a FEATURES 65 MSPS Minimum Sample Rate 80 dB Spurious-Free Dynamic Range IF-Sampling to 70 MHz 710 mW Power Dissipation Single +5 V Supply On-Chip T/H and Reference Twos Complement Output Format 3.3 V or 5 V CMOS-Compatible Output Levels APPLICATIONS Cellular/PCS Base Stations Multichannel, Multimode Receivers GPS Anti-Jamming Receivers Communications Receivers Phased Array Receivers 12-Bit, 65 MSPS IF Sampling A/D Converter AD6640 FUNCTIONAL BLOCK DIAGRAM AVCC DVCC AIN AIN VREF ENCODE ENCODE BUF TH1 +2.4V REFERENCE TH2 ADC DAC A ADC AD6640 7 6 INTERNAL TIMING DIGITAL ERROR CORRECTION LOGIC MSB GND TH3 LSB D11 D10 D9 D8 D7 D6 D5 D4 D3 D2 D1 D0 PRODUCT DESCRIPTION PRODUCT HIGHLIGHTS The AD6640 is a high speed, high performance, low power, monolithic 12-bit analog-to-digital converter. All necessary functions, including track-and-hold (T/H) and reference are included on-chip to provide a complete conversion solution. The AD6640 runs on a single +5 V supply and provides CMOScompatible digital outputs at 65 MSPS. 1. Guaranteed sample rate is 65 MSPS. 2. Fully differential analog input stage specified for frequencies up to 70 MHz; enables “IF Sampling.” 3. Low power dissipation: 710 mW off a single +5 V supply. 4. Digital outputs may be run on +3.3 V supply for easy interface to digital ASICs. 5. Complete Solution: reference and track-and-hold. 6. Packaged in small, surface mount, plastic 44-terminal TQFP. Specifically designed to address the needs of multichannel, multimode receivers, the AD6640 maintains 80 dB spuriousfree dynamic range (SFDR) over a bandwidth of 25 MHz. Noise performance is also exceptional; typical signal-to-noise ratio is 68 dB. The AD6640 is built on Analog Devices’ high speed complementary bipolar process (XFCB) and uses an innovative multipass architecture. Units are packaged in a 44-terminal Plastic Thin Quad Flatpack (TQFP) specified from –40°C to +85°C. REV. 0 Information furnished by Analog Devices is believed to be accurate and reliable. However, no responsibility is assumed by Analog Devices for its use, nor for any infringements of patents or other rights of third parties which may result from its use. No license is granted by implication or otherwise under any patent or patent rights of Analog Devices. One Technology Way, P.O. Box 9106, Norwood, MA 02062-9106, U.S.A. Tel: 781/329-4700 World Wide Web Site: http://www.analog.com Fax: 781/326-8703 © Analog Devices, Inc., 1998 AD6640–SPECIFICATIONS DC SPECIFICATIONS (AV CC = +5 V, DVCC = +3.3 V; TMIN = –408C, TMAX = +858C) Parameter Temp Test Level Min AD6640AST Typ RESOLUTION Max 12 Units Bits ACCURACY No Missing Codes Offset Error Gain Error Differential Nonlinearity (DNL)1 Integral Nonlinearity (INL)1 +25°C Full Full +25°C Full I VI VI I V TEMPERATURE DRIFT Offset Error Gain Error Full Full V V 50 100 ppm/°C ppm/°C Full V ± 0.5 mV/V Full V 2.4 V Full Full Full +25°C V V IV V VREF ± 0.05 2.0 0.9 1.5 V V p-p kΩ pF Full Full VI VI Full Full Full POWER SUPPLY REJECTION (PSRR) REFERENCE OUT (VREF) 2 ANALOG INPUTS (AIN, AIN)3 Analog Input Common-Mode Range4 Differential Input Voltage Range Differential Input Resistance Differential Input Capacitance POWER SUPPLY Supply Voltage AVCC DVCC Supply Current IAVCC (AVCC = 5.0 V) IDVCC (DVCC = 3.3 V) POWER CONSUMPTION –10 –10 –1.0 GUARANTEED 3.5 4.0 ± 0.5 ± 1.25 0.7 4.75 3.0 +10 +10 +1.5 1.1 mV % FS LSB LSB 5.0 3.3 5.25 5.25 V V VI VI 135 10 160 20 mA mA VI 710 865 mW NOTES 1 ENCODE = 20 MSPS 2 If VREF is used to provide a dc offset to other circuits, it should first be buffered. 3 The AD6640 is designed to be driven differentially. Both AIN and AIN should be driven at levels VREF ± 0.5 volts. The input signals should be 180 degrees out of phase to produce a 2 V p-p differential input signal. See Driving the Analog Inputs section for more details. 4 Analog input common-mode range specifies the offset range the analog inputs can tolerate in dc-coupled applications (see Figure 35 for more detail). Specifications subject to change without notice . DIGITAL SPECIFICATIONS (AV CC Parameter LOGIC INPUTS (ENC, ENC)1 Encode Input Common-Mode Range2 Differential Input Voltage Single-Ended Encode Logic Compatibility3 Logic “1” Voltage Logic “0” Voltage Logic “1” Current (VINH = 5 V) Logic “0” Current (VINL = 0 V) Input Capacitance LOGIC OUTPUTS (D11–D0)4 Logic Compatibility Logic “1” Voltage (DVCC = +3.3 V) Logic “0” Voltage (DVCC = +3.3 V) Logic “1” Voltage (DVCC = +5.0 V) Logic “0” Voltage (DVCC = +5.0 V) Output Coding = +5 V, DVCC = +3.3 V; TMIN = –408C, TMAX = +858C) Temp Test Level Min Full Full IV IV 0.2 0.4 AD6640AST Typ Max Units 2.2 V V p-p V p-p 10 TTL/CMOS Full Full Full Full +25°C VI VI VI VI V 2.0 0 500 –400 Full Full Full Full VI VI IV IV 2.8 4.5 650 –320 2.5 CMOS DVCC – 0.2 0.2 DVCC – 0.3 0.35 Twos Complement 5.0 0.8 800 –200 0.5 0.5 V V µA µA pF V V V V NOTES 1 Best dynamic performance is obtained by driving ENC and ENC differentially. See Encoding the AD6640 section for more details. Performance versus ENC/ENC power is shown in Figure 18 under Typical Performance Characteristics. 2 For dc-coupled applications, Encode Input Common-Mode Range specifies the common-mode range the encode inputs can tolerate when driven differentially by minimum differential input voltage of 0.4 V p-p. For differential input voltage swings greater than 0.4 V p-p, the common-mode range will change. The minimum value insures that the input voltage on either encode pin does not go below 0 V. The maximum value insures that the input voltage on either encode pin does not go below 2.0 V or above AV CC (e.g., for a differential input swing of 0.8 V, the min and max common-mode specs become 0.4 V and 2.4 V respectively). 3 ENC or ENC may be driven alone if desired, but performance will likely be degraded. Logic Compatibility specifications are provided to show that TTL or CMOS clock sources will work. When driving only one encode input, bypass the complementary input to GND with 0.01 µF. 4 Digital output load is one LCX gate. Specifications subject to change without notice. –2– REV. 0 AD6640 SWITCHING SPECIFICATIONS1 (AV CC = +5 V, DVCC = +3.3 V; ENCODE & ENCODE = 65 MSPS; TMIN = –408C, TMAX = +858C) Parameter (Conditions) Temp Test Level Maximum Conversion Rate Minimum Conversion Rate2 Aperture Delay (tA) Aperture Uncertainty (Jitter) ENCODE Pulsewidth High3 ENCODE Pulsewidth Low Output Delay (tOD) DVCC +3.3 V/5.0 V4 Full Full +25°C +25°C +25°C +25°C Full VI IV V V IV IV IV Min AD6640AST Typ Max 65 6.5 400 0.3 6.5 6.5 8.5 10.5 12.5 Units MSPS MSPS ps ps rms ns ns ns NOTES 1 All switching specifications tested by driving ENCODE and ENCODE differentially. 2 A plot of Performance vs. Encode is shown in Figure 16 under Typical Performance Characteristics. 3 A plot of Performance vs. Duty Cycle (Encode = 65 MSPS) is shown in Figure 17 under Typical Performance Characteristics. 4 Outputs driving one LCX gate. Delay is measured from differential crossing of ENC, ENC to the time when all output data bits are within valid logic levels. Specifications subject to change without notice. AC SPECIFICATIONS1 (AV CC = +5 V, DVCC = +3.3 V; ENCODE & ENCODE = 65 MSPS; TMIN = –408C, TMAX = +858C) Temp Test Level 2.2 MHz 15.5 MHz 31.0 MHz 69.0 MHz +25°C +25°C +25°C +25°C V I V V 2.2 MHz 15.5 MHz 31.0 MHz 69.0 MHz +25°C +25°C +25°C +25°C V I V V Worst Harmonic2 (2nd or 3rd) Analog Input 2.2 MHz @ –1 dBFS 15.5 MHz 31.0 MHz 69.0 MHz +25°C +25°C +25°C +25°C V I V V Worst Harmonic2 (4th or Higher) Analog Input 2.2 MHz @ –1 dBFS 15.5 MHz 31.0 MHz 69.0 MHz +25°C +25°C +25°C +25°C V I V V Multitone SFDR (w/Dither)3 Eight Tones @ –20 dBFS Full Parameter (Conditions) SNR Analog Input @ –1 dBFS SINAD Analog Input @ –1 dBFS Min AD6640AST Typ Max Units 68 67.7 67.5 66 dB dB dB dB 68 67.2 67.0 65.5 dB dB dB dB 80 80 79.5 78.5 dBc dBc dBc dBc 85 85 85 84 dBc dBc dBc dBc V 90 dBFS Full V 80 dBc +25°C V 300 MHz 64 63.5 74 74 4 Two-Tone IMD Rejection F1, F2 @ –7 dBFS 5 Analog Input Bandwidth NOTES 1 All ac specifications tested by driving ENCODE and ENCODE differentially. 