input Note that startup time from Sleep Mode and Power Down Mode will be affected by this filter as the time required to charge the series capacitors is dependent on the filter cut-off frequency. If the input signal has a long traveling distance, and the kick-backs from the ADC not are effectively terminated at the signal source, the input network of Figure 12 can be used. The configuration is designed to attenuate the kickback from the ADC and to provide an input impedance that looks as resistive as possible for frequencies below Nyquist. 120nH 33Ω 1:1 optional RT 68Ω 220Ω pF 120nH 33Ω Figure 12: Alternative Input Network Values of the series inductor will however depend on board design and conversion rate. In some instances a shunt capacitor in parallel with the termination resistor (e.g. 33pF) may improve ADC performance further. This capacitor attenuate the ADC kick-back even more, and minimize the kicks traveling towards the source. However, the impedance match seen into the transformer becomes worse. www.cadeka.com 26 Rev 0.4.0 Figure 11 shows AC-coupling using capacitors. Resistors from the CM_EXT output, RCM, should be used to bias the differential input signals to the correct voltage. The series capacitor, CI, form the high-pass pole with these resistors, and the values must therefore be determined based on the requirement to the high-pass cut-off frequency. Ω CDK8307 12/13-bit, 20/40/50/65MSPS, Eight Channel, Ultra Low Power ADC with LVDS A signal transformer or series capacitors can be used to make an AC-coupled input network. Figure 8 shows a recommended configuration using a transformer. Make sure that a transformer with sufficient linearity is selected, and that the bandwidth of the transformer is appropriate. The bandwidth should exceed the sampling rate of the ADC with at least a factor of 10. It is also important to keep phase mismatch between the differential ADC inputs small for good HD2 performance. This type of transformer coupled input is the preferred configuration for high frequency signals as most differential amplifiers do not have adequate performance at high frequencies. Magnetic coupling between the transformers and PCB traces may impact channel crosstalk, and must hence be taken into account during PCB layout. PRELIMINARY Data Sheet Clock Input and Jitter Considerations The input clock can be supplied in a variety of formats. The clock pins are AC-coupled internally, and hence a wide common mode voltage range is accepted. Differential clock sources as LVDS, LVPECL or differential sine wave can be connected directly to the input pins. For CMOS inputs, the CLKN pin should be connected to ground, and the CMOS clock signal should be connected to CLKP. For differential sine wave clock input the amplitude must be at least ±0.8Vpp. The quality of the input clock is extremely important for high-speed, high-resolution ADCs. The contribution to SNR from clock jitter with a full scale signal at a given frequency is shown in equation below. SNRjitter = 20 • log (2 • π • FIN • εt) where FIN is the signal frequency, and εt is the total rms jitter measured in seconds. The rms jitter is the total of all jitter sources including the clock generation circuitry, clock distribution and internal ADC circuitry. The jitter performance is improved with reduced rise and fall times of the input clock. Hence, optimum jitter performance is obtained with LVDS or LVPECL clock with fast edges. CMOS and sine wave clock inputs will result in slightly degraded jitter performance. If the clock is generated by other circuitry, it should be retimed with a low jitter master clock as the last operation before it is applied to the ADC clock input. CDK8307 12/13-bit, 20/40/50/65MSPS, Eight Channel, Ultra Low Power ADC with LVDS Typically high-speed ADCs use both clock edges to generate internal timing signals. In the CDK8307 only the rising edge of the clock is used. Hence, input clock