Powering High Speed Analog-to-Digital Converters with Switching Power Supplies By Michael Cobb, Senior Applications Engineer, High Speed Converter Group, Analog Devices Reprinted with Permission from Power Management DesignLine — May 27, 2009 Introduction Modern electronic systems utilizing analog-to-digital converters (ADCs) demand lower power and higher performance. This article describes the differences between linear and switching supplies and demonstrates that combining a high performance ADC with an efficient dc-to-dc converter can significantly reduce system power without degrading its performance. System designers are being asked to reduce overall power in order to lessen the impact on our environment, while reducing both capital and operating costs. They are also being asked to increase circuit density so that electronic systems can be pushed into smaller form factors and operate in harsher environments. Unfortunately, incorporating high power solutions into these systems causes significant difficulties in removing the excess heat and leaves the other objectives unfulfilled. Traditionally, ADC manufacturers have recommended using linear voltage regulators to provide clean power supplies for the converter. The linear regulators reject low frequency noise often present in system power supplies. In addition, a combination of ferrite beads and decoupling capacitors is used to attenuate the high frequency noise. This technique is effective, but it limits efficiency, especially in systems where linear regulators must regulate down from a power rail several volts above their output voltage. LDOs typically offer 30% to 50% efficiency, whereas the efficiency of a dc-to-dc regulator can be greater than 90%. Figure 1 shows the typical efficiency of a stepdown switching regulator, Analog Devices ADP2114. 100 VIN = 3.3V; VOUT = 1.8V VIN = 5.0V; VOUT = 3.3V EFFICIENCY (%) 95 90 VIN = 5.0V; VOUT = 1.8V 85 DC-to-DC converters, while much more efficient than LDOs, have traditionally been considered too noisy to directly power high speed analog-to-digital converters without significant performance degradation. This noise has at least two sources: noise coupled directly into the converter through supply ripple and noise due to magnetic coupling effects. The ripple can appear as distinct tones (or spurs) in the ADC’s output spectrum or cause an overall elevation in the noise floor. The ADC’s susceptibility to these distinct tones can be characterized and is often specified in converter data sheets as power supply rejection ratio (PSRR). PSRR measurements, however, do not characterize wideband effects on a converter’s noise floor. The high currents produced in a switching power supply often lead to strong magnetic fields that can couple into other magnetic components on the board, including inductors found in matching networks and transformers used to couple analog and clock signals. Careful board layout techniques must be utilized to prevent these fields from coupling into critical signals. Power Savings (Efficiency Advantages) While semiconductor companies continue to introduce higher efficiency ADCs, DACs, and amplifiers, these improvements are small compared with the overall system power efficiency that can be obtained by replacing LDOs with dc-to-dc regulators. Consider a linear circuit that requires 100 mA, or 330 mW from a 3.3 V supply. With a typical LDO regulating 5 V down to 3.3 V, the overall power consumption would be 500 mW, while only 330 mW would provide a useful function. The raw supply must be 51% larger than actually necessary, resulting in both wasted energy and higher cost. By comparison, consider a dc-to-dc regulator with 90% efficiency. The total demand from a 5 V source would be 74 mA, a significantly smaller requirement, reducing both power and cost over time. 80 75 70 0 0.5 1.0 1.5 2.0 LOAD CURRENT (A) Figure 1. Typical efficiency of ADP2114 