2 For a single test tone at –1 dBFS, the worst case spectral performance is typically limited by the direct or aliased 2nd or 3rd harmonic. If a system is designed such that the 2nd and 3rd harmonics fall out-of-band, overall performance in the band of interest is typically improved by 5 dB. Worst Harmonic (4th or Higher) includes 4th and higher order harmonics and all other spurious components. Reference Figure 12 for more detail. 3 See Overcoming Static Nonlinearities with Dither section for details on improving SFDR performance. To measure SFDR, eight tones from 14 MHz to 18 MHz (0.5 MHz spacing) are swept from –20 dBFS to –90 dBFS. An open channel at 16 MHz is used to monitor SFDR. 4 F1 = 14.9 MHz, F2 = 16 MHz. 5 Specification is small signal bandwidth. Plots of Performance versus Analog Input Frequency are shown in Figures 10, 11 and 12. Sampling wide bandwidths (5 MHz–15 MHz) should be limited to 70 MHz center frequency. Specifications subject to change without notice. REV. 0 –3– AD6640 ABSOLUTE MAXIMUM RATINGS 1 Parameter Min ELECTRICAL AVCC Voltage DVCC Voltage Analog Input Voltage Analog Input Current Digital Input Voltage (ENCODE) Digital Output Current 0 0 0 0 –10 ENVIRONMENTAL2 Operating Temperature Range (Ambient) –40 Maximum Junction Temperature Lead Temperature (Soldering, 10 sec) Storage Temperature Range (Ambient) –65 Max 7 7 AVCC 25 AVCC 10 EXPLANATION OF TEST LEVELS Test Level Units I II V V V mA V mA – – III – IV – V – VI – +85 +150 +300 +150 °C °C °C °C 100% production tested. 100% production tested at +25°C, and sample tested at specified temperatures. AC testing done on sample basis. Sample tested only. Parameter is guaranteed by design and characterization testing. Parameter is a typical value only. All devices are 100% production tested at +25°C; sample tested at temperature extremes. NOTES 1 Absolute maximum ratings are limiting values to be applied individually, and beyond which the serviceability of the circuit may be impaired. Functional operability is not necessarily implied. Exposure to absolute maximum rating conditions for an extended period of time may affect device reliability. 2 Typical thermal impedances (44-terminal TQFP); θJA = 55°C/W. ORDERING GUIDE Model Temperature Range Package Description Package Option AD6640AST AD6640ST/PCB –40°C to +85°C (Ambient) 44-Terminal TQFP (Thin Quad Plastic Flatpack) Evaluation Board with AD6640AST ST-44 CAUTION ESD (electrostatic discharge) sensitive device. Electrostatic charges as high as 4000 V readily accumulate on the human body and test equipment and can discharge without detection. Although the AD6640 features proprietary ESD protection circuitry, permanent damage may occur on devices subjected to high energy electrostatic discharges. Therefore, proper ESD precautions are recommended to avoid performance degradation or loss of functionality. –4– WARNING! ESD SENSITIVE DEVICE REV. 0 AD6640 PIN FUNCTION DESCRIPTIONS Pin No. Name Function 1, 2, 36, 37, 40, 41 3 4 DVCC ENCODE ENCODE +3.3 V/+5 V Power Supply (Digital). Powers output stage only. Encode Input. Data conversion initiated on rising edge. Complement of ENCODE. Drive differentially with ENCODE or bypass to Ground for single-ended clock mode. See Encoding the AD6640 section. 5, 6, 13, 14, 17, 18, 21, 22, 24, 34, 35, 38, 39 7 8 9 GND AIN AIN VREF 10 11, 12, 15, 16, 19, 20 23 25 26–33 42, 43 44 C1 AVCC NC D0 (LSB) D1–D8 D9–D10 D11 (MSB)1 Ground. Analog Input. Complement of Analog Input. Internal Voltage Reference. Nominally +2.4 V. Bypass to Ground with 0.1 µF + 0.01 µF microwave chip capacitor. Internal Bias Point. Bypass to ground with 0.01 µF capacitor. +5 V Power Supply (Analog). No Connect. Digital Output Bit (Least Significant Bit). Digital Output Bits. Digital Output Bits. Digital Output Bit (Most Significant Bit). NOTE 1 Output coded as twos complement. GND GND DVCC DVCC GND DVCC GND DVCC D9 D11 (MSB) D10 PIN CONFIGURATION 44 43 42 41 40 39 38 37 36 35 34 33 D8 DVCC 1 DVCC 2 32 D7 PIN 1 ENCODE 3 31 D6 ENCODE 4 30 D5 GND 5 GND 6 AIN 7 AD6640 29 D4 TOP VIEW (Not to Scale) 28 D3 27 D2 26 D1 AIN 8 25 D0 (LSB) VREF 9 C1 10 24 GND AVCC 11 23 NC NC = NO CONNECT REV. 0 –5– GND GND AVCC GND AVCC GND 16 17 18 19 20 21 22 AVCC GND AVCC GND AVCC 12 13 14 15 AD6640 DEFINITION OF SPECIFICATIONS Analog Bandwidth (Small Signal) The analog input frequency at which the spectral power of the fundamental frequency (as determined by the FFT analysis) is reduced by 3 dB. Aperture Delay The delay between a differential crossing of ENCODE and ENCODE and the instant at which the analog input is sampled. Power Supply Rejection Ratio The ratio of a change in input offset voltage to a change in power supply voltage. Signal-to-Noise-and-Distortion (SINAD) The ratio of the rms signal amplitude (set at 1 dB below full scale) to the rms value of the sum of all other spectral components, including harmonics but excluding dc. Signal-to-Noise Ratio (SNR) Differential Nonlinearity The ratio of the rms signal amplitude (set at 1 dB below full scale) to the rms value of the sum of all other spectral components, excluding the first five harmonics and dc. The deviation of any code from an ideal 1 LSB step. Spurious-Free Dynamic Range (SFDR) Encode Pulsewidth/Duty Cycle The ratio of the rms signal amplitude to the rms value of the peak spurious spectral component. The peak spurious component may or may not be a harmonic. May be reported in dBc (i.e., degrades as signal levels is lowered), or in dBFS (always related back to converter full scale). Aperture Uncertainty (Jitter) The sample-to-sample variation in aperture delay. Pulsewidth high is the minimum amount of time that the ENCODE pulse should be left in logic “1” state to achieve rated performance; pulsewidth low is the minimum time ENCODE pulse should be left in low state. At a given clock rate, these specs define an acceptable Encode duty cycle. Integral Nonlinearity The deviation of the transfer function from a reference line measured in fractions of 1 LSB using a “best straight line” determined by a least square curve fit. Minimum Conversion Rate The encode rate at which the SNR of the lowest analog signal frequency drops by no more than 3 dB below the guaranteed limit. Maximum Conversion Rate The encode rate at which parametric testing is performed. Output Propagation Delay The delay between a differential crossing of ENCODE and ENCODE and the time when all output data bits are within valid logic levels. Two-Tone Intermodulation Distortion Rejection The ratio of the rms value of either input tone to the rms value of the worst third order intermodulation product; reported in dBc. Two-Tone SFDR The ratio of the rms value of either input tone to the rms value of the peak spurious component. The peak spurious component may or may not be an IMD product. May be reported in dBc (i.e., degrades as signal levels is lowered), or in dBFS (always related back to converter full scale). Worst Harmonic The ratio of the rms signal amplitude to the rms value of the worst harmonic component, reported in dBc. –6– REV. 0 Equivalent Circuits–AD6640 tA AIN N ANALOG INPUTS N+1 AIN ENCODE INPUTS (ENCODE) DIGITAL OUTPUTS (D11–D0) N–2 N–1 N tOD Figure 1. Timing Diagram VCH AVCC DVCC AIN CURRENT MIRROR T/H BUF 450V VCL VREF BUF VCH AVCC 450V DVCC AIN T/H BUF VREF D0–D11 VCL Figure 2. Analog Input Stage AVCC CURRENT MIRROR AVCC AVCC R1 17kV Figure 5. Digital Output Stage R1 17kV ENCODE ENCODE R2 8kV TIMING CIRCUITS R2 8kV AVCC AVCC 2.4V VREF Figure 3. Encode Inputs 0.5mA AVCC Figure 6. 