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| SPT5510 16-BIT, 200 MWPS ECL D/A CONVERTER FEATURES * * * * * * * 16-Bit, 200 MWPS digital-to-analog converter Differential linearity of 0.6 LSB (typical) Integral linearity of 0.75 LSB (typical) Fast settling time: 35 ns to 0.0008%; 25 ns to 0.01% Low glitch energy On-chip voltage reference ECL compatibility APPLICATIONS * * * * * * * High-precision arbitrary waveform generation Test and measurement instrumentation Digital waveform synthesis Microwave and satellite modems Disk drive test equipment Industrial process control Military applications GENERAL DESCRIPTION The SPT5510 is a 16-bit, 200 MWPS digital-to-analog converter designed for high-resolution waveform synthesis for test and measurement instrumentation applications. It features true 16-bit linearity, with differential non-linearity of typically 0.6 LSB and integral non-linearity of 0.75 LSB. It has a very high-speed update rate of up to 200 MHz and is ECL compatible. It has an ultrafast settling time of 25 ns to 0.01% and 35 ns to 0.0008%. The SPT5510 operates over an industrial temperature range of -40 C to +85 C and is available in a 10 x 10 mm, 44-lead metric quad flat pack (MQFP) plastic package. BLOCK DIAGRAM REFIN D15-D12 IOUT IOUT MSB Decoder 16 MSB Latch 16 IOUT Digital Inputs D15-D0 16 Input Latch LSB Buffer 12 LSB Latch 12 Bias D11-D0 CLK BGOUT Current Cells IOUT Bandgap Reference Bias RSET AMPINB + - Ref Amp Reference Cell 20 AMPOUT 10 AMPCC ABSOLUTE MAXIMUM RATINGS (Beyond which damage may occur)1 Supply Voltages Negative supply voltage (VEE) ................................. -7 V A/D ground voltage differential ................................ 0.5 V Input Voltages Digital input voltage (D15-D0, Clock)... ........... -2.5 to 0 V Ref amp input voltage range .......................... -2.5 to 0 V Reference input voltage range (Ref In) ...... VEE to -2.5 V Output Currents Bandgap reference output current ..................... 500 A Ref amplifier output current ................................ 2.5 mA Temperature Operating temperature ............................... -40 to +85 C Junction temperature .......................................... +150 C Lead, soldering (10 seconds) ............................. +250 C Storage .................................................... -65 to +150 C Note: 1. Operation at any Absolute Maximum Rating is not implied. See Electrical Specifications for nominal operating conditions. ELECTRICAL SPECIFICATIONS TA= 25 C, VEE=-5.2 V 5%, 50% duty cycle clock, unless otherwise specified. PARAMETERS DC Performance1 Resolution Differential Linearity Differential Linearity Integral Linearity Integral Linearity Integral Linearity Drift Offset Drift Monotonicity Output Capacitance Gain Error Gain Error Tempco Gain Error Tempco Offset Error Compliance Voltage Output Resistance Dynamic Performance Conversion Rate Settling Time tST2 TEST CONDITIONS TEST LEVEL MIN SPT5510 TYP 16 0.6 1.0 0.75 1.5 MAX UNITS Bits LSB LSB LSB LSB LSB/C ppm FS/C Bits pF % FS ppm FS/C ppm FS/C A V k MHz TMIN-TMAX TMIN-TMAX TMIN-TMAX With Ext Reference With Internal Bandgap Ref VI IV VI IV IV IV V V I V V I IV IV IV -1.95 -4.0 -1.95 -4.0 -0.2 -2.5 15 -2 1.95 4.0 1.95 4.0 0.2 2.5 10 0.4 50 50 2 -4 -1.2 0.88 200 1.1 4 2 1.32 Settling to 0.01% Settling to 0.0008% Delay Time tD Glitch Energy Full Scale Output Current Rise Time/Fall Time Spurious Free Dynamic Range OUT=5 MHz; CLOCK=30 MHz OUT=10 MHz; CLOCK=100 MHz 1Measured 2Measured With On-Chip References RL = 50 10 MHz Span 10 MHz Span V V V V V V V V 25 35 2 30 19 2 84 76 ns ns ns pV-s mA ns dB dB at 0 V output using I-V. as voltage settling for mid-scale transition; RL = 50 . SPT5510 2 9/27/00 ELECTRICAL SPECIFICATIONS TA= 25 C, VEE=-5.2 V 5%, 50% duty cycle clock, unless otherwise specified. TEST PARAMETERS Power Supply Requirements Negative Supply Current (-5.2 V) Nominal Power Dissipation Power