switching regulator. www.analog.com In systems such as wireless base stations, power is often derived from a single high current power supply. Often this power gets regulated down through a number of different step-down stages before reaching the linear and mixed-signal components. Each of these step-down stages, although they may be quite efficient, results in some wasted power. The figure below shows a typical system where power is regulated down from a 12 V power rail. Three or more step-down stages may be involved in providing power to the ADC and other analog components. The last stage, which is typically an LDO, is often the least efficient of the step-down stages. Even efficient dc-to-dc regulators that achieve 90% efficiency result in only about 81% efficiency when cascaded twice, as shown in Figure 2. This gets even worse when LDOs must follow for the final regulation stage. MAIN POWER BLOCK 12V OUTPUT STEP DOWN STEP DOWN LDO LINEAR AND MIXED SIGNAL COMPONENTS Figure 2. Typical system level power supply. Recent improvements in dc-to-dc power supply technology and higher switching frequencies have enabled ADC operation directly from dc-to-dc power supplies with no loss in performance and significantly greater efficiency. Figure 3 shows a typical step-down circuit with the LDO eliminated. MAIN POWER BLOCK 12V OUTPUT STEP DOWN ADP2114 PWM step-down regulator. This dual output stepdown regulator is up to 95% efficient, operates at a high switching frequency, and has low noise. A lab study compared the ADC’s performance with linear regulators vs. its performance when using a switching regulator. These experiments were performed using the converter’s customer evaluation board. The converter has two input supplies: AVDD powers the analog portion, while DRVDD powers the digital and output sections. For comparison, the converter was initially evaluated with two linear regulators (Analog Devices ADP1706), supplying both AVDD and DRVDD voltages. The setup for this test is shown in Figure 4. The converter was then powered with a switching regulator, as shown in Figure 5. One of the switching regulator’s outputs supplied AVDD; the second output supplied DRVDD. In both setups, the analog input source was a Rhode & Schwartz SMA-100 with a K&L band-pass filter. The analog input was supplied through a double balun input network, which converts the single-ended output from the signal generator to a differential input for the ADC. The sample clock source was a low jitter Wenzel oscillator, which was also supplied through a balun circuit for single-ended-todifferential conversion. The input supply rail (ahead of the regulators) was set to 3.6 V for both measurements. ~3.5V LINEAR AND MIXED-SIGNAL COMPONENTS ADP1706-1.8 ADP1708 Figure 3. Reduced system level power supply. In addition, many systems employ a separate LDO for each ADC. Separate LDOs have been used to provide noise isolation between different ADCs and to reduce the power dissipated in each LDO. This separation spreads out the heat generated by the LDOs and allows the use of LDOs in small packages. Due to the higher efficiency of switching converters, one switcher can power several ADCs and other linear components, without excessive power dissipation and heat generation that would occur using a single large LDO. Using filtering ferrite beads at the output of the switching supply provides isolation between components that share the same power rail. The use of a switcher decreases the need for regulators in the system, resulting in significant power savings and reduced board cost by eliminating redundant LDOs and associated circuitry. FERRITE BEADS R&S SMA-100 SIGNAL GENERATOR K&L TUNABLE BANDPASS FILTER WENZEL OSCILLATOR @125MHz 2 | AD9268 VIN–A CLK+ CLK– SINGLE BALUN CLOCK CIRCUIT Figure 4. Block diagram for linear power supply measurements using ADP1708 LDOs. ~3.5V ADP2114 OUTPUT 1 = 1.8V OUTPUT 2 = 1.8V FERRITE BEADS From the Lab A 16-bit, 125 MSPS analog-to-digital converter such as Analog Devices AD9268 achieves very low noise with a 78 dB signal-to-noise ratio (SNR) specification. The low noise floor of –152 dBm/Hz makes it an ideal candidate for evaluation with a switching power supply. Any additional noise or spurious content contributed by the dc-to-dc converter would be easily visible in the converter’s output spectrum. The converter was paired with an Analog Devices AVDD DRVDD VIN+A DOUBLE BALUN INPUT CIRCUIT TO DIGITAL BUFFERS R&S SMA-100 SIGNAL GENERATOR K&L TUNABLE BANDPASS FILTER WENZEL OSCILLATOR @125MHz DOUBLE BALUN INPUT CIRCUIT AVDD DRVDD VIN+A AD9268 VIN–A CLK+ CLK– SINGLE BALUN CLOCK CIRCUIT Figure 5. Block diagram for switching power supply measurements using ADP2114 switching regulator. Powering High Speed Analog-to-Digital Converters with Switching Power Supplies ADC Performance Results The converter performance was measured with each supply configuration to determine if any degradation occurred when using the switching supplies. The SNR and SFDR were measured over a number of input frequencies; the results, summarized in Table 1, show no significant difference in SNR or SFDR when using linear regulators vs. using the switching supplies. The switching regulator can run asynchronously or it can be synchronized to the converter’s sample clock without affecting the converter’s performance. Synchronization allows for additional freedom in applications where it may be advantageous. Table 1. Performance Comparison: Linear Supplies vs. Switching Regulator Linear Supplies Figure 7. 70 MHz AIN with ADP2114 switching supplies. Switching Supply Analog Input Frequency (MHz) SNRFS SFDR SNRFS SFDR 10.3 79.2 92.2 79.2 92.3 70.0 78.5 91.0 78.4 90.8 100.3 77.8 85.8 77.7 85.6 140.3 76.9 85.0 76.9 84.8 170.3 76.2 84.3 75.9 84.6 200.3 75.0 76.9 75.0 77.0 Efficiency Results Table 2 shows the measured efficiency of each power solution. With a 3.6 V input voltage, the switching regulator provides a 35% improvement in efficiency and a savings of 640 mW. This savings is for a single converter and would be amplified dramatically in systems utilizing multiple ADCs. Table 2. Efficiency Comparison: Linear Supplies vs. Switching Regulator Linear Regulators ADP2114 Switching Regulator Input Voltage/ Current 3.6 V/0.433 mA (1.5588 W) 3.6 V/0.255 mA (0.918 W) Output Voltage/ Current 1.8 V/0.433 mA (0.7794 W) 1.8 V/0.433 mA (0.7794 W) 50% 85% FFT Plots Figure 6 and Figure 7 show FFTs of the AD9268 with a 70 MHz analog input frequency using linear supplies vs. switching supplies. Overall Efficiency Figure 6. 70 MHz AIN with ADP1708 linear supplies. www.analog.com | 3 Thermal Images Figure 8 and Figure 9 below show the differences in heat generated in the power supply section of the board between using the LDO supply vs. the ADP2114. The same scaling is applied to both images. Measurement points SP01, SP02, and SP03 show the temperature of the linear regulators, which are operational in Figure 8. SP06 in Figure 9 shows the temperature of the ADP2114, which is 10°C to 15°C lower than the linear regulators shown in Figure 8. SP04 shows the temperature of the AD9268, which is similar in both images. Also note that in Figure 8 the overall background temperature is higher, and a series blocking diode (unlabeled) is handling a much higher thermal load. Circuit Details Figure 10 shows the detailed circuit diagram used for the switching regulator, which was configured to operate in the forced PWM mode with the channels set up for 2 A individual outputs. The regulator’s switching frequency was Figure 8. Thermal image of AD9268 evaluation board with linear power supply. 