2.4 V Reference VREF AVCC AVCC CURRENT MIRROR C1 Figure 4. Compensation Pin, C1 REV. 0 –7– AD6640–Typical Performance Characteristics ENCODE = 65MSPS AIN = 2.2MHz 40 60 2 3 4 5 6 7 8 ENCODE = 65MSPS TEMP = –40 C, +25 C, & +85 C 81 20 WORST CASE HARMONIC – dBc POWER RELATIVE TO ADC FULL SCALE – dB 0 9 80 100 80 T = +25 C 79 T = –40 C, +85 C 78 77 120 dc 6.5 13.0 19.5 FREQUENCY – MHz 0 32.5 26.0 14 63 70 0 ENCODE = 65MSPS AIN = 15.5MHz ENCODE = 65MSPS TEMP = –40 C, +25 C, & +85 C 69 20 68 40 60 4 8 9 5 3 7 6 2 T = –40 C T = +25 C 67 T = +85 C 80 66 100 65 120 dc 6.5 13.0 19.5 FREQUENCY – MHz 0 32.5 26.0 14 7 21 28 35 42 49 56 ANALOG INPUT FREQUENCY – MHz 90 0 WORST OTHER SPUR ENCODE = 65MSPS AIN = 31.0MHz 80 SNR, HARMONICS – dB, dBc 20 40 60 2 4 6 8 9 7 5 63 70 Figure 11. Noise vs. AIN Figure 8. Single Tone at 15.5 MHz POWER RELATIVE TO ADC FULL SCALE – dB 21 28 35 42 49 56 ANALOG INPUT FREQUENCY – MHz Figure 10. Harmonics vs. AIN SNR – dB POWER RELATIVE TO ADC FULL SCALE – dB Figure 7. Single Tone at 2.2 MHz 7 3 80 100 ENCODE = 65MSPS HARMONICS (2nd, 3rd) 70 SNR 60 50 40 120 30 dc 6.5 13.0 19.5 FREQUENCY – MHz 26.0 32.5 Figure 9. Single Tone at 31.0 MHz 1 2 10 100 4 20 40 ANALOG INPUT FREQUENCY – MHz 200 300 Figure 12. Harmonics, Noise vs. AIN –8– REV. 0 85 0 AIN = 19.5MHz ENCODE = 65MSPS AIN = 15.0, 16.0MHz NO DITHER 20 SNR, WORST CASE SPURIOUS – dB, dBc POWER RELATIVE TO ADC FULL SCALE – dB AD6640 40 60 80 100 dc 6.5 13.0 19.5 FREQUENCY – MHz 26.0 32.5 SNR, WORST FULL SCALE SPURIOUS – dB, dBc WORST CASE SPURIOUS – dBc and dBFS 100 dBFS 80 70 60 ENCODE = 65MSPS AIN = 31.0MHz 50 40 dBc SFDR = 80dB REFERENCE LINE 30 20 10 0 –80 –70 –60 –50 –40 –30 –20 –10 ANALOG INPUT POWER LEVEL – dBFS 0 Figure 14. Single Tone SFDR SNR, WORST FULL SCALE SPURIOUS – dB, dBc WORST CASE SPURIOUS – dBc and dBFS 90 dBFS 80 70 50 ENCODE = 65MSPS F1 = 15.0MHz F2 = 16.0MHz dBc SFDR = 80dB REFERENCE LINE 40 30 20 10 0 –80 –70 –60 –50 –40 –30 –20 –10 INPUT POWER LEVEL (F1 = F2) – dBFS 0 Figure 15. Two Tone SFDR REV. 0 SNR 65 8 16 24 32 40 48 56 SAMPLE RATE – MSPS 64 72 80 90 ENCODE = 65MSPS AIN = 2.2MHz 85 80 WORST SPUR 75 70 SNR 65 60 55 50 45 40 35 30 25 35 30 40 45 50 55 60 65 ENCODE DUTY CYCLE – % 70 75 Figure 17. SNR, Worst Spurious vs. Duty Cycle 100 60 70 Figure 16. SNR, Worst Spurious vs. Encode Figure 13. Two Tones at 15.0 MHz & 16.0 MHz 90 75 60 dc 120 WORST SPUR 80 90 85 2.2MHz WORST SPUR ENCODE = 65MSPS 80 69MHz 75 70 2.2MHz 65 60 SNR 69MHz 55 50 45 40 35 30 –15 –12 –9 –6 –3 0 3 6 ENCODE POWER – dBm 9 12 15 Figure 18. SNR, Worst Spurious vs. Encode Power –9– 0 POWER RELATIVE TO ADC FULL SCALE – dB POWER RELATIVE TO ADC FULL SCALE – dB AD6640 ENCODE = 65MSPS AIN = 19.5MHz @ –36dBFS NO DITHER –20 –40 –60 –80 –100 –120 dc 65 13.0 19.5 FREQUENCY – MHz 26.0 0 ENCODE = 65MSPS AIN = 19.5MHz @ –36dBFS DITHER = –32.5dBm –20 –40 –60 –80 –100 –120 dc 32.5 65 Figure 19. 16K FFT without Dither 32.5 100 90 90 ENCODE = 65MSPS AIN = 19.5MHz NO DITHER 80 WORST CASE SPURIOUS – dBc WORST CASE SPURIOUS – dBc 26.0 Figure 22. 16K FFT with Dither 100 70 60 50 40 30 20 SFDR = 80dB REFERENCE LINE 10 0 –80 –70 70 60 50 40 30 20 –60 –50 –40 –30 –20 –10 ANALOG INPUT POWER LEVEL – dBFS 0 –80 0 POWER RELATIVE TO ADC FULL SCALE – dB 0 –30 ALIASED SIGNALS –60 –60 ANALOG IF FILTER MASK –80 –90 –100 –120 50 55 60 65 FREQUENCY – MHz 70 –70 0 –60 –50 –40 –30 –20 –10 ANALOG INPUT POWER LEVEL – dBFS Figure 23. SFDR with Dither ENCODE = 50MSPS AIN = 65.5, 68.5MHz NO DITHER –40 SFDR = 80dB REFERENCE LINE 10 0 –20 ENCODE = 65MSPS AIN = 19.5MHz DITHER = –32.5dBm 80 Figure 20. SFDR without Dither POWER RELATIVE TO ADC FULL SCALE – dB 13.0 19.5 FREQUENCY – MHz –120 75 0 –20 –30 –40 ALIASED SIGNALS –60 –60 ANALOG IF FILTER MASK –80 –90 –100 –120 Figure 21. IF-Sampling at 70 MHz without Dither 0 ENCODE = 50MSPS AIN = 65.5MHz, 68.5MHz DITHER = –32.5dBm 50 55 60 65 FREQUENCY – MHz 70 –120 75 Figure 24. IF-Sampling at 70 MHz with Dither –10– REV. 0 AD6640 THEORY OF OPERATION The AD6640 analog-to-digital converter (ADC) employs a twostage subrange architecture. This design approach ensures 12-bit accuracy, without the need for laser trim, at low power. ENCODE SOURCE Vl RX 0.01mF As shown in the functional block diagram, the AD6640 has complementary analog input pins, AIN and AIN. Each analog input is centered at 2.4 volts and should swing ± 0.5 volts around this reference (ref. Figure 2). Since AIN and AIN are 180 degrees out of phase, the differential analog input signal is 2 volts peak-to-peak. +5V R1 ENCODE R2 AD6640 Figure 26. Lower Logic Threshold for Encode Vl = Both analog inputs are buffered prior to the first track-and-hold, TH1. The high state of the ENCODE pulse places TH1 in hold mode. The held value of TH1 is applied to the input of a 6-bit coarse ADC. The digital output of the coarse ADC drives a 6-bit DAC; the DAC is 12 bits accurate. The output of the 6bit DAC is subtracted from the delayed analog signal at the input of TH3 to generate a residue signal. TH2 is used as an analog pipeline to null out the digital delay of the coarse ADC. 5R2 R1RX R2 + R1+ RX to raise logic threshold. AVCC RX +5V ENCODE SOURCE ENCODE ENCODE Vl The 6-bit coarse ADC word and 7-bit residue word are added together and corrected in the digital error correction logic to generate the output word. The result is a 12-bit parallel digital CMOS-compatible word, coded as twos complement. 0.01mF AD6640 R1 R2 Figure 27. Raise Logic Threshold for Encode APPLYING THE AD6640 Encoding the AD6640 Best performance is obtained by driving the encode pins differentially. However, the AD6640 is also designed to interface with TTL and CMOS logic families. The source used to drive the ENCODE pin(s) must be clean and free from jitter. Sources with excessive jitter will limit SNR (reference Equation 1 under “Noise Floor and SNR”). While the single-ended encode will work well for many applications, driving the encode differentially will provide increased performance. Depending on circuit layout and system noise, a 1 dB to 3 dB improvement in SNR can be realized. It is not recommended that differential TTL logic be used however, because most TTL families that support complementary outputs are not delay or slew rate matched. Instead, it is recommended that the encode signal be ac-coupled into the ENCODE and ENCODE pins. The simplest option is shown below. The low jitter TTL signal is coupled with a limiting resistor, typically 100 ohms, to the primary side of an RF transformer (these transformers are inexpensive and readily available; part number in Figure 28 is from Mini-Circuits). The secondary side is connected to the ENCODE and ENCODE pins of the converter. Since both encode inputs are self-biased, no additional components are required. AD6640 TTL OR CMOS SOURCE ENCODE ENCODE ENCODE 0.01mF Figure 25. Single-Ended TTL /CMOS Encode The AD6640 encode inputs are connected to a differential input stage (see Figure 3 under EQUIVALENT CIRCUITS). With no input signal connected to either ENCODE pin, the voltage dividers bias the inputs to 1.6 volts. For TTL or CMOS usage, the encode source should be connected to ENCODE, Pin 3. ENCODE should be decoupled using a low inductance or microwave chip capacitor to ground. If a logic threshold other than the nominal 1.6 V is required, the following equations show how to use an external resistor, Rx, to raise or lower the trip point (see Figure 3; R1 = 17 kΩ, R2 = 8 kΩ). Vl = REV. 0 5R2Rx to lower logic threshold. R1R2 + R1Rx + R2Rx 100V TTL 0.1mF T1–1T ENCODE AD6640 ENCODE Figure 28. TTL Source – Differential Encode A clean sine wave may be substituted for a TTL clock. In this case, the matching network is shown below. Select a transformer ratio to match source and load impedances. The input impedance of the AD6640 encode is approximately 11 kΩ differentially. Therefore “R,” shown in the Figure 29, may be any value that is convenient for available drive power. –11– AD6640 T1–1T SINE SOURCE ENCODE AD6640 R ENCODE Figure 29. Sine Source – Differential Encode If a low jitter ECL clock is available, another option is to accouple a differential ECL signal to the encode input pins as shown below. The capacitors shown here should be chip capacitors but do not need to be of the low inductance variety. 