PI3420-00-EVAL1

ZVS Regulators PI34xx-00-LGIZ 8 – 18VIN, 15A ZVS Buck Regulator Product Description Features & Benefits The PI34xx-00 is a family of high‑efficiency DC-DC ZVS Buck regulators integrating the controller, power switches and support components within a high-density System-in-Package (SiP). • High-efficiency ZVS Buck topology The PI34xx-00 is designed to achieve optimum efficiency at low input voltage ranges (8 – 18V). The utilization of zero‑current soft turn-on provided by the high‑performance ZVS topology within the PI34xx-00 series increases point‑of‑load performance, providing best in class power efficiency with high throughput power. • Very fast transient response The PI34xx-00 requires only an external inductor and minimal capacitors to form a complete DC-DC switching‑mode buck regulator. • Parallel capable with single‑wire current sharing Device Output Voltage • Input voltage range of 8 – 18V • Power-up into pre-biased load • High-accuracy pre-trimmed output voltage • User adjustable soft start & tracking • Input over/undervoltage lockout (OVLO/UVLO) • Output overvoltage protection (OVP) • Overtemperature Protection (OTP) IOUT Max Set Range PI3423-00-LGIZ 3.3V 2.3 – 4.1V 15A PI3424-00-LGIZ 5.0V 3.3 – 6.5V 15A • Fast and slow current limits • –40 to 125°C operating range (TINT) The ZVS architecture enables high‑frequency operation while minimizing switching losses and maximizing efficiency. The high‑switching‑frequency operation reduces the size of the external filtering components, improves power density, and enables very fast dynamic response to line and load transients. The ZVS architecture enables operation up to 750kHz while minimizing switching losses and the use of variable frequency extends high efficiency over a very wide dynamic range. The PI34xx-00 series has a minimum on time of 20ns which enables large step‑down conversion ratios. Applications • High-Efficiency Systems • Computing, Communications, Industrial, Automotive Equipment Package Information • 10 x 14 x 2.6mm LGA SiP Note: Product images may not highlight current product markings. ZVS Regulators Page 1 of 22 Rev 2.2 01/2022 PI34xx-00-LGIZ Contents Order Information 3 Application Description 15 Thermal, Storage and Handling Information 3 Output Voltage Trim 15 Absolute Maximum Ratings 3 Soft-Start Adjust and Tracking 16 Functional Block Diagram 4 Inductor Pairing 17 Pin Description 5 Thermal De-Rating 17 Package Pinout 6 Filter Considerations 17 PI3423-00-LGIZ (3.3VOUT ) Electrical Characteristics 7 PI3424-00-LGIZ (5.0VOUT ) Electrical Characteristics Layout Guidelines 18 10 Recommended PCB Footprint and Stencil 19 Thermal De-Rating Curves 13 Package Drawings 20 Functional Description 14 Product Warranty 22 Enable (EN) 14 Remote Sensing 14 Switching Frequency Synchronization 14 Output Voltage Trim 14 Output Current Limit Protection 14 Input Undervoltage Lockout 14 Input Overvoltage Lockout 14 Output Overvoltage Protection 15 Overtemperature Protection 15 Parallel Operation 15 Pulse Skip Mode (PSM) 15 Variable-Frequency Operation 15 ZVS Regulators Page 2 of 22 Rev 2.2 01/2022 PI34xx-00-LGIZ Order Information Product Output Range IOUT Max Package Transport Media 2.3 – 4.1V 15A 10 x 14mm 123-pin LGA TRAY 3.3 – 6.5V 15A 10 x 14mm 123-pin LGA TRAY Set Range PI3423-00-LGIZ 3.3V PI3424-00-LGIZ 5.0V Thermal, Storage and Handling Information Name Rating Storage Temperature –65 to 150°C Internal Operating Temperature –40 to 125°C Soldering Temperature for 20 seconds 245°C MSL Rating 3 ESD Rating 2kV HBM; 1.0kV CDM Absolute Maximum Ratings Name Rating VIN –0.7 to 22V VS1 –0.7 to 22V, 25V for 5ns, –4V for 5ns VOUT, REM See relevant product section SGND 100mA PWRGD, SYNCO, SYNCI, EN, EAO, ADJ, TRK, ADR1, ADR2, SCL, SDA, VDR –0.3 to 5.5V / 5mA Notes: At 25°C ambient temperature. Stresses beyond these limits may cause permanent damage to the device. Operation at these