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ADP1872-BL2-EVZ

ADP1872-BL2-EVZ

  • 厂商:

    AD(亚德诺)

  • 封装:

    -

  • 描述:

    EVAL BOARD FOR ADP1872

  • 数据手册
  • 价格&库存
ADP1872-BL2-EVZ 数据手册
ADP1872-EVALZ/ADP1873-EVALZ User Guide UG-057 One Technology Way • P.O. Box 9106 • Norwood, MA 02062-9106, U.S.A. • Tel: 781.329.4700 • Fax: 781.461.3113 • www.analog.com Evaluating the ADP1872/ADP1873 PWM Buck Controllers FEATURES TYPICAL APPLICATIONS CIRCUIT VIN = 2.75V TO 20V VIN CC ADP1872/ ADP1873 CC2 RC BST COMP/EN VOUT CIN CBST RTOP FB DRVH RBOT GND CVDD2 VDD = 2.75V TO 5.5V APPLICATIONS L VOUT COUT Q2 SW VDD Q1 DRVL PGND RRES LOAD 5A CVDD Perform basic evaluation board operations Evaluate IC and application board performance + 08548-001 Wide power input voltage (VIN): 2.75 V to 20 V Bias supply voltage (VDD) range: 2.75 V to 5.5 V Available in 1.8 V fixed-output voltage Available in 300 kHz, 600 kHz, and 1.0 MHz switching frequency options Available in power saving mode (PSM) for light loads (ADP1873 only) Starts into a precharged or preloaded output Figure 1. GENERAL DESCRIPTION This document describes the evaluation board hardware for the ADP1872/ADP1873 PWM buck controllers. The evaluation boards can be used to evaluate the ADP1872 or ADP1873 and application circuits using these ICs without requiring any additional software. The ADP1872/ADP1873 evaluation boards employ a power input voltage (VIN) that ranges between 2.75 V and 20 V and a bias supply voltage (VDD) that ranges between 2.75 V and 5.5 V. Both inputs can be tied together for application input voltage conditions equal to or less than 5.5 V. The evaluation board is available in a fixedoutput voltage option (VOUT = 1.8 V), as well as in a 300 kHz, 600 kHz, or 1 MHz switching frequency (test trimmed in production). The ADP1872/ADP1873 evaluation boards offer an output accuracy of 2% over the full temperature range and provide a high input voltage (VIN ± 10%) and a full-scale load current up to 15 A. See the last page for an important warning and disclaimers. 08548-100 The ADP1872/ADP1873 are versatile current-mode, synchronous step-down controllers that provide superior transient response, optimal stability, and current limit protection by using a constant on-time, pseudo-fixed frequency with a programmable currentsense gain, current-control scheme. The ADP1873 is the power saving mode (PSM) version of the device and is capable of pulse skipping to maintain output regulation while achieving improved system efficiency at light loads (see the ADP1872/ADP1873 data sheet for more information). Both devices are available in a small, 10-lead MSOP package and can operate over the −40°C to +125°C temperature range. Figure 2. ADP1872 Evaluation Board Configured for 300 kHz Switching Frequency Operation The ADP1872/ADP1873 data sheet provides more information, including details about how to modify the evaluation board while maintaining system stability throughout the entire load current range and, therefore, should be consulted in conjunction with this user guide when using the evaluation boards. Rev. A | Page 1 of 20 UG-057 ADP1872-EVALZ/ADP1873-EVALZ User Guide TABLE OF CONTENTS Features .............................................................................................. 1 Typical Performance Characteristics ..............................................6 Applications ....................................................................................... 1 Typical Application Circuits ......................................................... 10 General Description ......................................................................... 1 Dual-Input, 300 kHz High Current Application Circuit ...... 10 Typical Applications Circuit............................................................ 1 Evaluation Board Schematics and Layout ................................... 11 Revision History ............................................................................... 2 1.8 V Output, 300 kHz, 14 A Application Circuit.................. 11 Evaluation Board Hardware ............................................................ 3 Layer 1.......................................................................................... 12 Setting Up the Evaluation Board ................................................ 3 Layer 2.......................................................................................... 13 Powering Up and Powering Down the Evaluation Board ....... 