Supply Rejection Ratio Voltage Input and Control Bandgap Reference Voltage Bandgap Output Current Ref Amp Bandwidth3 Ref Amp Input Current Ref Amp Output Current Ref In Operating Voltage Digital Inputs Logic 1 Voltage Logic 0 Voltage Logic 1 Current Logic 0 Current Input Capacitance Input Setup Time (tS) Input Hold Time (tH) Clock Pulse Width (tPWH) 3Ref TEST LEVEL VI V I V IV V V V V VI VI V V V IV IV IV MIN SPT5510 TYP 115 600 0.002 -1.2 16 40 16 200 -3.4 -0.8 -1.7 2.5 0 3 MAX 150 800 0.6 UNITS mA mW % FS V A MHz A A V V V A A pF ns ns ns CONDITIONS TMIN -TMAX V Supply = 5 % -0.6 TA=25 C 10 C -110 220 TMIN -TMAX TMIN -TMAX -0.8 V -1.8 V -1.0 -1.5 3.0 0.5 1.5 Amp Bandwidth is limited by its compensation network TEST LEVEL CODES All electrical characteristics are subject to the following conditions: All parameters having min/max specifications are guaranteed. The Test Level column indicates the specific device testing actually performed during production and Quality Assurance inspection. Any blank section in the data column indicates that the specification is not tested at the specified condition. TEST LEVEL I II III IV V VI TEST PROCEDURE 100% production tested at the specified temperature. 100% production tested at TA = +25 C, and sample tested at the specified temperatures. QA sample tested only at the specified temperatures. Parameter is guaranteed (but not tested) by design and characterization data. Parameter is a typical value for information purposes only. 100% production tested at TA = +25 C. Parameter is guaranteed over specified temperature range. SPT5510 3 9/27/00 THEORY OF OPERATION The SPT5510 is a segmented 16-bit current-output DAC. The four MSBs, D15-D12, are decoded to fifteen unit cells (current sinks). The remaining bits (D11-D0) are binary; bits D9-D0 are derived from an R-2R ladder. All cells are laser trimmed for maximum accuracy. The block diagram shows the basic architecture. All output cells are always on, with the data determining whether a given cell's current is routed from IOUT or IOUT. This provides nearly constant power dissipation independent of data and clock rate. It also reduces noise transients on power and ground lines. The reference loop utilizes an MSB-weighted cell and provides a gain of about 16 to the output. The on-chip reference amplifier has very high open-loop gain and is offset trimmed to provide a very low temperature drift (typically <10 ppm/C gain drift). Figure 1 - Typical Interface Circuit POWER SUPPLY AND GROUNDING The SPT5510 requires a single -5.2V power supply. All supply pins attach to a common on-chip power bus and should be treated as analog supplies. For best settling performance, each supply pin should be decoupled as shown in figure 1 - typical interface circuit. There are three separate on-chip ground busses. DGND pins should be tied together and connected to system ground through a ferrite bead. REFGND and OGND pins should be tied directly to the SPT5510's ground plane and connected to system ground through a ferrite bead. It is critical that REFGND and OGND are very tightly coupled, as any differential signal (dc offset, noise, etc.) will be transmitted to the output. Two of the OGND pins can be disconnected from the ground plane and used as sense lines for a current-to-voltage converter, as shown in the OUTPUTS section. C13 20 pF C12 10 pF .01 F 1K 50 47 pF 47 pF 1K AVEE .01 F C7 R7 R9 C9 C10 22 20 12 19 16 AMPINB 18 REFGND REFGND BGOUT RSET CLK 17 AMPCC AMPB 15 9 AMPOUT 1 2 3 4 5 6 D15 D14 D13 D12 D11 D10 D9 D8 D7 D6 D5 D4 D3 D2 D1 D0 REFIN 21 R10 50 R8 C8 IOUT 41 Input Data 7 8 25 26 27 28 29 30 31 32 SPT5510 36 IOUT OGND DGND OGND OGND OGND DGND DGND DGND AVEE AVEE AVEE AVEE AVEE AVEE AVEE 44 10 24 33 40 42 35 37 R1 10 R2 10 R4 10 2.2 F 2.2 F 2.2 F 2.2 F .01 F .01 F .01 F .01 F R6 10 C5 C6 .01 F R3 10 C14 C15 C17 C1 .01 F C2 C3 C16 C4 R5 10 C1-C13 -- SURFACE MOUNT CERAMIC CHIP C14-C17 -- TANTALUM