conditions or conditions beyond those listed in the Electrical Characteristics is not guaranteed. All voltage nodes are referenced to PGND unless otherwise noted. Test conditions are per the specifications within the individual product Electrical Characteristics. ZVS Regulators Page 3 of 22 Rev 2.2 01/2022 PI34xx-00-LGIZ Functional Block Diagram VIN VS1 VIN Q2 Q1 VOUT R4 REM Power Control R1 VCC + ZVS Control SYNCO SYNCI PWRGD EN PGND Memory Interface EAO ADJ 1V R2 TRK 0Ω ADR1 SDA ADR0 SCL SGND Simplified block diagram (I2C™ pins SCL, SDA, ADR0, and ADR1 are for factory use only. Not for use in application.) ZVS Regulators Page 4 of 22 Rev 2.2 01/2022 VOUT PI34xx-00-LGIZ Pin Description Name Location I/O Description SGND Block 1 I/O Signal Ground: Internal logic ground for EA, TRK, SYNCI, SYNCO and ADJ. SGND and PGND are star‑connected within the regulator package. PGND Block 2 Power Power Ground: VIN and VOUT power returns. VIN Block 3 Power Input Voltage: and sense for UVLO, OVLO and feed‑forward ramp. VOUT Block 5 Power Output Voltage: and sense for power switches and feed-forward ramp. VS1 Block 4 Power Switching Node: and ZVS sense for power switches. PWRGD A1 O Power Good: High-impedance when regulator is operating and output voltage is within approximately 80% of regulation set point; also can be used for parallel timing manangement intended for lead regulator. EAO A2 O Error Amp Output: External connection for additional compensation and current sharing. EN A3 I/O Enable Input: Regulator enable control. Asserted high or left floating: regulator enabled. Asserted low: regulator output disabled. REM A5 I Remote Sense: High‑side connection. Connect to output regulation point. ADJ B1 I Adjust Input: An external resistor may be connected between ADJ pin and SGND or VOUT to trim the output voltage up or down. TRK C1 I/O Soft-Start and Track Input: An external capacitor may be connected between TRK pin and SGND to decrease the rate of rise during soft start. NC A4 Open SYNCO K4 O Synchronization Output: Outputs a high signal for ½ of the minimum period for synchronization of other regulators. VDR K3 O Internally generated 5.1V for internal use. May be used externally provided it is impedance‑limited to prevent current in excess of 2mA under any circumstances. SYNCI K5 I Synchronization Input: Synchronize to the falling edge of external clock frequency. SYNCI is a high‑impedance digital input node and should always be connected to SGND when not in use. SDA D1 I/O Data Line: Connect to SGND. Factory use only. Not for use in application. SCL E1 I/O Clock Line: Connect to SGND. Factory use only. Not for use in application. ADR1 H1 I Tri-State Address: No connect. Factory use only. Not for use in application. ADR0 G1 I Tri-State Address: No connect. Factory use only. Not for use in application. ZVS Regulators Page 5 of 22 No Connect: Leave pins floating. Rev 2.2 01/2022 PI34xx-00-LGIZ Package Pinout A D E G K PGD/ PWRGD ADJ TRK SDA SCL SGND ADR0 ADR1 SGND SGND EAO SGND SGND SGND SGND SGND SGND SGND SGND SGND EN SGND SGND SGND SGND SGND SGND SGND SGND VDR NC SGND SGND PGND PGND PGND PGND PGND SYNCO PGND PGND PGND PGND PGND SYNCI REM VOUT VOUT VOUT VOUT PGND PGND PGND PGND PGND PGND VOUT VOUT VOUT VOUT PGND PGND PGND PGND PGND PGND PGND PGND PGND PGND PGND PGND PGND PGND PGND PGND PGND PGND PGND PGND PGND PGND PGND PGND PGND PGND PGND PGND PGND PGND PGND PGND PGND PGND PGND PGND VS1 VS1 VS1 VS1 VS1 VIN VIN VIN VIN VS1 VS1 VS1 VS1 VS1 VIN VIN VIN VIN VS1 VS1 VS1 VS1 VS1 VIN VIN VIN VIN PI34xx-00 Pin Block Name Group of pins SGND B2-4, C2-4, D2-3, E2-3, F1-3, G2-3, H2-3, J1-3, K1-2 PGND A8-10, B8-10, C8-10, D8-10, E4-10, F4-10, G4-10, H4-10, J4-10, K6-10 VIN G12-14, H12-14, J12-14, K12-14 VS1 A12-14, B12-14, C12-14, D12-14, E12-14 VOUT A6-7, B6-7, C6-7, D6-7 ZVS Regulators Page 6 of 22 Rev 2.2 01/2022 PI34xx-00-LGIZ PI3423-00-LGIZ (3.3VOUT) Electrical