4 Layer 3.......................................................................................... 14 Enabling and Disabling the ADP1872/ADP1873 .................... 4 Layer 4.......................................................................................... 15 Evaluating the Performance of the ADP1872/ADP1873 ........ 4 Bill of Materials ............................................................................... 16 Modifying the Evaluation Board ................................................ 5 1.8 V Output, 300 kHz, 14 A Application Circuit.................. 16 REVISION HISTORY 12/13—Rev. 0 to Rev. A Deleted 3.3 V Fixed-Output Voltage Model ................... Universal Deleted Single-Input, 600 kHz Application Circuit Section and Figure 29............................................................................... 10 Updated ESD Caution and Legal Terms and Conditions ......... 18 3/10—Revision 0: Initial Version Rev. A | Page 2 of 20 ADP1872-EVALZ/ADP1873-EVALZ User Guide UG-057 EVALUATION BOARD HARDWARE Upon receipt of the ADP1872/ADP1873 evaluation board, the following criteria have already been determined: • • The IC is either the ADP1872 (forced pulse-width modulation [PWM]) or the ADP1873 (power saving mode [PSM]). The switching frequency is 300 kHz, 600 kHz, or 1 MHz. SETTING UP THE EVALUATION BOARD Before powering up the system, set up the evaluation board as follows to ensure that all passive and active components are properly soldered to the evaluation board: 1. 2. 3. 4. 5. 6. 7. Ensure that the Headers JP2 and J1 connections are correct for a given application (see Table 1 and the Headers JP2 and J1 section). Ensure that the main power supply (VIN) is off but set to 0 V, and then connect the main power supply to the evaluation board, connecting the positive terminal to TP_VIN1 and the negative terminal to TP_PGND. Optionally, place a current meter in series with the main power supply to monitor the input current. Ensure that the low input voltage supply (VDD) is off but set to 0 V, and then connect the low input voltage supply to the evaluation board, connecting the positive terminal to J1 and the negative terminal to TP_PGND. Ensure that the electronic load is turned off, and then connect the load to the evaluation board, connecting the positive terminal to TP_VOUT1 and the negative terminal to TP_PGND. Optionally, connect a power resistor of the appropriate value for your application across the TP_VOUT1 and TP_PGND terminals of the evaluation board. Optionally, to continually monitor VIN, VDD, and VOUT, solder SMB jacks to each of the following measuring points: VIN1, VOUT1, and VREG1 (see Figure 33). Table 1. Header Connections Header J1 Input Voltage (V) ≤5.5 >5.5 JP2 ≤5.5 >5.5 JP3 N/A Description of Connection Floating (no jumper), single input configuration. Connect to VDD (dual input configuration), and, optionally, add a voltmeter across J1 and TP_PGND to monitor the low input voltage. Jumper between VIN and VDD (single input configuration). Open (no jumper), dual input configuration. Jumper at all times. Headers JP2 and J1 When the power input voltage is greater than 5.5 V, the device is in dual input configuration. If this configuration is chosen, ensure that Header JP2 is open (no jumper), and connect J1 to VDD. Optionally, you can also add a voltmeter across J1 and TP_PGND to monitor the low input voltage. If the power input voltage is less than or equal to 5.5 V, the device is in single input configuration. In this case, a jumper can be placed on Header JP2 that connects VIN to VDD. If a jumper is used in this way, leave Header J1 floating (no jumper), and ensure that VIN does not exceed 5.5 V. Header JP3 Always put a jumper on Header JP3 to connect the high voltage input to Pin 1 (VIN) of the IC. High Input Voltage Power Source (VIN) Ensure that the main power supply equipment is turned off but set to 0 V before connecting the main power supply to the evaluation board. Place a current meter in series with this power supply to monitor the input current. Connect the positive terminal (+) of the power supply to the TP_VIN1 terminal of the evaluation board. Connect the negative terminal of the power supply (−) to the TP_PGND terminal of the evaluation board. Low Input Voltage Supply for Bias (VDD) Set the low input voltage supply to 0 V and make sure that it is turned off before connecting the positive terminal (+) to Jumper J1 of the evaluation board. Connect