R1-R6 -- CARBON FILM 1/4 W R7-R10 -- SURFACE MOUNT CERAMIC CHIP FB -- FERRITE BEAD is to be located as closely to the device as possible. FB AVEE 39 43 11 13 14 23 34 38 AVEE C11 47 pF Output Output Complementary SPT5510 4 9/27/00 Wideband decoupling is required for optimum settling performance. This may require several capacitors in parallel, and series resistors when appropriate, to reduce resonance effects. Some applications may need only a single capacitor; however, decoupling influences both long- and shortterm settling, so caution is urged. Your application may require some research to determine the optimum power supply decoupling network. DIGITAL INPUTS AND TIMING Each digital input is buffered, decoded, and then latched into D flip-flops which drive the output switches. Masterslave flip-flops are not used; thus, there is only a 1/2 clock period delay (max) from data change to output change. In this architecture, clock and data edge speeds (i.e., rise/fall times) may affect data feedthrough. Using a data edge of approximately 0.8 ns will cause data feedthrough of about 10 pV-s, while a 5 ns data edge will reduce the feedthrough to about 4 pV-s. Data lines may include series resistors or RC filters for edge control if desired. The clock signal controls when the data is latched into the flip-flops. When the CLK is high, the DAC is in track mode. A negative going CLK latches the data. If CLK is held low, the DAC is in hold mode. See figure 2. Figure 2 - Timing Diagram tS CLK tH tD OUTPUTS The output is comprised of current sinks, R-2R ladder, and associated parasitics. See figure 3 for an equivalent output circuit. The DAC's full-scale output current when using the internal reference amplifier is determined by the voltage at pin AMPINB and the RSET resistance. It can be found (to within an LSB) by using the following formula: IOUT FS = (AMPINB/RSET) x 16 The inputs determine whether the current from each sink comes from IOUT or IOUT as follows: Code (D15 is MSB) 0 (zero scale) 32768 (mid-scale) 65535 (full-scale) IOUT No current IOUT = IOUT All current IOUT All current IOUT = IOUT No current Differential outputs facilitate maximum noise rejection and signal swing. The DAC is trimmed using a current to voltage (I-V) converter which provides a virtual ground at the outputs and includes sense lines to mitigate the impact of bus drops. Operating into a load other than a virtual ground will introduce a slight bow at the output. This bow is related to the current sinks' finite output impedance and ladder impedance. An example circuit using an I-V converter is shown in figure 4. Note that resistor and op-amp self heating over the DAC's full-scale range will introduce additional temperature dependence. The op-amp and feedback resistor must both have very low tempcos if the DAC's intrinsic gain drift is to be maintained. A sense line helps reduce wire effects - both IR loss and temperature drift. Figure 4 - I-V Converter BNC "IOUT" DATA IOUT IOUT tST tH = hold time tD = time to output valid tS = setup time tST = settling time OGND IOUT OGND - 250 GND Figure 3 - Equivalent Output Circuit IOUT or IOUT AVEE OGND IOUT 1.1k 10 pF OGND 5 + + - GND 250 BNC "IOUT" SPT5510 9/27/00 The feedback resistor should be matched to RSET to reduce gain drift. Also, the op amp's ground reference should be the same as RSET's to reduce gain and offset errors. A composite amplifier may be required to obtain optimal dc performance. A differential circuit may be used; a common heat sink covering both sides (op amps and resistors) will help reduce temperature effects. Achieving good settling performance requires careful board layout with multiple decoupling circuits and very clean power and ground routing. It is important that digital switching currents do not flow across analog input (REFIN) and output signals. Terminations must be broadband and near the device. Measuring settling performance