4 | set to 1.2 MHz by placing a 27 kΩ resistor between the FREQ pin and GND. In addition to the circuit shown, an additional ferrite bead was included between the switcher and the ADC, and standard bypass capacitors were placed near the ADC supply pins. This design achieves 220 µV of switching ripple and less than 6 µV of high frequency noise at the output of the ADP2114. The additional ferrite bead and bypassing near the AD9268 reduce this to 300 nV and less than 3 µV noise at the ADC power pins. The bill of materials and layout information are provided as well. Note in the layout that the switching inductors L101 and L102 are on the opposite side of the board from the ADC and signal path components. This placement helps to minimize any potential coupling between these inductors and the components on the top of the board, particularly the baluns in the signal and clock paths. In any layout with a switching converter, care should be taken to avoid magnetic or electric field coupling. Figure 9. Thermal image of AD9268 evaluation board with ADP2114 supply. Powering High Speed Analog-to-Digital Converters with Switching Power Supplies C148 22𝛍F C147 22𝛍F R104 10𝛀 R105 100k𝛀 3 5 27 26 25 14 15 16 2 L101 2.2𝛍H C109 10000pF E116 100MHz 1 2 VOUT_1.8VA C138 22𝛍F R118 13k𝛀 PGND1 PGND2 20 PGND3 19 PGND4 EPAD VIN VOUT_1.8VB R111 15k𝛀 C111 100pF 29 C139 22𝛍F C112 1500pF C113 100pF L102 2.2𝛍H E117 100MHz 1 2 VOUT_1.8VB 21 C108 10000pF 1 VOUT_1.8VA R110 15k𝛀 COMP1 22 R109 4.75k𝛀 PGOOD1 C110 2200pF 6 VIN R107 27k𝛀 SCFG FREQ 24 SYNC_CLKOUT SW1 23 OPCFG SW2 28 ADP2114 EN1 12 31 V1SET PGOOD2 32 7 FB1 COMP2 30 18 SS1 SW3 13 17 EN2 SW4 10 V2SET 9 FB2 11 SS2 GND PAD SW_FREQ R106 100k𝛀 R108 10.5k𝛀 VIN1 VIN2 VIN3 VIN4 VIN5 VIN6 4 VDD 8 C107 1𝛍F C141 22𝛍F C142 22𝛍F Figure 10. ADP2114 circuit configuration. Table 3. Bill of Materials Quantity Reference Designator Description Manufacturer Part Number Package Type 1 C107 1 µF CAP CER Panasonic ECJ-0EF0J105Z C0402 2 C108, C109 10000 pF CAP CER MULTILAYER X7R 0402 Panasonic ECJ-0EB1E103K C0402 1 C110 2200 pF CAP CER Phycomp (Yageo) 0402R222K8B20D C0402 2 C111, C113 100 pF CAP CHIP MONO CER C0G 0402 Murata GRM1555C1H101JD01D C0402 1 C112 1500 pF CAP CER 0402 Panasonic ECJ-0EB1H152K C0402 6 C138, C139, C141, C142, C147, C148 22 µF CAP CER CHIP Murata GRM21BR60J226ME39L C0805 2 E116, E117 100 MHz INDUCTOR FERRITE BD Panasonic EXC-ML20A390U L0805 2 L101, L102 2.2 µH INDUCTOR SM Toko FDV0630-2R2M LSML291W264H118 1 R104 10 Ω RES PREC THICK FILM CHIP R0402 Panasonic ERJ-2RKF10R0X R0402 2 R105, R106 100 kΩ RES PREC THICK FILM CHIP R0402 Panasonic ERJ-2RKF1003X R0402 1 R107 27 kΩ RES CHIP SMD 0402 Panasonic ERJ-2RKF2702X R0402 1 R108 10.5 kΩ RES PREC THICK FILM CHIP R0402 Panasonic ERJ-2RKF1052X R0402 1 R109 4.75 kΩ RES CHIP SMD 0402 Panasonic ERJ-2RKF4751X R0402 2 R110, R111 15 kΩ RES CHIP SMD 0402 Panasonic ERJ-2RKF1502X R0402 1 R118 13 kΩ RES FILM SMD 0402 Yageo 9C04021A1302FLHF3 R0402 VR101 IC ADI DUAL CONFIG SYNC PWM STEPDOWN REG ADI ADP2114 QFN32_5X5_PAD3_3X3_3 1 www.analog.com | 5 ADP2114 CIRCUIT AD9268 AND INPUT CIRCUITRY Figure 11. PCB layout showing relative location of ADP2114 and the AD9268 (note the switching inductors are on the opposite side of the PCB). Conclusion This article demonstrates that analog-to-digital converters can be powered directly from switching power supplies with no loss in performance if careful design practice is followed. The converter’s performance showed no degradation when powered from the ADP2114 switching supply vs. ADP1708 linear supplies. Using a switching power supply can improve supply efficiency by 30% to 40% and significantly reduce overall power consumption — even more than simply selecting a lower power converter. In many systems, these devices are running continuously, so employing switching power supplies results in significantly lower operating costs with no penalty in performance. Michael Cobb is a senior applications engineer for Analog Devices High Speed Converter Group. He can be reached at [email protected]. Analog Devices, Inc. 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