Characteristics Specifications apply for –40°C < TINT < 125°C, VIN = 12V, L1 = 150nH [a] unless other conditions are noted. Parameter Symbol Conditions Min Typ Max Unit 8 12 18 V Input Specifications Input Voltage VIN_DC [f] Input Current IIN_DC VIN = 12V, TC = 25°C, IOUT = 15A Input Current at Output Short (Fault-Condition Duty Cycle) IIN_Short 4.43 [b] A 10 Disabled 2.6 Input Quiescent Current IQ_VIN Input Voltage Slew Rate VIN_SR [b] VOUT_DC [b] 3.24 VOUT_DC [c] 2.3 Enabled (no load) mA mA 4 1 V/µs 3.30 3.36 V 3.3 4.1 V Output Specifications Output Voltage Total Regulation Output Voltage Trim Range Line Regulation ∆VOUT(∆VIN) Load Regulation ∆VOUT(∆IOUT) At 25°C, 8V < VIN < 18V 0.10 At 25°C, 0.5A < IOUT < 15A 0.10 % 17 mVP-P Output Voltage Ripple VOUT_AC IOUT = 7.5A, COUT = 8 x 100μF, 20MHz BW [d] Continuous Output Current Range IOUT_DC Refer to load current vs. ambient temperature curves Current Limit IOUT_CL % 15 18 A A Protection UVLO Start Threshold VUVLO_START UVLO Stop Hysteresis VUVLO_HYS OVLO Stop Threshold VOVLO OVLO Start Hysteresis VOVLO_HYS 7.10 7.60 8.00 0.36 19.0 20.75 V V 21.78 V 0.37 V Number of the switching-frequency cycles 128 Cycles tf +1% overdrive 500 ns Output Overvoltage Protection VOVP Above set VOUT 20 % Overtemperature Fault Threshold TOTP UVLO/OVLO Fault Delay Time UVLO/OVLO Response Time Overtemperature Restart Hysteresis tf_DLY 130 TOTP_HYS 135 30 [a] 140 ºC ºC All parameters reflect regulator and inductor system performance. Measurements were made using a standard PI34xx-00 evaluation board with 3 x 4in dimensions and 4 layer, 2oz copper. Refer to inductor pairing table within Application Description section for specific inductor manufacturer and value. [b] Regulator is assured to meet performance specifications by design, test correlation, characterization, and/or statistical process control. [c] Output current capability may be limited and other performance may vary from noted electrical characteristics when switching frequency or VOUT is modified. [d] Refer to output ripple plots. [e] Refer to switching frequency vs. load current curves. [f] Minimum 5V between V – V IN OUT must be maintained or a minimum load of 1mA required. ZVS Regulators Page 7 of 22 Rev 2.2 01/2022 PI34xx-00-LGIZ PI3423-00-LGIZ (3.3VOUT) Electrical Characteristics (Cont.) Specifications apply for –40°C < TINT < 125°C, VIN = 12V, L1 = 150nH [a] unless other conditions are noted. Parameter Symbol Conditions Min Typ Max Unit Timing Switching Frequency Fault Restart Delay fS [e] tFR_DLY 700 kHz 30 ms Sync In (SYNCI) Synchronization Frequency Range ∆fSYNCI SYNCI Threshold VSYNCI 2.5 V SYNCI Input Impedance ZSYNCI 100 kΩ Relative to set switching frequency [c] 50 110 % Sync Out (SYNCO) SYNCO High VSYNCO_HI Source 1mA SYNCO Low VSYNCO_LO Sink 1mA SYNCO Rise Time tSYNCO_RT 20pF load 10 ns SYNCO Fall Time tSYNCO_FT 20pF load 10 ns 4.5 V 0.5 V Soft Start and Tracking TRK Active Input Range VTRK Internal reference tracking range 0 1.2 V TRK Max Output Voltage VTRK_MAX TRK Enable Threshold VTRK_OV 20 40 62 mV ITRK –70 –50 –25 µA Charge Current (Soft–Start) Discharge Current (Fault) Soft-Start Time 1.2 ITRK_DIS tSS CTRK = 0µF TRK to EAIN Offset V 6.8 mA 2.2 ms 34 100 mV Enable High Threshold VEN_HI 0.9 1 1.1 V Low Threshold VEN_LO 0.7 0.8 0.9 V Threshold Hysteresis VEN_HYS 100 200 300 mV Enable Pull-Up Voltage (Floating, Unfaulted) VEN_PU With positive-logic EN polarity 2 V Enable Pull-Down Voltage (Floating, Faulted) VEN_PD With negative-logic EN polarity 0 V Source Current IEN_SO With positive-logic EN polarity –50 µA Sink Current IEN_SK With negative-logic EN polarity 50 µA [a] All parameters reflect regulator and inductor system performance. Measurements were made using a standard PI34xx-00 evaluation board with 3 x 4in dimensions and 4 layer, 2oz copper. Refer to inductor pairing table within Application Description section for specific inductor