the negative terminal (−) to the TP_PGND terminal of the evaluation board. Output Terminal The output terminal (TP_VOUT1) of the ADP1872/ADP1873 evaluation board is equipped with a banana terminal plug similar to TP_VIN1 and TP_PGND. The evaluation board is designed to withstand load immediately upon power-up, but may be damaged if the load is not properly connected to TP_VOUT1. Ensure that the electronic load is turned off prior to connecting the positive terminal (+) and negative terminal (−) to the VOUT and TP_PGND terminals of the evaluation board, respectively. If a power resistor is used, connect this device across the TP_VOUT1 and TP_PGND terminals of the evaluation board. Ensure that proper current values for your application are programmed on the electronic load prior to activation and, if applicable, that the correct power resistor value for your application is in place before powering up the evaluation board. DC Voltmeter on VIN, VDD, and VOUT For more accurate dc measurements of VIN, VDD, and VOUT, add a dedicated voltmeter for each of these voltage nodes (resources permitting) to continually monitor VIN, VOUT, and VDD. This can be done by placing an SMB jack on VIN1, VOUT2, VREG1 (see Figure 33). Rev. A | Page 3 of 20 UG-057 ADP1872-EVALZ/ADP1873-EVALZ User Guide Placeholders for SMB jacks are integrated into each evaluation board to facilitate such connections. Therefore, to accurately measure VIN, connect the voltmeter’s positive terminal (+) to the node where the positive terminal of the high voltage input capacitors (C3 to C8) and the drain of Q1/Q2 meet, and connect the voltmeter’s negative terminal (−) to the node where the negative terminal of the input capacitors and the source terminal of Q3 meet. These SMB terminals are optimally placed to minimize unnecessary voltage drops that may otherwise produce inaccurate VIN dc measurements. Similarly, for output voltage (VOUT) dc measurements, a placeholder for an SMB terminal is positioned directly across the positive and negative terminals of the output capacitor that is farthest from the inductor terminal and source of Q3. For accurate low input voltage (VDD) dc measurements, an SMB terminal footprint is positioned as close as possible across C1, which is laid out near the VDD pin (Pin 5) and the PGND pin (Pin 7) of the ADP1872/ADP1873. POWERING UP AND POWERING DOWN THE EVALUATION BOARD After completing the procedure described in the Setting Up the Evaluation Board section, power up the evaluation board as follows: 1. 2. 3. 4. 5. Apply power to the VDD pin. Apply power to the VIN pin. Slowly increase the VDD supply while monitoring the current meter until VDD is equal to 5 V. Because VIN is 0 V, IDD should jump between 120 µA (when approaching the UVLO threshold of 2.65 V) to less than 1 mA until VDD is equal to 5 V. Do not exceed 5.5 V on VDD. No output (VOUT) regulation is expected yet because VIN is 0 V. Slowly increase VIN up to 12 V. When VIN is increased, VOUT begins regulating to the desired voltage setpoint (via the VOUT dedicated voltmeter). Continue to increase VIN up to 12 V. Do not exceed 20 V on VIN. Output voltage regulation should occur regardless of whether there is a load connected at the output. After the output voltage is in regulation with the desired input voltage, increase the electronic load to the desired value. To power down the evaluation board, 1. 2. voltage on this pin above the enable threshold of 285 mV, thus enabling the IC, which causes the output voltage to regulate. EVALUATING THE PERFORMANCE OF THE ADP1872/ADP1873 Verifying the Switching Waveform To verify the switching waveform, 1. 2. 3. 4. 5. 6. 7. The resultant switching waveform should be between 0 V and the value of VIN (that is, 12 V), and the jitter should be less than or equal to 100 ns. Observing the Output Voltage Ripple To observe the output voltage ripple, 1. 2. 3. 