0.1mF ENCODE ECL GATE AD6640 0.1mF ENCODE 510V To take full advantage of this high input impedance, a 20:1 transformer would be required. This is a large ratio and could result in unsatisfactory performance. In this case, a lower step-up ratio could be used. For example, if RT were set to 260 ohms, along with a 4:1 transformer, the input would match to a 50 ohm source with a full-scale drive of +4 dBm (Figure 33). Note that the external load resistor, RT, is in parallel with the AD6640 analog input resistance of 900 ohms. The external resistor value can be calculated from the following equation: RT = 1 1 1 – Z 900 where Z is the desired impedance (200 Ω for a 4:1 transformer with 50 Ω input source). 1:4 510V ANALOG INPUT SIGNAL –VS AIN RT AD6640 AIN Figure 30. Differential ECL for Encode VREF As a final alternative, the ECL gate may be replaced by an ECL comparator. The input to the comparator could then be a logic signal or a sine signal. 0.1mF 0.01mF Figure 33. Transformer-Coupled Analog Input Signal AD96687 (1/2) 0.1mF ENCODE AD6640 0.1mF 50V ENCODE 510V 510V If the lower drive power is attractive, a combination transformer match and LC match could be employed that would use a 4:1 transformer with an LC as shown in Figure 34. This solution is useful when good performance in the third Nyquist zone is required. Such a requirement arises when digitizing high intermediate frequencies in communications receivers. –VS Figure 31. ECL Comparator for Encode ANALOG SIGNAL AT –3dBm Driving the Analog Input Because the AD6640 operates from a single +5 volt supply, the analog input voltage range is offset from ground by 2.4 volt. Each analog input connects through a 450 ohm resistor to the 2.4 volt bias voltage and to the input of a differential buffer (Figure 32). This resistor network on the input properly biases the followers for maximum linearity and range. Therefore, the analog source driving the AD6640 should be ac-coupled to the input pins. Since the differential input impedance of the AD6640 is 0.9 kΩ, the analog input power requirement is only –3 dBm, simplifying the drive amplifier in many cases. BUF AIN AD6640 450V BUF 450V AIN VREF 0.1mF BUF +2.4V REFERENCE 0.01mF Figure 32. Differential Analog Inputs +j100V 1:4 AIN AD6640 –j125V AIN VREF 0.1mF 0.01mF Figure 34. Low Power Drive Circuit In applications where gain is needed but dc-coupling is not necessary, an extension of Figure 34 is recommended. A 50 ohm gain block may be placed in front of the LC matching network. Such gain blocks are readily available for commercial applications. These low cost modules can have excellent NF and intermodulation performance. This circuit is especially good for the “IF” receiver application previously mentioned. In applications where dc-coupling is required the following circuit can be used (Figure 35). It should be noted that the addition of circuitry for dc-coupling may compromise performance in terms of noise, offset and dynamic performance. This circuit requires an inverting and noninverting signal path. Additionally, an offset must be generated so that the analog input to each pin is centered near 2.4 volts. Since the input is differential, small differences in the dc voltage at each input can translate into an offset for the circuit. The same holds true for gain mismatch. Therefore, some means of adjusting the gain and offset between –12– REV. 0 AD6640 the device. A full-scale transition can cause up to 120 mA (12 bits × 10 mA/bit) of current to flow through the digital output stages. The series resistor will minimize the output currents that can flow in the output stage. These switching currents are confined between ground and the DVCC pin. Standard TTL gates should be avoided since they can appreciably add to the dynamic switching currents of the AD6640. the sides should be implemented. The addition of small value resistors between the AD9631 and the AD6640 will prevent oscillation due to the capacitive input of the ADC. SIGNAL SOURCE AD9631 62V 15V AIN 467V 78V 350V OP279 (1/2) Layout Information AD6640 1000V OP279 (1/2) The schematic of the evaluation board (Figure 36) represents a typical implementation of the AD6640. The pinout of the AD6640 facilitates ease of use and the implementation of high frequency/high resolution design practices. All of the digital outputs are on one side while the other sides contain all of the inputs. It is highly recommended that high quality ceramic chip capacitors be used to decouple each supply pin to ground directly at the device. Depending on the configuration used for the encode and analog inputs, one or more capacitors are required on those input pins. The capacitors used on the ENCODE and VREF pins must be a low inductance chip capacitor as referenced previously in the data sheet. VREF 750V 0.1mF 0.01mF 0.1mF 425V 350V 350V 467V 15V AIN 127V AD9631 Figure 35. DC-Coupled Analog Input Circuit Power Supplies Care should be taken when selecting a power source. Linear supplies are strongly recommended as switching supplies tend to have radiated components that may be “received” by the AD6640. Each of the power supply pins should be decoupled as closely to the package as possible using 0.1 µF chip capacitors. The AD6640 has separate digital and analog +5 V pins. The analog supplies are denoted AVCC and the digital supply pins are denoted DVCC. Although analog and digital supplies may be tied together, best performance is achieved when the supplies are separate. This is because the fast digital output swings can couple switching noise back into the analog supplies. Note that AVCC must be held within 5% of 5 volts; however the DVCC supply may be varied according to output digital logic family (i.e., DVCC should be connected to the same supply as the digital circuitry). The AD6640 is specified for DVCC = 3.3 V as this is a common supply for digital ASICs. Evaluation Boards The evaluation board for the AD6640 is very straightforward, consisting of power, signal inputs and digital outputs. The evaluation board includes the option for an onboard clock oscillator for the encode. Power to the analog supply pins is connected via banana jacks. The analog supply powers the crystal oscillator and the AVCC pins of the AD6640. Output Loading Care must be taken when designing the data receivers for the AD6640. It is recommended that the digital outputs drive a series resistor (e.g. 348 ohms) followed by a gate like the 74LCX574. To minimize capacitive loading, there should only be one gate on each output pin. An example of this is shown in the evaluation board schematic shown in Figure 36. The digital outputs of the AD6640 have a constant rise time output stage. The output slew rate is about 1 V/ns when DVCC = +5 V. A typical CMOS gate combined with PCB trace and through hole will have a load of approximately 10 pF. Therefore as each bit switches, 10 mA 1V 10 pF × 1ns of dynamic current per bit will flow in or out of A multilayer board is recommended to achieve best results. Care should be taken when placing the digital output runs. Because the digital outputs have such a high slew rate, the capacitive loading on the digital outputs should be minimized. Circuit traces for the digital outputs should be kept short and connect directly to the receiving gate (broken only by the insertion of the series resistor). Digital data lines should be kept clear of analog and