manufacturer and value. [b] Regulator is assured to meet performance specifications by design, test correlation, characterization, and/or statistical process control. [c] Output current capability may be limited and other performance may vary from noted electrical characteristics when switching frequency or VOUT is modified. [d] Refer to output ripple plots. [e] Refer to switching frequency vs. load current curves. [f] Minimum 5V between V – V IN OUT must be maintained or a minimum load of 1mA required. ZVS Regulators Page 8 of 22 Rev 2.2 01/2022 PI34xx-00-LGIZ PI3423-00-LGIZ (3.3VOUT) Electrical Characteristics (Cont.) 100 95 Efficiency (%) 90 85 80 75 70 65 60 55 50 0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 Output Current (A) VIN: 8V 12V 18V Figure 1 — Efficiency at 25ºC Figure 4 — Transient response: 7.5 – 15A, at 5A/µs Figure 2 — Short circuit test Figure 5 — Output ripple 12VIN 3.3VOUT at 15A; COUT = 8 x 100µF Switching Frequency (kHz) 800 700 600 500 400 300 200 100 0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 Output Current (A) VIN: 8V 12V Figure 3 — Switching frequency vs. load current ZVS Regulators Page 9 of 22 18V Figure 6 — Output ripple 12VIN 3.3VOUT at 7.0A; COUT = 8 x 100µF Rev 2.2 01/2022 PI34xx-00-LGIZ PI3424-00-LGIZ (5.0VOUT) Electrical Characteristics Specifications apply for –40°C < TINT < 125°C, VIN = 12V, L1 = 150nH [a] unless other conditions are noted. Parameter Symbol Conditions Min Typ Max Unit 8 12 18 V Input Specifications Input Voltage VIN_DC [f] Input Current IIN_DC VIN = 12V, TC = 25°C, IOUT = 15A Input Current at Output Short (Fault-Condition Duty Cycle) IIN_Short 6.57 [b] A 10 Disabled 2.6 Input Quiescent Current IQ_VIN Input Voltage Slew Rate VIN_SR [b] VOUT_DC [b] 4.93 VOUT_DC [c] 3.3 Enabled (no load) mA mA 4 1 V/µs 5.07 V 6.5 V Output Specifications Output Voltage Total Regulation Output Voltage Trim Range Line Regulation ∆VOUT(∆VIN) Load Regulation ∆VOUT(∆IOUT) At 25°C, 8V < VIN < 18V 5 0.10 % At 25°C, 0.5A < IOUT < 15A 0.10 % Output Voltage Ripple VOUT_AC IOUT = 7.5A, COUT = 8 x 100μF, 20MHz BW [d] 20.8 mVP-P Continuous Output Current Range IOUT_DC Refer to load current vs. ambient temperature curves Current Limit IOUT_CL 15 18 A A Protection UVLO Start Threshold VUVLO_START UVLO Stop Hysteresis VUVLO_HYS OVLO Stop Threshold VOVLO OVLO Start Hysteresis VOVLO_HYS 7.10 7.60 8.00 0.36 19.0 20.75 V V 21.78 V 0.37 V Number of the switching-frequency cycles 128 Cycles tf +1% overdrive 500 ns Output Overvoltage Protection VOVP Above set VOUT 20 % Overtemperature Fault Threshold TOTP UVLO/OVLO Fault Delay Time UVLO/OVLO Response Time Overtemperature Restart Hysteresis tf_DLY 130 TOTP_HYS 135 30 [a] 140 ºC ºC All parameters reflect regulator and inductor system performance. Measurements were made using a standard PI34xx-00 evaluation board with 3 x 4in dimensions and 4 layer, 2oz copper. Refer to inductor pairing table within Application Description section for specific inductor manufacturer and value. [b] Regulator is assured to meet performance specifications by design, test correlation, characterization, and/or statistical process control. [c] Output current capability may be limited and other performance may vary from noted electrical characteristics when switching frequency or VOUT is modified. [d] Refer to output ripple plots. [e] Refer to switching frequency vs. load current curves. [f] Minimum 5V between V – V IN OUT must be maintained or a minimum load of 1mA required. ZVS Regulators Page 10 of 22 Rev 2.2 01/2022 PI34xx-00-LGIZ PI3424-00-LGIZ (5.0VOUT) Electrical Characteristics (Cont.) Specifications apply for –40°C < TINT < 125°C, VIN = 12V, L1 = 150nH [a] unless other conditions are noted. Parameter Symbol Conditions Min Typ Max Unit Timing Switching Frequency Fault Restart Delay fS [e] tFR_DLY 750 kHz 30 ms Sync In (SYNCI) Synchronization Frequency Range ∆fSYNCI SYNCI Threshold