duty cycles between 20% and 80% is acceptable. For applications where jitter may limit the obtainable performance, it is of utmost importance to limit the clock jitter. This can be obtained by using precise and stable clock references (e.g. crystal oscillators with good jitter specifications) and make sure the clock distribution is well controlled. It might be advantageous to use analog power and ground planes to ensure low noise on the supplies to all circuitry in the clock distribution. It is of utmost importance to avoid crosstalk between the ADC output bits and the clock and between the analog input signal and the clock since such crosstalk often results in harmonic distortion. Rev 0.4.0 ©2009 CADEKA Microcircuits LLC www.cadeka.com 27 PRELIMINARY Data Sheet Mechanical Dimensions QFN-64 aaa C A A ccc C A A2 A3 D D1 A1 E F G L e θ1 E1 aaa bbb ccc Pin 1 ID 0.05 Dia. Min – 0.00 – 0.008 0.197 0.197 0.05 0.0096 0.012 0° Inches Millimeters Typ Max Min Typ – 0.035 – – 0.0004 0.002 0.00 0.01 0.026 0.028 – 0.65 0.008 REF 0.2 REF 0.010 0.012 0.2 0.25 0.354 BSC 9.00 BSC 0.354 BSC 8.75 BSC 0.205 0.213 5.0 5.2 0.354 BSC 9.00 BSC 0.344 BSC 8.75 BSC 0.205 0.213 5.0 5.2 – – 1.3 – 0.0168 0.024 0.24 0.42 0.016 0.020 0.3 0.4 0.020 BSC 0.50 BSC – 12° 0° – Tolerance of Form and Position 0.10 0.004 0.10 0.004 0.05 0.002 Max 0.9 0.05 0.7 0.30 5.4 5.4 – 0.6 0.5 12° NOTES: 1. All dimensions are in millimeters. 2. Die thickness allowable is 0.305mm maximum (.012 inches maximum) 3. Dimensioning & tolerances conform to ASME y14.5m. -1994. bbb C B B C bbb C A 1.14 5. The pin #1 identifier must be placed on the top surface of the package by using indentation mark or other feature of package body. 6. Exact shape and size of this feature is optional. 7. Package warpage max 0.08mm. SIDE VIEW 9. Applied only to terminals. 10. Package corners unless otherwise specipied are r0.175±0.025mm. F D2 0.45 4. Dimension applies to plated terminal and is measured between 0.20 and 0.25mm from terminal tip. 8. Applied for exposed pad and terminals. Exclude embedding part of exposed pad from measuring. TOP VIEW Pin 1 ID Dia. 0.20 seating plane θ1 1.14 G E2 L e b 0.10 M C A B L BOTTOM VIEW CDK8307 12/13-bit, 20/40/50/65MSPS, Eight Channel, Ultra Low Power ADC with LVDS aaa C B Symbol A A1 A2 A3 b D D1 D2 E E1 E2 Rev 0.4.0 ©2009 CADEKA Microcircuits LLC www.cadeka.com 28 PRELIMINARY Data Sheet Mechanical Dimensions (Continued) TQFP-80 Dimensions (mm) 1.20 0.10 ±0.05 1.00 ±0.05 A3 0.25 b 0.22 ±0.05 0.145 +0.055 0.145 -0.045 12.00 ±0.20 12.00 ±0.20 c D E e 0.50 HD HE L Lp L1 x y ZD ZE 14.00 ±0.20 14.00 ±0.20 0.50 0.60 ±0.15 1.00 ±0.20 0.08 0.08 1.25 1.25 3° +5° 3° -3° θ NOTE: Each lead centerline is located within 0.08mm of its true position at maximum material condition. Detail of Lead End For additional information regarding our products, please visit CADEKA at: cadeka.com A m p l i fy t h e H u m a n E x p e r i e n c e CADEKA, the CADEKA logo design, COMLINEAR and the COMLINEAR logo design are trademarks or registered trademarks of CADEKA Microcircuits LLC. All other brand and product names may be trademarks of their respective companies. CADEKA reserves the right to make changes to any products and services herein at any time without notice. CADEKA does not assume any responsibility or liability arising out of the application or use of any product or service described herein, except as expressly agreed to in writing by CADEKA; nor does the purchase, lease, or use of a product or service from CADEKA convey a license under any patent rights, copyrights, trademark rights, or any other of the intellectual property rights of CADEKA or of third parties. Copyright ©2009 by CADEKA Microcircuits LLC. All rights reserved. designed by Rev 0.4.0 CADEKA Headquarters Loveland, Colorado T: 970.663.5452 T: 877.663.5452 (toll free) CDK8307 12/13-bit, 20/40/50/65MSPS, Eight Channel, Ultra Low Power ADC with LVDS TQFP-80 Symbol A A1 A2