4. Power down VIN. Power down VDD. Ensure that the oscilloscope, probe tips, and ground loop clip are in good working condition; that the probe tips have been calibrated per the manufacturer’s instructions and are clear of debris and dirt; and that the ground loops do not have any breaks or peels. Set the operating mode of the respective oscilloscope to DC Coupling in the oscilloscope’s Channel menu. Set the bandwidth to its maximum value (≥150 MHz). Set the vertical scale to 5 V per division and the timescale (x-axis) to 1/(2 × fSW) per division, where fSW is the switching frequency of the evaluation board. Securely attach the ground loop clip onto the TP_PGND terminal of the evaluation board. Ideally, the loop should be as close as possible to the negative terminal of the high input voltage capacitors (C3 to C8) and to the source of MOSFET Q1. Land or securely attach the probe tip to the drain of Q1. Observe the subsequent switching waveform and jitter. Set the operating mode of the respective oscilloscope to AC Coupling in the oscilloscope’s Channel menu. Set the vertical scale to 100 mV per division and the timescale to 1/(2 × fSW). Securely attach the ground loop clip onto the TP_PGND terminal of the evaluation board. Ideally, the loop should be as close as possible to the negative terminal (−) of the farthest output capacitor from the inductor terminal, and the probe tip should touch the positive terminal (+) of the same output capacitor. Observe the output voltage ripple. Evaluating the Inductor Current Waveform To evaluate the inductor current waveform, ENABLING AND DISABLING THE ADP1872/ADP1873 1. The ADP1872/ADP1873 evaluation board has a placeholder for a switch (normally open) for the COMP/EN pin to allow you to enable (open) and disable (closed) the ADP1872/ADP1873 on the evaluation board. When closed, the switch shorts this pin to ground, disabling the ADP1872/ADP1873. When the switch is subsequently opened (released), the error amplifier brings the 2. 3. Rev. A | Page 4 of 20 Calibrate the current probe per the manufacturer’s instructions. Power up the system (see the Powering Up and Powering Down the Evaluation Board section). Solder a 3 inch wire loop (from 10 gauge to 14 gauge) between the source of Q1 and the inductor terminal. The current probe has a clamping mechanism and can clamp onto this wire to measure the current traveling through the wire. ADP1872-EVALZ/ADP1873-EVALZ User Guide 4. 5. 6. 7. Ensure that the current direction is toward the output voltage (TP_VOUT1) and that the clamp of the current probe is in the closed, or locked, position. Set the vertical scale to one-third of the total load current that the converter is designed to deliver. Set the timescale similar to how the switching and output ripple waveforms were set. Observe the inductor current waveform. UG-057 Observing Transient Response To observe the transient response, 1. 2. 3. Obtaining Efficiency Measurements To obtain more accurate efficiency measurements, 1. 2. 3. 4. Power down the device. Remove the 3 inch wire loop between the source of Q1 and the inductor terminal. Power up the device. Record the current and voltage readings. Efficiency is calculated based on the measurements made between the output and the input of the converter: η= VOUT × I OUT V IN × I IN where: VOUT is the dc voltage readout by the voltmeter that is connected to the SMB terminal of the evaluation board or by the voltmeter that is connected across the output capacitor that is located farthest from the inductor terminal. IOUT is the digital readout produced by the electronic load equipment. VIN is the dc voltage readout by the voltmeter. IIN is the current readout from the current meter in series between the high input voltage supply equipment and the TP_VIN1 terminal of the evaluation board. Assessing Line Regulation To assess the line regulation, 1. 2. Vary the high input voltage. Record the resultant changes on the dc level of the output voltage (VOUT). Evaluating Short-Circuit Protection To evaluate the self-protection scheme of the ADP1873 during output short-circuit events, 1. 2. Achieve steady state regulation. Short the voltage output (TP_VOUT1) to TP_PGND. The system then enters hiccup mode and remains in this mode until the violation disappears (see the ADP1872/ADP1873 data sheet for more details). MODIFYING THE EVALUATION BOARD For any given ADP1872/ADP1873 evaluation board, an ADP1872 or ADP1873 IC can be used interchangeably as long as the pretrimmed frequency setpoint is the same for both ICs. To maintain system stability throughout the entire load current range, one component (passive or active) cannot be modified without modifying the rest. Refer to the ADP1872/ADP1873 data sheet for information about how each of the following elements can be adjusted, keeping in mind that any change affects the entire system: • • • • Examining Load Regulation To examine the load regulation, 1. 