VSYNCI 2.5 V SYNCI Input Impedance ZSYNCI 100 kΩ Relative to set switching frequency [c] 50 110 % Sync Out (SYNCO) SYNCO High VSYNCO_HI Source 1mA SYNCO Low VSYNCO_LO Sink 1mA SYNCO Rise Time tSYNCO_RT 20pF load 10 ns SYNCO Fall Time tSYNCO_FT 20pF load 10 ns 4.5 V 0.5 V Soft Start and Tracking TRK Active Input Range VTRK Internal reference tracking range 0 1.2 V TRK Max Output Voltage VTRK_MAX TRK Enable Threshold VTRK_OV 20 40 62 mV ITRK –70 –50 –25 µA Charge Current (Soft–Start) Discharge Current (Fault) Soft-Start Time 1.2 ITRK_DIS tSS CTRK = 0µF TRK to EAIN Offset V 6.8 mA 2.2 ms 34 100 mV Enable High Threshold VEN_HI 0.9 1 1.1 V Low Threshold VEN_LO 0.7 0.8 0.9 V Threshold Hysteresis VEN_HYS 100 200 300 mV Enable Pull-Up Voltage (Floating, Unfaulted) VEN_PU With positive-logic EN polarity 2 V Enable Pull-Down Voltage (Floating, Faulted) VEN_PD With negative-logic EN polarity 0 V Source Current IEN_SO With positive-logic EN polarity –50 µA Sink Current IEN_SK With negative-logic EN polarity 50 µA [a] All parameters reflect regulator and inductor system performance. Measurements were made using a standard PI34xx-00 evaluation board with 3 x 4in dimensions and 4 layer, 2oz copper. Refer to inductor pairing table within Application Description section for specific inductor manufacturer and value. [b] Regulator is assured to meet performance specifications by design, test correlation, characterization, and/or statistical process control. [c] Output current capability may be limited and other performance may vary from noted electrical characteristics when switching frequency or VOUT is modified. [d] Refer to output ripple plots. [e] Refer to switching frequency vs. load current curves. [f] Minimum 5V between V – V IN OUT must be maintained or a minimum load of 1mA required. ZVS Regulators Page 11 of 22 Rev 2.2 01/2022 PI34xx-00-LGIZ PI3424-00-LGIZ (5.0VOUT) Electrical Characteristics (Cont.) 100 95 Efficiency (%) 90 85 80 75 70 65 60 55 50 0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 Output Current (A) VIN: 8V 12V 18V Figure 7 — Efficiency at 25ºC Figure 10 — Transient response: 7.5 – 15A, at 5A/µs Figure 8 — Short circuit test Figure 11 — Output ripple 12VIN 5.0VOUT at 15A; COUT = 8 x 47µF Switching Frequency (kHz) 800 700 600 500 400 300 200 100 0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 Output Current (A) VIN: 8V 12V Figure 9 — Switching frequency vs. load current ZVS Regulators Page 12 of 22 18V Figure 12 — Output ripple 12VIN 5.0VOUT at 7.0A; COUT = 8 x 47µF Rev 2.2 01/2022 PI34xx-00-LGIZ 16 16 14 14 12 12 Load Current (A) Load Current (A) Thermal De-Rating Curves 10 8 6 4 2 10 8 6 4 2 0 0 25 35 45 55 65 75 85 95 105 25 115 35 Ambient Temperature (ºC) VIN: 8V 12V 55 65 75 85 95 105 115 Ambient Temperature (ºC) 18V VIN: Figure 13 — PI3423 – load current vs. ambient temperature, 0LFM ZVS Regulators Page 13 of 22 45 8V 12V 18V Figure 14 — PI3424 – load current vs. ambient temperature, 0LFM Rev 2.2 01/2022 PI34xx-00-LGIZ Functional Description Soft-Start The PI34xx-00 is a family of highly integrated ZVS Buck regulators. The PI34xx-00 has a set output voltage that is trimmable within a prescribed range shown in Table 1. Performance and maximum output current are characterized with a specific external power inductor (see Table 4). The PI34xx-00 includes an internal soft-start capacitor to ramp the output voltage in 2ms from 0V to full output voltage. Connecting an external capacitor from the TRK pin to SGND will increase the start-up ramp period. See, “Soft Start Adjustment and Track,” in the Applications Description section for more details. Output Voltage Trim The PI34xx-00 output voltage can be trimmed up from the preset output by connecting a resistor from ADJ pin to SGND and can be trimmed down by connecting a resistor from ADJ pin to VOUT. The Table 1 defines the voltage ranges for the PI34xx-00 family. L1 VIN