is quite challenging and requires several test systems to ensure settling errors from the instruments are not included. Dynamic performance characteristics (e.g., settling, rise and fall times, etc.) were measured with the outputs terminated to ground through 50 resistors. SFDR was determined using a transformer to convert the output from differential to single-ended as shown in figure 5. The SPT5510 is designed primarily for step and settle or narrowband RF applications. The second harmonic generally dominates wideband SFDR measurements, although close-in spurs are very small. Figure 5 - Transformer Output Circuit IOUT 25 BANDGAP VOLTAGE REFERENCE The on-chip bandgap voltage reference is designed to bias the non-inverting input of the reference amplifier (AMPINB) through a resistor equal to RSET to help compensate the reference amplifier (see the following section). If the bandgap voltage is required by another DAC, or elsewhere in the system, it must be buffered with a precision op amp configured as a high impedance (e.g., unity gain follower) buffer. A resistor, or RC filter, plus a ferrite bead will help isolate the output from the reference amplifier's compensation and high-frequency charge pulses produced during operation. The output should always be very carefully checked for oscillations using a sensitive, wideband oscilloscope and spectrum analyzer. REFERENCE AMPLIFIER The reference amplifier is a highly temperature-stable driver to bias the precision current sinks. The reference amplifier should only be used to drive REFIN. Additional loads will change the amplifier's compensation, which can lead to instability and other settling issues. There are two reference amplifier outputs: AMP OUT and AMPCC. AMPOUT has a 20 ohm series resistor between the output of the reference amplifier and the AMPOUT pin; AMPCC has a 10 ohm resistor. These parallel outputs aide compensation and decoupling. The open-loop output impedance is approximately 1200 ohms. Reference amplifier compensation is key to achieving high performance. Without proper compensation, oscillations that affect accuracy and settling time will occur. Figure 6 shows a typical reference amplifier compensation circuit. Note that several small value capacitors are used from REFIN to ground. This is to provide suitably low impedance 25 IOUT Figure 6 - Reference Amplifier Circuit SPT5510 DAC RSET 1 k 17 + 20 10 20 21 REFIN Ref Amp AMPOUT 19 50 1 k 0.01 F 16 18 - AMPCC 10 pF C1 C2 C3 BGOUT 15 47 pF each AMPB 0.01 F VEE 20 pF All components are ceramic chip-type. SPT5510 6 9/27/00 around 300 MHz, the amplifier's phase crossover point. The unity-gain bandwidth is roughly 700 MHz. Larger value capacitors exhibit lower self-resonance frequency and thus may not adequately compensate the reference amplifier. Large capacitors may also introduce low frequency tails which increase settling time. The DAC itself exhibits very broadband switching spikes (charge kickback) at the RSET node, which can contribute to amplifier instability if not suppressed. Note that the AMPINB input must not be directly bypassed, as this will short all feedback to ground, leading to severe oscillation. Compensation must be optimized for each application. As with any high-speed, high-resolution design, attention must be paid to grounding, decoupling, and parasitic elements that may cause instability. It may be wise to use a guard ring, and/or clear the board ground, around the reference amplifier's inputs. All traces must be short, and capacitors with high self-resonance must be used. Compensation is perhaps the most challenging aspect of setting up the SPT5510. By slowly switching a full-scale data input (generating a low-frequency square wave), with appropriate clock timing, the DAC's output can be observed using a suitable oscilloscope and spectrum analyzer to observe and suppress any oscillations caused by board and decoupling