2. Power up the system (see the Powering Up and Powering Down the Evaluation Board section). Solder a 3 inch wire loop (from 10 gauge to 14 gauge) between the source of Q1 and the inductor terminal. Record instances where the output transient is out of phase with the load. Such occurrences are caused by sudden changes in the output load current and can be recorded by capturing the inductor ripple current waveform and the output voltage ac transient using the single acquisition feature of the oscilloscope. Vary the load current through electronic load adjustments. Record the resultant changes on the dc level of the output voltage (VOUT). Rev. A | Page 5 of 20 Feedback resistor divider Inductor Output capacitor Compensation network • Output filter impedance (ZFILT) • Error amplifier output impedance (ZCOMP) • Error amplifier gain (GM) • Current-sense loop gain (GCS) • Programmable current-sense gain (ACS) • Valley current limit setting • Crossover frequency UG-057 ADP1872-EVALZ/ADP1873-EVALZ User Guide TYPICAL PERFORMANCE CHARACTERISTICS For the most up-to-date typical performance characteristics, see the ADP1872/ADP1873 data sheet. 100 95 VDD = 5.5V, VIN = 5.5V (PSM) VDD = 5.5V, VIN = 5.5V 1.815 90 1.813 VDD = 5.5V, VIN = 16.5V (PSM) VDD = 5.5V, VIN = 16.5V 65 VDD = 5.5V, VIN = 13V (PSM) 60 55 VDD = 3.6V, VIN = 3.6V 50 VDD = 5.5V, VIN = 13V 45 40 VDD = 3.6V, VIN = 5.5V 35 25 100 1k 10k 100k LOAD CURRENT (mA) VIN = 13V 1.807 1.805 1.803 WURTH IND: 744325120, L = 1.2µH, DCR: 2.0mΩ INFINEON FETS: BSC042N03MS G (UPPER/LOWER) TA = 25°C 30 1.809 1.801 0 4500 6000 7500 9000 10,500 12,000 13,500 15,000 Figure 6. Load Regulation Plot for fSW = 300 kHz, VOUT = 1.8 V 1.821 OUTPUT VOLTAGE (V) 1.816 1.811 1.806 1.801 1.796 VIN = 5.5V +125°C +25°C –40°C 1.791 VIN = 13V +125°C +25°C –40°C VIN = 16.5V +125°C +25°C –40°C 1.786 08548-010 EFFICIENCY (%) LOAD CURRENT (mA) 3000 LOAD CURRENT (mA) Figure 3. Efficiency—300 kHz, VOUT = 1.8 V 100 VDD = 5.5V, VIN = 5V (PSM) V = 5.5V, 95 VDD= 16.5V (PSM) IN 90 85 VDD = 5.5V, 80 VIN = 5V VDD = 5.5V, V = 5.5V, V = 16.5V 75 VIN = 13V DD IN V = 3.6V, V = 13V (PSM) DD IN 70 VDD = 3.6V, VIN = 16.5V 65 VDD = 5.5V, VIN = 13V 60 55 50 45 40 35 30 WURTH IND: 744303022, L = 0.22µH, DCR: 0.33mΩ INFINEON FETs: BSC042N03MS G (UPPER/LOWER) 25 TA = 25°C 20 1k 10k 100k 100 1500 08548-102 70 VIN = 16.5V 1.811 0 1500 3000 4500 6000 7500 9000 10,500 12,000 13,500 15,000 LOAD CURRENT (mA) Figure 4. Efficiency—1 MHz, VOUT = 1.8 V Figure 7. Output Voltage Accuracy—300 kHz, VOUT = 1.8 V 1.821 2.658 VDD = 5V TA = 25°C 2.657 1.816 1.811 UVLO (V) 2.655 1.806 NO LOAD 1.801 2.654 2.653 2.652 2.651 1.796 1.791 5.50 6.95 8.40 9.85 11.30 12.75 14.20 15.65 17.10 18.55 20.00 VIN (V) Figure 5. Line Regulation Plot for fSW = 300 kHz, VOUT = 1.8 V 2.649 –40 –20 0 20 40 60 80 TEMPERATURE (°C) Figure 8. UVLO vs. Temperature Rev. A | Page 6 of 20 100 120 08548-034 2.650 08548-101 OUTPUT VOLTAGE (V) 2.656 LOAD = 15A 08548-014 75 08548-005 EFFICIENCY (%) 80 OUTPUT VOLTAGE (V) 85 ADP1872-EVALZ/ADP1873-EVALZ User Guide UG-057 OUTPUT VOLTAGE OUTPUT VOLTAGE 2 1 INDUCTOR CURRENT 20A STEP 2 1 SW NODE SW NODE 3 3 LOW SIDE LOW SIDE CH2 5A Ω CH4 5V M400ns T 35.8% A CH2 3.90A 08548-043 CH1 50mV BW CH3 10V BW CH1 10A Ω CH3 20V CH2 200mV CH4 5V B W M2ms T 75.6% A CH1 3.40A 08548-046 4 4 Figure 12. Load Transient Step—PSM Enabled, 20 A (See Figure 28 for Application Circuit) Figure 9. Power Saving Mode (PSM) Operational Waveform, 100 mA OUTPUT VOLTAGE OUTPUT VOLTAGE 2 1 INDUCTOR CURRENT 20A POSITIVE STEP 2 SW NODE 1 SW NODE 3 3 LOW SIDE LOW SIDE CH2 5A Ω CH4 5V M4.0µs T 35.8% A CH2 3.90A 08548-044 CH1 50mV BW CH3 10V BW CH1 10A Ω CH3 20V CH2 200mV CH4 5V B W M20µs T 30.6% A CH1 3.40A 08548-047 4 4 Figure 13. Positive Step During Heavy Load Transient Behavior—PSM Enabled, 20 A, VOUT = 1.8 V (See Figure 28 for Application Circuit) Figure 10. PSM Waveform at Light Load, 500 mA OUTPUT VOLTAGE 2 4 OUTPUT VOLTAGE INDUCTOR CURRENT 20A NEGATIVE STEP 1 SW NODE 3 1 SW NODE LOW SIDE 3 CH4 100mV B W M400ns T 30.6% A CH3 Figure 11. CCM Operation at Heavy Load, 18 A (See Figure 28 for Application Circuit) 2.20V CH1 10A Ω CH3 20V CH2 200mV CH4 5V B W M20µs T 48.2% A CH1 3.40A 08548-048 CH1 5A Ω CH3 10V 08548-045 4 Figure 14. Negative Step During Heavy Load Transient Behavior—PSM Enabled, 20 A (See Figure 28 for Application Circuit) Rev. A | Page 7 of 20 UG-057 ADP1872-EVALZ/ADP1873-EVALZ User Guide OUTPUT VOLTAGE 4 1 OUTPUT VOLTAGE INDUCTOR CURRENT 2 20A STEP LOW SIDE LOW SIDE 1 4 2 SW NODE SW NODE CH2 5V CH4 200mV B W M2ms T 15.6% A CH1 6.20A 08548-049 CH1 10A Ω CH3 20V CH1 2V BW CH2 5A