encode traces. The DVCC power is supplied via J3, the digital interface. This digital supply connection also powers the digital gates on the PCB. By maintaining separate analog and digital power supplies, degradation in SNR and SFDR is kept to a minimum. Total power requirement is approximately 200 mA. This configuration allows for easy evaluation of different logic families (i.e., connection to a 3.3 volt logic board). The analog input is connected via J2 and is transformer-coupled to the AD6640 (see Driving the Analog Input). The onboard termination resistor is 270 Ω. This resistor, in parallel with the AD6640’s input resistance (900 Ω), provides a 50 Ω load to the analog source driving the 1:4 transformer. If a different input impedance is required, replace R16 by using the following equation R16 = 1 1 1 − Z 900 where Z is desired input impedance (200 Ω for a 4:1 transformer with 50 Ω source). REV. 0 –13– AD6640 The analog input range of the PCB is ± 0.5 volts (i.e., signal accoupled to AD6640). The encode signal may be generated using an onboard crystal oscillator, U1. The oscillator is socketed and may be replaced by an external encode source via J1. If an external source is used, it should be a high quality TTL source. A transformer converts the single-ended TTL signal to a differential clock (see Encoding the AD6640). Since the encode is coupled with a transformer, a sine wave could have been used; note, however, that U5 requires TTL levels to function properly. AD6640 output data is latched using 74LCX574 (U3, U4) latches following 348 ohm series resistors. The resistors limit the current that would otherwise flow due to the digital output slew rate. The resistor value was chosen to represent a time constant of ~25% of the data rate at 65 MHz. This reduces slew rate while not appreciably distorting the data waveform. Data is latched in a pipeline configuration; a rising edge generates the new AD6640 data sample, latches the previous data at the converter output, and strobes the external data register over J3. NOTE: Power and ground must be applied to J3 to power the digital logic section of the evaluation board. Table I. AD6640ST/PCB Bill of Material Item 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 Quantity 2 11 2 1 3 1 25 1 1 2 1 1 2 1 1 2 2 Reference +5 VA, GND C7–C9, C11–C17, C19 C4, C6 J3 J1, J2, J4 R1 R2–R14, R20–R25, R30–R35 R15 R16 T1, T2 U1 DUT U3, U4 U5 C1, C18 C2, C3 CR1, CR2 Description Banana Jack Ceramic Chip Capacitor 0805, 0.1 µF Tantalum Chip Capacitor 10 µF 40-Pin Double Row Male Header BNC Coaxial PCB Connector Surface Mount Resistor 1206, 348 Ω Surface Mount Resistor 1206, 348 Ω Surface Mount Resistor 1206, 100 Ω Surface Mount Resistor 1206, 270 Ω Surface Mount Transformer Mini-Circuits T4–1T, 1:4 Ratio Clock Oscillator (Optional) AD6640AST 12-Bit–65 MSPS ADC Converter 74LCX574 Octal Latch 74LVQ00 Quad Two Input NAND Gate Ceramic Chip Capacitor 0508, 0.01 µF Low Inductance Ceramic Chip Capacitor 0508, 0.1 µF Low Inductance 1N2810 Schottky Diode –14– REV. 0 AD6640 348V +5VA 74LCX574 U5 74LVQ00 348V (DVCC) 9 (+5VA) 1 4 5 3 2 6 8 BUFLAT 7 348V 0.1mF 6 348V J4 5 348V 4 3 E1 ENCODE INPUT 2 348V 2 1 GND GND DVCC GND DVCC GND D9 D8 33 D7 32 3 ENCODE D6 31 ENCODE 5 GND D5 30 D2 14 15 16 17 18 19 20 21 22 +5V ANALOG SUPPLY 348V 9 8 7 5 3 2 C11 0.1mF C12 0.1mF C4 10mF C8 0.1mF C9 0.1mF C17 0.1mF C13 0.1mF C15 0.1mF 2Q 1D 1Q 17 348V –15– B07 B08 B09 B10 B11 18 19 DVCC (+3.3V OR +5.0V) 1 J3 40 GND 39 2 GND B11 38 B10 3 GND 37 B09 4 GND 36 B08 5 GND 35 6 B07 GND 34 B06 7 GND 33 B05 8 GND 9 32 B04 GND 10 31 GND 11 30 GND 12 29 B03 GND 28 GND B02 13 14 27 B01 GND 26 GND B00 15 25 GND GND 16 24 GND GND 17 18 23 GND GND 22 GND 19 GND 20 21 GND GND OE 1 8D 8Q 7D 7Q 6D 6Q 5D 5Q 4D 4Q 3D 3Q 2D 2Q 1D 1Q 11 Figure 36. AD6640ST/PCB Schematic REV. 0 2D CK C16 0.1mF +5VA + 3Q B06 (DVCC) 6 348V C7 0.1mF 3D 16 348V U4 348V C6 10mF 4Q 15 348V 74LCX574 348V NC = NO CONNECT +5VA + 4D 11 4 DVCC 5Q 348V +5VA GND 5D 14 348V BUFLAT 348V COMMON 6Q DVCC GND AVCC AVCC GND 24 NC 23 AVCC C1 AVCC GND 10 AVCC D1 26 (LSB) D0 25 AVCC VREF GND 9 12 13 6D 13 348V 27 AIN 0.1mF 7Q 12 348V TWO COMPLEMENT BUFFERED OUTPUTS D4 29 D3 28 DUT AD6640 8 0.01mF 7D CK 348V DVCC 11 8Q 34 DVCC GND 270V 1:4 0.1mF 35 2 GND 7 AIN 1 6 36 1 6 2 37 GND T4–1T 3 4 J2 38 4 1:4 ANALOG INPUT 39 GND 6 DVCC T4–1T 3 4 41 40 DVCC D11 DVCC 100V 43 42 D10 44 E2 J1 0.01mF 348V DVCC 8D OE 1 12 348V 13 348V 14 348V 15 348V 16 348V 17 348V 18 19 B00 B01 B02 B03 B04 B05 AD6640 Figure 37. AD6640ST/PCB Top Side Silkscreen Figure 39. AD6640ST/PCB Top Side Copper Figure 38. AD6640ST/PCB Bottom Side Silkscreen Figure 40. AD6640ST/PCB Bottom Side Copper (Positive) NOTE: Evaluation boards are often updated, consult factory for latest version. –16– REV. 0 AD6640 Figure 41. AD6640ST/PCB Ground Layer (Negative) REV. 0 Figure 42. AD6640ST/PCB “Split” Power Layer (Negative) –17– AD6640 is used for demodulation, different routines may be used to demodulate different standards such as AM, FM, GMSK or any other desired standard. In addition, as new standards arise or new software revisions are generated, they may be field installed with standard software update channels. A radio that performs demodulation in software as opposed to hardware is often referred to as a soft radio because it may be changed or modified simply through code revision. DIGITAL WIDEBAND RECEIVERS Introduction Several key technologies are now being introduced that may forever alter the vision of radio. Figure 43 shows the typical dual conversion superheterodyne receiver. The signal picked up by the antenna is mixed down to an intermediate frequency (IF) using a mixer with a variable local oscillator (LO); the variable LO is used to “tune-in” the desired signal. This first IF is mixed down to a second IF using another mixer stage and a fixed LO. Demodulation takes place at the second or third IF using either analog or digital techniques. NARROWBAND FILTER LNA IF1 RF e.g. 900MHz VARIABLE SHARED System Description In the wideband digital radio (Figure 44), the first down conversion functions in much the same way as a block converter does. An entire band is shifted in frequency to the desired intermediate frequency. In the case of cellular base station receivers, 5 MHz to 30 MHz of bandwidth are down-converted simultaneously to an IF frequency suitable for digitizing with a wideband analog-to-digital converter. Once digitized the broadband digital data stream contains all of the in-band signals. The remainder of the radio is constructed digitally using special purpose and general purpose programmable DSP to perform filtering, demodulation and signal conditioning not unlike the analog counter parts. ADCs NARROWBAND FILTER I Q IF2 FIXED ONE RECEIVER PER CHANNEL Figure 43. Narrowband Digital Receiver Architecture If demodulation takes place in the analog domain then traditional discriminators, envelop detectors, phase locked loops or other synchronous detectors are generally employed to strip the modulation from the selected carrier. In the narrowband receiver (Figure 43), the signal to be received must be tuned. This is accomplished by using a variable local oscillator at the first mix down stage. The first IF then uses a narrow band filter to reject out of band signals and condition the selected carrier for signal demodulation. However, as general purpose DSP chips such as the ADSP-2181 become more popular, they will be used in many basebandsampled applications like the one shown in Figure 43. As shown in the figure, prior to ADC conversion, the signal must be mixed down, filtered, and the I and Q components separated. These functions are realizable through DSP techniques, however several key technology breakthroughs are required: high dynamic range ADCs such as the AD6640, new DSPs (highly programmable with onboard memory, fast), digital tuners and filters such as the AD6620, wide band mixers and amplifiers. LNA WIDEBAND MIXER WIDEBAND FILTER WIDEBAND ADC In the digital wideband receiver (Figure 44), the variable local oscillator has been replaced with a fixed oscillator, so tuning must be accomplished in another manner. Tuning is performed digitally using a digital down conversion and filter chip frequently called a channelizer. The term channelizer is used because the purpose of these chips is to select one channel out of many within the broadband spectrum present in the digital data stream of the ADC. COS DIGITAL TUNER/FILTER DSP DATA 12.5MHz (416 CHANNELS) SHARED CHANNEL SELECTION Figure 44. Wideband Digital Receiver Architecture Figure 44 shows such a wideband system. This design shows that the front end variable local oscillator has been replaced with a fixed oscillator and the back end has been replaced with a wide dynamic range ADC, digital tuner and DSP. This technique offers many benefits. First, many passive discrete components have been eliminated that formed the tuning and filtering functions. These passive components often require “tweaking” and special handling during assembly and final system alignment. Digital components require no such adjustments; tuner and filter characteristics are always exactly the same. Moreover, the tuning and filtering characteristics can be changed through software. Since software I DECIMATION FILTER LOW-PASS FILTER Q DIGITAL TUNER Figure 45. AD6620 Digital Channelizer DIGITAL TUNER/FILTER DSP FIXED LOW-PASS FILTER SIN "n" CHANNELS TO DSP RF e.g. 900MHz DECIMATION FILTER Figure 45 shows the block diagram of a typical channelizer, such as the AD6620. Channelizers consist of a complex NCO (Numerically Controlled Oscillator), dual multiplier (mixer), and matched digital filters. These are the same functions that would be required in an analog receiver, however implemented in digital form. The digital output from the channelizer is the desired carrier, frequently in I & Q format; all other signals have been filtered and removed based on the filtering characteristics desired. Since the channelizer output consists of one selected RF channel, one tuner chip is required for each frequency received, although only one wideband RF receiver is needed for the entire band. Data from the channelizer may then be processed using a digital signal processor such as the ADSP-2181 or the SHARC® processor, the ADSP-21062. This data may then be processed through software to demodulate the information from the carrier. SHARC is a registered trademark of Analog Devices, Inc. –18– REV. 0 AD6640 +5V (A) PRESELECT FILTER +3.3V (D) 5–15MHz PASSBAND LNA AIN LO DRIVE AD6620 (REF. FIG 45) CMOS BUFFER ADSP-2181 348V D11 AIN I&Q DATA 12 AD6640 1900MHz NETWORK CONTROLLER INTERFACE ENCODE M/N PLL SYNTHESIZER REF IN ENCODE D0 CLK 65.00MHz REFERENCE CLOCK Figure 46. Simplified Wideband PCS Receiver System Requirements power dissipation is not a function of sample rate. Thus there is no penalty paid in power by operating at faster sample rates. All of this is good because, by carefully selecting input frequency range and sample rate, some of the drive amplifier and ADC harmonics can actually be placed out-of-band. Figure 46 shows a typical wideband receiver subsystem based around the AD6640. This strip consists of a wideband IF filter, amplifier, ADC, latches, channelizer and interface to a digital signal processor. This design shows a typical clocking scheme used in many receiver designs. All timing within the system is referenced back to a single clock. While this is not necessary, it does facilitate PLL design, ease of manufacturing, system test, and calibration. Keeping in mind that the overall performance goal is to maintain the best possible dynamic range, many considerations must be made. One of the biggest challenges is selecting the amplifier used to drive the AD6640. Since this is a communications application, it is common to directly sample an intermediate frequency (IF) signal. As such, IF gain blocks can be implemented instead of baseband op amps. For these gain block amplifiers, the critical specifications are third order intercept point and noise figure. A bandpass filter will remove harmonics generated within the amplifier, but intermods should be better than the performance of the A/D converter. In the case of the AD6640, amplifier intermods must be better than –80 dBFS when driving fullscale power. As mentioned earlier, there are several amplifiers to choose from and the specifications depend on the end application. Figure 47 shows a typical multitone test. POWER RELATIVE TO ADC FULL SCALE – dB 0 –20 ENCODE = 65MSPS –40 –60 –80 –100 –120 dc 6.5 13.0 19.5 FREQUENCY – MHz 26.0 32.5 Figure 47. Multitone Performance Two other key considerations for the digital wideband receiver are converter sample rate and IF frequency range. Since performance of the AD6640 converter is largely independent of both sample rate and analog input frequency (Figures 10, 11 and 16), the designer has greater flexibility in the selection of these parameters. Also, since the AD6640 is a bipolar device, REV. 0 For example, if the system has second and third harmonics that are unacceptably high, by carefully selecting the encode rate and signal bandwidth, these second and third harmonics can be placed out-of-band. For the case of an encode rate equal to 60 MSPS and a signal bandwidth of 7.5 MHz, placing the fundamental at 7.5 MHz places the second and third harmonics out of band as shown in the table below. Table II. Encode Rate Fundamental Second Harmonic Third Harmonic 60 MSPS 7.5 MHz–15 MHz 15 MHz–30 MHz 22.5 MHz–30 MHz, 30 MHz–15 MHz Another option can be found through bandpass sampling. If the analog input signal range is from dc to FS/2, then the amplifier and filter combination must perform to the specification required. However, if the signal is placed in the third Nyquist zone (FS to 3 FS/2), the amplifier is no longer required to meet the harmonic performance required by the system specifications since all harmonics would fall outside the passband filter. For example, the passband filter would range from FS to 3 FS/2. The second harmonic would span from 2 FS to 3 FS, well outside the passband filter’s range. The burden then has been passed off to the filter design provided that the ADC meets the basic specifications at the frequency of interest. In many applications, this is a worthwhile tradeoff since many complex filters can easily be realized using SAW and LCR techniques alike at these relatively high IF frequencies. Although harmonic performance of the drive amplifier is relaxed by this technique, intermodulation performance cannot be sacrificed since intermods must be assumed to fall in-band for both amplifiers and converters. Noise Floor and SNR Oversampling is sampling at a rate that is greater than twice the bandwidth of the signal desired. Oversampling does not have anything to do with the actual frequency of the sampled signal, it is the bandwidth of the signal that is key. Bandpass or “IF” sampling refers to sampling a frequency that is higher than Nyquist and often provides additional benefits such as down conversion using the ADC and replacing a mixer with a trackand-hold. Oversampling leads to processing gains because the –19– AD6640 faster the signal is digitized, the wider the distribution of noise. Since the integrated noise must remain constant, the actual noise floor is lowered by 3 dB each time the sample rate is doubled. The effective noise density for an ADC may be calculated by the equation: V NOISE rms / Hz = 10 − SNR /20 4 FS For a typical SNR of 68 dB and a sample rate of 65 MSPS, this is equivalent to 25 nV/√Hz. This equation shows the