parasitics. Consult Fairchild Applications for further assistance if required. LONG-TERM STABILITY VERSUS TEMPERATURE As with all high-speed, high-resolution digital-to-analog converters, the initial accuracy of the device will degrade with both time and temperature. The graph shown in figure 7 can be used to determine the expected change in linearity performance over time when the device is operated at various ambient temperatures. This graph shows how long it will take for the SPT5510 linearity to change by 8 ppm (or 1/2 LSB) at any operating temperature. The top curve shown represents integral nonlinearity (ILE) changes; the bottom curve shows differential nonlinearity (DLE) changes. Figure 7 - Linearity Performance over Time 1000 years 100 years (Hours) 1 year 104 105 106 107 ILE 103 1 month DLE 102 0 20 40 60 80 100 120 Temperature (C) Expected time required to produce an 8 ppm (1/2 LSB) linearity (ILE or DLE) shift as a function of temperature. PACKAGE OUTLINE 44-Lead MQFP A B SYMBOL A Pin 1 Index MIN INCHES MAX 0.5295 0.3957 0.3957 0.5295 0.0319 0.0177 0.0827 0.0098 0.0406 MILLIMETERS MIN MAX 12.95 9.95 9.95 12.95 0.79 0.30 1.95 0.10 0.73 13.45 10.05 10.05 13.45 0.81 0.45 2.10 0.25 1.03 1.60 REF 0 7 0.5098 0.3917 0.3917 0.5098 0.0311 0.0118 0.0768 0.0039 0.0287 B C D C D E F G H E F I J 0.0630 REF 0 7 G I H J K K SPT5510 7 9/27/00 PIN ASSIGNMENTS OGND 42 OGND 40 OGND 37 OGND 35 DGND 44 AVEE AVEE AVEE 34 AVEE 43 IOUT 41 PIN FUNCTIONS IOUT 36 NAME D15-D0 DGND D0 (LSB) D1 D2 D3 D4 D5 D6 D7 DGND AVEE FUNCTION Digital Input Bits - all inputs high sends all current to IOUT, none to IOUT Clock - latches D flip-flops Analog Current Output Complementary Analog Current Output Bandgap Voltage Reference Ref Amp's Inverting Input Ref Amp's Non-Inverting Input - connection for reference-current-setting resistor, nominally 1k to ground Bias Voltage for Output Current Switches - drives REFIN (on-chip 20 resistor for compensation) Bias Voltage Node for Output Current Switches - driven by AMPOUT Used to Decouple Ref Amp's Circuits to AVEE AMPOUT plus on-chip 10 series resistor for compensation Negative Supply - -5.2 V Digital Ground Return Output Ground Return Reference Amplifier Ground Return 39 38 (MSB) D15 D14 D13 D12 D11 D10 D9 D8 CLK DGND AVEE 1 2 3 4 5 6 7 8 9 10 11 33 32 31 30 CLK IOUT IOUT BGOUT AMPINB RSET SPT5510 44-Pin MQFP 29 28 27 26 25 24 23 AMPOUT ORDERING INFORMATION PART NUMBER SPT5510SIM TEMPERATURE RANGE -40 to +85 C PACKAGE 44L MQFP DISCLAIMER FAIRCHILD SEMICONDUCTOR RESERVES THE RIGHT TO MAKE CHANGES WITHOUT FURTHER NOTICE TO ANY PRODUCTS HEREIN TO IMPROVE RELIABILITY, FUNCTION OR DESIGN. FAIRCHILD DOES NOT ASSUME ANY LIABILITY ARISING OUT OF THE APPLICATION OR USE OF ANY PRODUCT OR CIRCUIT DESCRIBED HEREIN; NEITHER DOES IT CONVEY ANY LICENSE UNDER ITS PATENT RIGHTS, NOR THE RIGHTS OF OTHERS. LIFE SUPPORT POLICY FAIRCHILD'S PRODUCTS ARE NOT AUTHORIZED FOR USE AS CRITICAL COMPONENTS IN LIFE SUPPORT DEVICES OR SYSTEMS WITHOUT THE EXPRESS WRITTEN APPROVAL OF THE PRESIDENT OF FAIRCHILD SEMICONDUCTOR CORPORATION. As used herein: 1. Life support devices or systems are devices or systems which, (a) are intended for surgical implant into the body, or (b) support or sustain life, and whose failure to perform, when properly used in accordance with instructions for use provided in the labeling, can be reasonably expected to result in a significant injury to the user. www.fairchildsemi.com 12 13 14 15 16 17 18 19 20 21 22 AMPINB AMPCC AMPOUT AVEE AVEE AMPB REFIN REFGND REFGND RSET BGOUT REFIN AMPB AMPCC AVEE DGND OGND REFGND 2. A critical component is any component of a life support device or system whose failure to perform can be reasonably expected to cause the failure of the life support device or system, or to affect its safety or effectiveness. (c) Copyright 2002 Fairchild Semiconductor Corporation SPT5510 8 9/27/00 |
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