Ω CH3 10V CH4 5V M4ms T 49.4% A CH1 920mV 08548-052 3 3 Figure 18. Output Short-Circuit Behavior Leading to Hiccup Mode Figure 15. Load Transient Step—Forced PWM at Light Load, 20 A (See Figure 28 for Application Circuit) OUTPUT VOLTAGE 1 4 OUTPUT VOLTAGE INDUCTOR CURRENT 20A POSITIVE STEP 2 LOW SIDE 1 SW NODE 3 2 SW NODE LOW SIDE CH2 5V CH4 200mV B W M20µs T 43.8% A CH1 6.20A 08548-050 CH1 10A Ω CH3 20V CH1 5V BW CH2 10A Ω CH4 5V CH3 10V A CH2 8.20A Figure 19. Magnified Waveform During Hiccup Mode Figure 16. Positive Step During Heavy Load Transient Behavior—Forced PWM at Light Load, 20 A, VOUT = 1.8 V (See Figure 28 for Application Circuit) OUTPUT VOLTAGE 2 M10µs T 36.2% 08548-053 4 3 OUTPUT VOLTAGE 1 INDUCTOR CURRENT 20A NEGATIVE STEP 2 1 SW NODE LOW SIDE 4 3 SW NODE LOW SIDE CH2 200mV CH4 5V B W M10µs T 23.8% A CH1 5.60A CH1 2V BW CH2 5A Ω CH3 10V CH4 5V Figure 17. Negative Step During Heavy Load Transient Behavior—Forced PWM at Light Load, 20 A (See Figure 28 for Application Circuit) Rev. A | Page 8 of 20 M2ms T 32.8% A CH1 720mV Figure 20. Start-Up Behavior at Heavy Load, 18 A, 300 kHz (See Figure 28 for Application Circuit) 08548-054 CH1 10A Ω CH3 20V 3 08548-051 4 ADP1872-EVALZ/ADP1873-EVALZ User Guide UG-057 LOW SIDE TA = 25°C OUTPUT VOLTAGE 1 4 HIGH SIDE SW NODE INDUCTOR CURRENT 2 LOW SIDE 4 3 2 M SW NODE M4ms T 41.6% A CH1 720mV 08548-055 CH1 2V BW CH2 5A Ω CH3 10V CH4 5V CH2 5V CH4 2V CH3 5V MATH 2V 40ns Figure 21. Power-Down Waveform During Heavy Load M40ns T 29.0% A CH2 4.20V 08548-058 HS MINUS SW 3 Figure 24. Output Drivers and SW Node Waveforms LOW SIDE OUTPUT VOLTAGE TA = 25°C 16ns (tf, DRVL) 1 INDUCTOR CURRENT 4 22ns (tpdh, DRVH) HIGH SIDE 2 SW NODE 25ns (tr, DRVH) SW NODE 3 LOW SIDE 3 2 CH2 5A Ω CH4 5V M2µs T 35.8% A CH2 3.90A 08548-056 CH1 50mV BW CH3 10V BW Figure 22. Output Voltage Ripple Waveform During PSM Operation at Light Load, 2 A HS MINUS SW CH2 5V CH4 2V CH3 5V MATH 2V 40ns M40ns T 29.0% A CH2 4.20V 08548-059 M 4 Figure 25. Upper-Side Driver Rising and Lower-Side Falling Edge Waveforms, CIN = 4.3 nF (Upper-/Lower-Side MOSFET), QTOTAL = 27 nC (VGS = 4.4 V (Q1), VGS = 5 V (Q3) 18ns (tr, DRVL) LOW SIDE OUTPUT VOLTAGE 1 4 HIGH SIDE 24ns (tpdh, DRVL) LOW SIDE 4 HS MINUS SW SW NODE 11ns (tf, DRVH) SW NODE 3 2 3 M INDUCTOR CURRENT CH2 5A Ω CH4 2V M1ms T 63.2% A CH1 Figure 23. Soft Start and RES Detect Waveform 1.56V 08548-057 CH1 1V BW CH3 10V BW CH2 5V CH4 2V CH3 5V MATH 2V 20ns M20ns T 39.2% A CH2 4.20V 08548-060 TA = 25°C 2 Figure 26. Upper-Side Driver Falling and Lower-Side Rising Edge Waveforms, CIN = 4.3 nF (Upper-/Lower-Side MOSFET), QTOTAL = 27 nC (VGS = 4.4 V (Q1), VGS = 5 V (Q3) Rev. A | Page 9 of 20 UG-057 ADP1872-EVALZ/ADP1873-EVALZ User Guide TYPICAL APPLICATION CIRCUITS DUAL-INPUT, 300 kHz HIGH CURRENT APPLICATION CIRCUIT HIGH VOLTAGE INPUT VIN = 12V LOW VOLTAGE INPUT VDD = 5.0V JP2 5 C2 0.1µF VDD 10 C12 100nF C3 22µF Q1 C5 22µF 1.0µH 8 Q3 7 C6 22µF C7 22µF Q2 9 Q4 DRVL 6 C1 1µF C4 22µF R6 2Ω C13 1.5nF C20 270µF VOUT = 1.8V, 15A + + C21 270µF C22 270µF + C23 270µF + MURATA: (HIGH VOLTAGE INPUT CAPACITORS) 22µF, 25V, X7R, 1210 GRM32ER71E226KE15L PANASONIC: (OUTPUT CAPACITORS) 270µF (SP-SERIES) 4V, 7mΩ EEFUE0G271LR INFINEON MOSFETs: BSC042N03MS G (BOTTOM) BSC080N03MS G (TOP) WURTH INDUCTORS: 1µH, 3.3mΩ, 20A 7443552100 R5 100kΩ 08548-088 C11 JP3 ADP1872/ 571pF ADP1873 C10 R3 1 VIN BST 57pF 47kΩ 2 COMP/EN SW R1 30kΩ VOUT 3 FB DRVH R2 15kΩ 4 GND PGND Figure 27. Application Circuit for 12 V Input, 1.8 V Output, 15 A, 300 kHz (Q2/Q4 No Connect) LOW VOLTAGE INPUT VDD = 5V HIGH VOLTAGE INPUT VIN = 13V JP2 5 C2 0.1µF VDD 10 C12 100nF C3 22µF Q1 C5 22µF 0.8µH 8 Q3 C6 22µF C7 22µF Q2 9 7 C4 22µF Q4 DRVL 6 C1 1µF C20 R6 270µF 2Ω C13 1.5nF VOUT = 1.8V, 20A + C21 270µF + C22 270µF + C23 270µF + MURATA: (HIGH VOLTAGE INPUT CAPACITORS) 22µF, 25V, X7R, 1210 GRM32ER71E226KE15L PANASONIC: (OUTPUT CAPACITORS) 270µF (SP-SERIES) 4V, 7mΩ EEFUE0G271LR INFINEON MOSFETs: BSC042N03MS G (BOTTOM) BSC080N03MS G (TOP) WURTH INDUCTORS: 0.72µH, 1.65mΩ, 35A 744325072 Figure 28. Application Circuit for 13 V Input, 1.8 V Output, 20 A, 300 kHz (Q2/Q4 No Connect) Rev. A | Page 10 of 20 08548-090 C11 JP3 ADP1872/ 800pF ADP1873 C10 R3 1 VIN BST 80pF 33.5kΩ 2 COMP/EN SW R1 30kΩ VOUT 3 FB DRVH R2 15kΩ 4 GND PGND ADP1872-EVALZ/ADP1873-EVALZ User Guide UG-057 EVALUATION BOARD SCHEMATICS AND LAYOUT This section provides the schematics for the 1.8 V output, 300 kHz, 14 A application circuit. For other application circuits, see the ADP1872/ADP1873 data sheet for the recommended values for the external components. 