relationship between SNR of the converter and the sample rate FS. This equation may be used for computational purposes to determine overall receiver noise. The signal-to-noise ratio (SNR) for an ADC can be predicted. When normalized to ADC codes, the following equation accurately predicts the SNR based on three terms. These are jitter, average DNL error and thermal noise. Each of these terms contributes to the noise within the converter. Equation 1: SNR = –20 log 2 πFANALOG t J rms ( FANALOG t J rms ε VNOISE rms 1/2 ) 2 2 2 1+ ε VNOISE rms + + 212 212 = analog input frequency = rms jitter of the encode (rms sum of encode source and internal encode circuitry) = average DNL of the ADC (typically 0.51 LSB) = V rms thermal noise referred to the analog input of the ADC (typically 0.707 LSB) Processing Gain Processing gain is the improvement in signal-to-noise ratio (SNR) gained through oversampling and digital filtering. Most of this processing gain is accomplished using the channelizer chips. These special purpose DSP chips not only provide channel selection and filtering but also provide a data rate reduction. The required rate reduction is accomplished through a process called decimation. The term decimation rate is used to indicate the ratio of input data rate to output data rate. For example, if the input data rate is 65 MSPS and the output data rate is 1.25 MSPS, then the decimation rate is 52. Large processing gains may be achieved in the decimation and filtering process. The purpose of the channelizer, beyond tuning, is to provide the narrowband filtering and selectivity that traditionally has been provided by the ceramic or crystal filters of a narrowband receiver. This narrowband filtering is the source of the processing gain associated with a wideband receiver and is simply the ratio of the passband to whole band expressed in dB. For example, if a 30 kHz AMPS signal is being digitized with an AD6640 sampling at 65 MSPS, the ratio would be 0.015 MHz/32.5 MHz. Expressed in log form, the processing gain is –10 × log (0.015 MHz/32.5 MHz) or 33.4 dB. Overcoming Static Nonlinearities with Dither Typically, high resolution data converters use multistage techniques to achieve high bit resolution without large comparator arrays that would be required if traditional “flash” ADC techniques were employed. The multistage converter typically provides better wafer yields meaning lower cost and much lower power. However, since it is a multistage device, certain portions of the circuit are used repetitively as the analog input sweeps from one end of the converter range to the other. Although the worst DNL error may be less than an LSB, the repetitive nature of the transfer function can play havoc with low level dynamic signals. Spurious signals for a full-scale input may be –80 dBc. However at 36 dB below full scale, these repetitive DNL errors may cause spurious-free dynamic range (SFDR) to fall below 80 dBFS as shown in Figure 20. A common technique for randomizing and reducing the effects of repetitive static linearity is through the use of dither. The purpose of dither is to force the repetitive nature of static linearity to appear as if it were random. Then, the average linearity over the range of dither will dominate SFDR performance. In the AD6640, the repetitive cycle is every 15.625 mV p-p. To ensure adequate randomization, 5.3 mV rms is required; this equates to a total dither power of –32.5 dBm. This will randomize the DNL errors over the complete range of the residue converter. Although lower levels of dither such as that from previous analog stages will reduce some of the linearity errors, the full effect will only be gained with this larger dither. Increasing dither even more may be used to reduce some of the global INL errors. However, signals much larger than the mVs proposed here begin to reduce the usable dynamic range of the converter. Even with the 5.3 mV rms of noise suggested, SNR would be limited to 36 dB if injected as broadband noise. To avoid this problem, noise may be injected as an out-of-band signal. Typically, this may be around dc but may just as well be at FS/2 or at some other frequency not used by the receiver. The bandwidth of the noise is several hundred kilohertz. By band-limiting and controlling its location in frequency, large levels of dither may be introduced into the receiver without seriously disrupting receiver performance. The result can be a marked improvement in the SFDR of the data converter. Figure 23 shows the same converter shown earlier but with this injection of dither (reference Figure 20). +15V 16kV LOW CONTROL (0–1 VOLT) 1mF NC202 NOISE DIODE (NoiseCom) A 2.2kV +5V REF 2kV –5V 1kV A OP27 Additional filtering and noise reduction techniques can be achieved through DSP techniques; many applications do use additional process gains through proprietary noise reduction algorithms. 0.1mF 39V AD600 OPTIONAL HIGH POWER DRIVE CIRCUIT 390V Figure 48. Noise Source (Dither Generator) –20– REV. 0 AD6640 The simplest method for generating dither is through the use of a noise diode (Figure 48). In this circuit, the noise diode NC202 generates the reference noise that is gained up and driven by the AD600 and OP27 amplifier chain. The level of noise may be controlled by either presetting the control voltage when the system is set up, or by using a digital-to-analog converter (DAC) to adjust the noise level based on input signal conditions. Once generated, the signal must be introduced to the receiver strip. The easiest method is to inject the signal into the drive chain after the last down conversion as shown in Figure 49. IF AMP BPF FROM RF/IF AIN COMBINER AIN NOISE SOURCE LPF AD6640 (REF. FIGURE 48) VREF 0.1mF 0.01mF Figure 49. Using the AD6640 with Dither Receiver Example To determine how the ADC performance relates to overall receiver sensitivity, the simple receiver in Figure 50 will be examined. This example assumes that the overall down conversion process can be grouped into one set of specifications, instead of individually examining all components within the system and summing them together. Although a more detailed analysis should be employed in a real design, this model will provide a good approximation. In examining a wideband digital receiver, several considerations must be applied. Although other specifications are important, receiver sensitivity determines the absolute limits of a radio excluding the effects of other outside influences. Assuming that receiver sensitivity is limited by noise and not adjacent signal strength, several sources of noise can be identified and their overall contribution to receiver sensitivity calculated. GAIN = 30dB NF = 10dB BW =12.5MHz SINGLE CHANNEL BW = 30kHz RF/IF AD6640 REF IN ENC CHANNELIZER 61.44MHz Figure 50. Receiver Analysis REV. 0 DSP The first noise calculation to make is based on the signal bandwidth at the antenna. In a typical broadband cellular receiver, the IF bandwidth is 12.5 MHz. Given that the power of noise in a given bandwidth is defined by P n = kTB, where B is bandwidth, k = 1.38 × 10–23 is Boltzman’s constant and T = 300k is absolute temperature, this gives an input noise power of 5.18 × 10–14 watts or –102.86 dBm. If our receiver front end has a gain of 30 dB and a noise figure of 10 dB, then the total noise presented to the ADC input becomes –62.86 dBm (–102.86 + 30 + 10) or 0.16 mV rms. Comparing receiver noise to dither required for good SFDR, we see that in this example, our receiver supplies about 3% of the dither required for good SFDR. Based on a typical ADC SNR specification of 68 dB, the equivalent internal converter noise is 0.140 mV rms. Therefore total broadband noise is 0.21 mV rms. Before processing gain, this is an equivalent SNR (with respect to full scale) of 64.5 dB. Assuming