VIN CIN PGND VS1 PI34xx VOUT VOUT COUT REM TRK SYNCO ADJ EN EAO SGND SYNCI Device For basic operation, Figure 15 shows the connections and components required. No additional design or settings are required. Enable (EN) EN is the enable pin of the regulator. The EN Pin is referenced to SGND and permits the user to turn the regulator on or off. The EN polarity is a positive logic assertion. If the EN pin is left floating or asserted high, the regulator output is enabled. Pulling EN pin below 0.8VDC with respect to SGND will disable the regulator output. Remote Sensing An internal 100Ω resistor is connected between REM pin and VOUT pin to provide regulation when the REM connection is broken. Referring to Figure 15, it is important to note that L1 and COUT are the output filter and the local sense point for the power supply output. As such, the REM pin should be connected at COUT as the default local sense connection unless remote sensing to compensate additional distribution losses in the system. The REM pin should not be left floating. Switching Frequency Synchronization The SYNCI input allows the user to synchronize the controller switching frequency by an external clock referenced to SGND. The external clock can synchronize the unit between 50 and 110% of the preset switching frequency (fS). ZVS Regulators Page 14 of 22 Set Range PI3423-00-LGIZ 3.3V 2.3 – 4.1V PI3424-00-LGIZ 5.0V 3.3 – 6.5V Table 1 — PI34xx-00 family output voltage ranges Figure 15 — ZVS Buck with required components The PI34xx-00 syncs to the falling edge of the applied clock providing 180° phase shift from SYNCO. This allows for the paralleling of two PI34xx-00 devices. When using the internal oscillator, the SYNCO pin provides a 5V clock that can be used to sync other regulators. Therefore, one PI34xx-00 can act as the lead regulator and have additional PI34xx-00s running in parallel and interleaved. Output Voltage Output Current Limit Protection PI34xx-00 has two methods implemented to protect from output short or overcurrent condition. Slow Current Limit protection: prevents the output load from sourcing current higher than the regulator’s maximum rated current. If the output current exceeds the Current Limit (IOUT_CL) for 1024µs, a slow current limit fault is initiated and the regulator is shut down which eliminates output current flow. After Fault Restart Delay (tFR_DLY ), a soft-start cycle is initiated. This restart cycle will be repeated indefinitely until the excessive load is removed. Fast Current Limit protection: PI34xx-00 monitors the regulator inductor current pulse-by-pulse to prevent the output from supplying very high current due to sudden low impedance short (50A typical). If the regulator senses a high inductor current pulse, it will initiate a fault and stop switching until Fault Restart Delay ends and then initiate a soft-start cycle. Input Undervoltage Lockout If VIN falls below the input Undervoltage Lockout (UVLO) threshold, the regulator will enter a low‑power state and initiate a fault. The system will restart once the input voltage is reestablished and after the Fault Restart Delay. Input Overvoltage Lockout If VIN exceeds the input Overvoltage Lockout (OVLO) threshold (VOVLO), while the regulator is running, the PI34xx-00 will complete the current cycle and stop switching. The system will resume operation after the Fault Restart Delay. Rev 2.2 01/2022 PI34xx-00-LGIZ Output Overvoltage Protection The PI34xx-00 family is equipped with output Overvoltage Protection (OVP) to prevent damage to input voltage sensitive devices. If the output voltage exceeds 20% of its set regulated value, the regulator will complete the current cycle, stop switching and issue an OVP fault. The system will resume operation once the output voltage falls below the OVP threshold and after Fault Restart Delay. Overtemperature Protection The internal package temperature is