1.8 V OUTPUT, 300 kHz, 14 A APPLICATION CIRCUIT HIGH VOLTAGE INPUT VIN = 13V LOW VOLTAGE INPUT VDD = 5.0V (J1 HEADER) TP_VIN1 (BANANA PLUG) JP2 (HEADER) VIN1 (SMB) C11 JP3 U1 571pF ADP1872 C10 R3 1 VIN BST 47kΩ FB1 (SMB) 57pF 2 COMP/EN SW R1 30kΩ VOUT 3 FB DRVH R2 15kΩ 4 GND PGND C1 1µF VREG1 (SMB) VDD C3 22µF Q1 7 C5 22µF C6 22µF C7 22µF L1 1.0µH R4 0kΩ DRVL 6 Q3 C8 N/A TP_VOUT1 (BANANA PLUG) VOUT2 (SMB) Q2 9 8 C4 22µF Q4 VOUT = 1.8V, 14A C20 270µF R6 2Ω C13 1.5nF C14 N/A R5 100kΩ + C21 270µF + C15 N/A C16 N/A C22 270µF + C17 N/A C23 270µF C18 N/A + C24 N/A + C19 N/A TP_PGND (BANANA PLUG) 08548-103 5 C2 0.1µF 10 C12 100nF Figure 29. 1.8 V Output, 300 kHz, 14 A Application Circuit Rev. A | Page 11 of 20 UG-057 ADP1872-EVALZ/ADP1873-EVALZ User Guide 08548-082 LAYER 1 Figure 30. Layer 1 Rev. A | Page 12 of 20 ADP1872-EVALZ/ADP1873-EVALZ User Guide UG-057 08548-083 LAYER 2 Figure 31. Layer 2 Rev. A | Page 13 of 20 UG-057 ADP1872-EVALZ/ADP1873-EVALZ User Guide 08548-084 LAYER 3 Figure 32. Layer 3 Rev. A | Page 14 of 20 ADP1872-EVALZ/ADP1873-EVALZ User Guide UG-057 08548-085 LAYER 4 Figure 33. Layer 4 Rev. A | Page 15 of 20 UG-057 ADP1872-EVALZ/ADP1873-EVALZ User Guide BILL OF MATERIALS 1.8 V OUTPUT, 300 kHz, 14 A APPLICATION CIRCUIT Table 2. Name CVDD CVDD CIN CIN CIN CIN CIN CIN CPAR CC CBST CSNUBBER COUT COUT COUT COUT COUT COUT COUT COUT COUT COUT COUT RTOP RBOT RC RGATE RRES RSNUBBER Top MOSFET Top MOSFET Bottom MOSFET Bottom MOSFET Inductor Header Header Header Banana Plugs Banana Plugs Banana Plugs Controller/Driver Diode 1 2 Reference Designator C1 C2 C3 C4 C5 C6 C7 C8 C10 C11 C12 C13 C14 C15 C16 C17 C18 C19 C20 C21 C22 C23 C24 R1 R2 R3 R4 R5 R6 Q1 Q2 Q3 Q4 L1 J1 JP2 JP3 TP_VIN1 TP_PGND TP_VOUT1 U1 D3 Value 1.0 0.1 22 22 22 22 22 N/A 57 571 100 1.5 N/A N/A N/A N/A N/A N/A 270 270 270 270 N/A 30 15 47 0 100 2 N/A N/A N/A N/A 1.0 N/A N/A N/A N/A N/A N/A N/A N/A Unit µF µF µF µF µF µF µF N/A pF pF nF nF N/A N/A N/A N/A N/A N/A µF µF µF µF N/A kΩ kΩ kΩ kΩ kΩ Ω N/A N/A N/A N/A µH N/A N/A N/A N/A N/A N/A N/A N/A Manufacturer Taiyo Yuden TDK Murata Murata Murata Murata Murata Description/Model 1.0 µF, 6.3 V, X5R ceramic capacitor (0402), JMK105BJ105KV-F 0.1 µF, 25 V, X5R ceramic capacitor (0402), C1005X5R1E104K 25 V, X7R, 1210 (3.2 mm × 2.5 mm × 2.5 mm) GRM32ER71E226KE15L 25 V, X7R, 1210 (3.2 mm × 2.5 mm × 2.5 mm) GRM32ER71E226KE15L 25 V, X7R, 1210 (3.2 mm × 2.5 mm × 2.5 mm) GRM32ER71E226KE15L 25 V, X7R, 1210 (3.2 mm × 2.5 mm × 2.5 mm) GRM32ER71E226KE15L 25 V, X7R, 1210 (3.2 mm × 2.5 mm × 2.5 mm) GRM32ER71E226KE15L Taiyo Yuden 1 Taiyo Yuden1 Taiyo Yuden1 Taiyo Yuden1 ±10%, 50 V, X7R ceramic capacitor (0402) ±5%, 50 V, C0H ceramic capacitor (0402) ±10%, 50 V, X7R ceramic capacitors (0603) ±10%, 50 V, X7R ceramic capacitors (0603) Panasonic Panasonic Panasonic Panasonic SP-series, 4 V, 7 mΩ, 3.7 A EEFUE0G271LR (4.3 mm × 7.3 mm × 4.2 mm) SP-series, 4 V, 7 mΩ, 3.7 A EEFUE0G271LR (4.3 mm × 7.3 mm × 4.2 mm) SP-series, 4 V, 7 mΩ, 3.7 A EEFUE0G271LR (4.3 mm × 7.3 mm × 4.2 mm) SP-series, 4 V, 7 mΩ, 3.7 A EEFUE0G271LR (4.3 mm × 7.3 mm × 4.2 mm) Vishay1 Vishay1 Vishay1 Vishay1 Vishay1 Vishay1 Infineon Infineon Infineon Infineon Würth Elek ±1% resistors (0603) ±1% resistors (0603) ±1% resistors (0603) ±1% resistors (0603) ±1% resistors (0603) ±1% resistors (0603) BSC080N03MS G BSC080N03MS G BSC080N03MS G BSC080N03MS G 7443251200 Analog Devices ADP1872ARMZ-0.3-R7 2 (LDT) or ADP1873ARMZ-0.3-R72 (LDF) Components from other manufacturers can also be used, as long as the characteristics listed in the corresponding description are met. Z = RoHS Compliant Part. Rev. A | Page 16 of 20 ADP1872-EVALZ/ADP1873-EVALZ User Guide NOTES Rev. A | Page 17 of 20 UG-057 UG-057 ADP1872-EVALZ/ADP1873-EVALZ User Guide NOTES Rev. A | Page 18 of 20 ADP1872-EVALZ/ADP1873-EVALZ User Guide NOTES Rev. A | Page 19 of 20 UG-057 UG-057 ADP1872-EVALZ/ADP1873-EVALZ User Guide NOTES ESD Caution ESD (electrostatic discharge) sensitive device. Charged devices and circuit boards can discharge without detection. Although this product features patented or proprietary protection circuitry, damage may occur on devices subjected to high energy ESD. Therefore, proper ESD precautions should be taken to avoid performance degradation or loss of functionality. Legal Terms and Conditions By using the evaluation board discussed herein (together with any tools, components documentation