a 30 kHz AMPS signal and a sample rate of 61.44 MSPS, the SNR through processing gain is increased by approximately 33 dB to 97.5 dB. However, if eight strong and equal signals are present in the ADC bandwidth, then each must be placed 18 dB below full scale to prevent ADC overdrive. Therefore we give away 18 dB of range and reduce the carrier-to-noise ratio (C/N) to 79.5 dB. Assuming that the C/N ratio must be 10 dB or better for accurate demodulation, one of the eight signals may be reduced by 66.5 dB before demodulation becomes unreliable. At this point, the input signal power would be –90.5 dBm. Referenced to the antenna, this is –120.5 dBm. To improve sensitivity, several things can be done. First, the noise figure of the receiver can be reduced. Since front end noise dominates the 0.16 mV rms, each dB reduction in noise figure translates to an additional dB of sensitivity. Second, providing broadband AGC can improve sensitivity by the range of the AGC. However, the AGC would only provide useful improvements if all in-band signals are kept to an absolute minimal power level so that AGC can be kept near the maximum gain. This noise limited example does not adequately demonstrate the true limitations in a wideband receiver. Other limitations such as SFDR are more restrictive than SNR and noise. Assume that the analog-to-digital converter has an SFDR specification of –80 dBFS or –76 dBm (Full scale = +4 dBm). Also assume that a tolerable carrier-to-interferer (C/I) (different from C/N) ratio is 18 dB. This means that the minimum signal level is –62 dBFS (–80 plus 18) or –58 dBm. At the antenna, this is –88 dBm. Therefore, as can be seen, SFDR (single or multitone) would limit receiver performance in this example. However, as shown previously, SFDR can be greatly improved through the use of dither (Figures 19, 22). In many cases, the addition of the out-of-band dither can improve receiver sensitivity nearly to that limited by thermal noise. –21– AD6640 Since performance of the AD6640 extends beyond the baseband region into the third Nyquist zone, the converter has many uses as a mix-down converter in both narrowband and wideband applications. This application is called bandpass sampling. Doing this has several positive implications in terms of the selection of the IF drive amplifier. Not only is filtering a bit easier, the selection of drive amplifiers is extended to classical IF gain blocks. In the third Nyquist zone and above, the second and third harmonics are easily filtered with a bandpass filter. Now only in-band spurs that result from third order products are important. POWER RELATIVE TO ADC FULL SCALE – dB Figures 21 and 24 in Typical Performance Characteristics illustrate a multicarrier, IF Sampling System. By using dither, all spurious components are forced below 90 dBFS (Figure 24). The dashed line illustrates how a 5 MHz bandpass filter could be centered at 67.5 MHz. As discussed earlier, this approach greatly reduces the size and complexity of the receiver’s RF/IF section. IF Sampling, Using the AD6640 as a Mix-Down Stage In narrowband applications, harmonics of the ADC can be placed out-of-band. One example is the digitization of a 201 MHz IF signal using a 17.333 MHz clock. As shown in Figure 51, the spurious performance has diminished due to internal slew rate limitations of the ADC. However, the SNR of the converter is still quite good. Subsequent digital filtering with a channelizer chip such as the AD6620 will yield even better SNR. For multicarrier applications, third order intercept of the drive amplifier is important. If the input network is matched to the internal 900 ohm input impedance, the required full-scale drive level is –3 dBm. If spurious products delivered to the ADC are required to be below –90 dBFS, the typical performance of the ADC with dither applied, then the required third order intercept point for the drive amplifier can be calculated. For multicarrier applications, the AD6640 is useful up to about 80 MHz analog in. For single channel applications, the AD6640 is useful to 200 MHz as shown from the bandwidth charts. In either case, many common IF frequencies exist in this range of frequencies. If the ADC is used to sample these signals, they will be aliased down to baseband during the sampling process in much the same manner that a mixer will down-convert a signal. For signals in various Nyquist zones, the following equations may be used to determine the final frequency after aliasing. f 1NYQUISTS = f SAMPLE − f SIGNAL f 2NYQUISTS = abs ( f SAMPLE − f SIGNAL ) f 3NYQUISTS = 2 × f SAMPLE − f SIGNAL f 4NYQUISTS = abs (2 × f SAMPLE − f SIGNAL ) Using the converter to alias down these narrowband or wideband signals has many potential benefits. First and foremost is the elimination of a complete mixer stage along with amplifiers, filters and other devices, reducing cost and power dissipation. In some cases, the elimination of two IF stages is possible. 0 ALIASED SIGNALS 20 ALIASED 3RD HARMONIC 40 ANALOG IF FILTER MASK ALIASED 2ND HARMONIC 60 80 100 198 199.8 201.6 203.4 FREQUENCY – MHz 205.2 207 Figure 51. IF-Sampling a 201 MHz Input RECEIVE CHAIN FOR A PHASED ARRAY CELLULAR BASE STATION The AD6640 is an excellent digitizer for beam forming in phased array antenna systems. The price performance of the AD6640 followed by AD6620 channelizers allows for a very competitive solution. Phase array base stations allow better coverage by focusing the receivers’ sensitivity in the direction needed. Phased array systems allow for the electronic beam to form on the receive antennas. A typical phased array system may have eight antennas as shown in Figure 52. Since a typical base station will handle 32 calls, each antenna would have to be connected to 32 receivers. If done with analog or traditional radios, the system grows quite rapidly. With a multicarrier receiver, however, the design is quite compact. Each antenna will have a wideband downconverter with one AD6640 per receiver. The output of each AD6640 would drive 32 AD6620 channelizers, which are phase locked in groups of eight—one per antenna. This allows each group of eight AD6620’s to tune and lock onto a different user. When the incoming signal direction is determined, the relative phase of each AD6620 in the group can be adjusted such the output signals sum together in a constructive manner, giving high gain and directivity in the direction of the caller. This application would not be possible with traditional receiver designs. –22– REV. 0 AD6640 SYNC 1 AD6620 (1) EIGHT WIDEBAND FRONT ENDS AD6620 (2) ANTENNA 1 AD6620 (3) AD6640 AD6620 (30) COMMON LO AD6620 (31) AD6620 (32) ANTENNA 2 AD6640 AD6620s (32 CHANNELS) COMBINE SIGNALS FROM EIGHT ANTENNA'S SYNC 1 AD6620 (1) SUM ADSP-21xx (1) SUM ADSP-21xx (2) SUM ADSP-21xx (3) AD6620 (2) ANTENNA 3 AD6620 (3) AD6640 AD6620 (30) AD6620 (31) ANTENNA 4 AD6620 (32) AD6640 AD6620s (32 CHANNELS) 32 CHANNELS OUT EACH CHANNEL IS SUMMATION FROM EIGHT ANTENNA'S SYNC 1 AD6620 (1) SUM ADSP-21xx (30) SUM ADSP-21xx (31) AD6620 (2) ANTENNA 5 AD6620 (3) AD6640 AD6620 (30) AD6620 (31) ANTENNA 6 SUM AD6620 (32) AD6640 ADSP-21xx (32) AD6620s (32 CHANNELS) SYNC 1 AD6620 (1) AD6620 (2) ANTENNA 7 AD6620 (3) AD6640 AD6620 (30) AD6620 (31) ANTENNA 8 AD6620 (32) AD6640 AD6620s (32 CHANNELS) Figure 52. Receive Chain for a Phased Array Cellular Base Station with Eight Antennas and 32 Channels REV. 0 –23– AD6640 AD6640AST OUTLINE DIMENSIONS Dimensions shown in inches and (mm) 0.063 (1.60) MAX C3141–8–1/98 44-Terminal Plastic Thin Quad Flatpack (ST-44) 0.472 (12.00) SQ 0.030 (0.75) 0.018 (0.45) 33 23 34 22 SEATING PLANE 0.394 (10.0) SQ TOP VIEW (PINS DOWN) 44 12 1 0.057 (1.45) 0.053 (1.35) 0.031 (0.80) BSC 0.018 (0.45) 0.012 (0.30) PRINTED IN U.S.A. 0.006 (0.15) 0.002 (0.05) 11 –24– REV. 0