or support materials, the “Evaluation Board”), you are agreeing to be bound by the terms and conditions set forth below (“Agreement”) unless you have purchased the Evaluation Board, in which case the Analog Devices Standard Terms and Conditions of Sale shall govern. Do not use the Evaluation Board until you have read and agreed to the Agreement. Your use of the Evaluation Board shall signify your acceptance of the Agreement. This Agreement is made by and between you (“Customer”) and Analog Devices, Inc. (“ADI”), with its principal place of business at One Technology Way, Norwood, MA 02062, USA. Subject to the terms and conditions of the Agreement, ADI hereby grants to Customer a free, limited, personal, temporary, non-exclusive, non-sublicensable, non-transferable license to use the Evaluation Board FOR EVALUATION PURPOSES ONLY. Customer understands and agrees that the Evaluation Board is provided for the sole and exclusive purpose referenced above, and agrees not to use the Evaluation Board for any other purpose. Furthermore, the license granted is expressly made subject to the following additional limitations: Customer shall not (i) rent, lease, display, sell, transfer, assign, sublicense, or distribute the Evaluation Board; and (ii) permit any Third Party to access the Evaluation Board. As used herein, the term “Third Party” includes any entity other than ADI, Customer, their employees, affiliates and in-house consultants. The Evaluation Board is NOT sold to Customer; all rights not expressly granted herein, including ownership of the Evaluation Board, are reserved by ADI. CONFIDENTIALITY. This Agreement and the Evaluation Board shall all be considered the confidential and proprietary information of ADI. Customer may not disclose or transfer any portion of the Evaluation Board to any other party for any reason. Upon discontinuation of use of the Evaluation Board or termination of this Agreement, Customer agrees to promptly return the Evaluation Board to ADI. ADDITIONAL RESTRICTIONS. Customer may not disassemble, decompile or reverse engineer chips on the Evaluation Board. Customer shall inform ADI of any occurred damages or any modifications or alterations it makes to the Evaluation Board, including but not limited to soldering or any other activity that affects the material content of the Evaluation Board. Modifications to the Evaluation Board must comply with applicable law, including but not limited to the RoHS Directive. TERMINATION. ADI may terminate this Agreement at any time upon giving written notice to Customer. Customer agrees to return to ADI the Evaluation Board at that time. LIMITATION OF LIABILITY. THE EVALUATION BOARD PROVIDED HEREUNDER IS PROVIDED “AS IS” AND ADI MAKES NO WARRANTIES OR REPRESENTATIONS OF ANY KIND WITH RESPECT TO IT. ADI SPECIFICALLY DISCLAIMS ANY REPRESENTATIONS, ENDORSEMENTS, GUARANTEES, OR WARRANTIES, EXPRESS OR IMPLIED, RELATED TO THE EVALUATION BOARD INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTY OF MERCHANTABILITY, TITLE, FITNESS FOR A PARTICULAR PURPOSE OR NONINFRINGEMENT OF INTELLECTUAL PROPERTY RIGHTS. IN NO EVENT WILL ADI AND ITS LICENSORS BE LIABLE FOR ANY INCIDENTAL, SPECIAL, INDIRECT, OR CONSEQUENTIAL DAMAGES RESULTING FROM CUSTOMER’S POSSESSION OR USE OF THE EVALUATION BOARD, INCLUDING BUT NOT LIMITED TO LOST PROFITS, DELAY COSTS, LABOR COSTS OR LOSS OF GOODWILL. ADI’S TOTAL LIABILITY FROM ANY AND ALL CAUSES SHALL BE LIMITED TO THE AMOUNT OF ONE HUNDRED US DOLLARS ($100.00). EXPORT. Customer agrees that it will not directly or indirectly export the Evaluation Board to another country, and that it will comply with all applicable United States federal laws and regulations relating to exports. GOVERNING LAW. This Agreement shall be governed by and construed in accordance with the substantive laws of the Commonwealth of Massachusetts (excluding conflict of law rules). Any legal action regarding this Agreement will be heard in the state or federal courts having jurisdiction in Suffolk County, Massachusetts, and Customer hereby submits to the personal jurisdiction and venue of such courts. The United Nations Convention on Contracts for the International Sale of Goods shall not apply to this Agreement and is expressly disclaimed. ©2010–2013 Analog Devices, Inc. All rights reserved. Trademarks and registered trademarks are the property of their respective owners. UG08548-0-12/13(A) Rev. A | Page 20 of 20
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