monitored to prevent internal components from reaching their thermal maximum. If the Overtemperature Protection Threshold (OTP) is exceeded (TOTP), the regulator will complete the current switching cycle, enter a low‑power mode, set a fault flag, and will soft start when the internal temperature falls below Overtemperature Restart (TOTP_HYS). Parallel Operation Paralleling modules can be used to increase the output current capability of a single power rail and reduce output voltage ripple. VIN VIN CIN SYNCO(#2) R1 SYNCI(#2) EN(#2) VS1 PGND SGND L1 VS1 PGND Each PI34xx-00 is preprogrammed to a base operating frequency, with respect to the power stage inductor (see Table 4), to operate at peak efficiency across line and load variations. At low‑line and high‑load applications, the base frequency will decrease to accommodate these extreme operating ranges. By stretching the frequency, the ZVS operation is preserved throughout the total input line voltage range therefore maintaining optimum efficiency. The PI34xx-00 family of buck regulators provides five common output voltages: 1.0, 1.8, 2.5, 3.3 and 5.0V. A post-package trim step is implemented to offset any resistor divider network errors ensuring maximum output accuracy. With a single resistor connected from the ADJ pin to SGND or REM, each device’s output can be varied above or below the nominal set voltage (the PI3420‑00 can only be adjusted above the set voltage of 1V). EN VIN Variable-Frequency Operation Output Voltage Trim SYNCO TRK PI34xx-00 features a PSM to achieve high efficiency at light loads. The regulators are set up to skip pulses if EAO falls below a PSM threshold. Depending on conditions and component values, this may result in single pulses or several consecutive pulses followed by skipped pulses. Skipping cycles significantly reduces gate drive power and improves light load efficiency. The regulator will leave PSM once the EAO rises above the Skip Mode threshold. Application Description SYNCI TRK(#2) Pulse Skip Mode (PSM) VOUT COUT ZVS Buck (#1) REM EAO CIN VOUT PWRGD EAO(#2) VIN L1 synchronization. Once the regulators reach regulation, SYNCI is released and the system is now synchronized in a closed-loop configuration which allows the system to adjust on the fly, when any of the individual regulators begin to enter variable frequency mode in the loop. VOUT COUT ZVS Buck (#2) REM PWRGD SYNCO(#1) SYNCI(#1) EN(#1) SYNCI Device SYNCO Set Range PI3423-00-LGIZ 3.3V 2.3 – 4.1V PI3424-00-LGIZ 5.0V 3.3 – 6.5V EN EAO(#1) EAO TRK(#1) TRK SGND Output Voltage Figure 16 — PI34xx-00 parallel operation Table 2 — PI34xx-00 family output voltage ranges By connecting the EAO pins and SGND pins of each module together the units will share the current equally. When the TRK pins of each unit are connected together, the units will track each other during soft start and all unit EN pins have to be released to allow the units to start (See Figure 16). Also, any fault event in any regulator will disable the other regulators. The two regulators will be out of phase with each other reducing output ripple (refer to Switching Frequency Synchronization). The remote pin (REM) should always be connected to the VOUT pin to prevent an output voltage offset. Figure 17 shows the internal feedback voltage‑divider network. To provide synchronization between regulators over the entire operational frequency range, the Power Good (PWRGD) pin must be connected to the lead regulator’s (#1) SYNCI pin and a 2.5kΩ Resistor, R1, must be placed between SYNCO (#2) return and the lead regulator’s SYNCI (#1) pin, as shown in Figure 16. In this configuration, at system soft start, the PWRGD pin pulls SYNCI low forcing the lead regulator to initialize the open-loop start‑up ZVS Regulators Page 15 of 22 Rev 2.2 01/2022 PI34xx-00-LGIZ Resistor RHIGH should be connected as shown in Figure 17 to achieve the desired 4.0V regulator output. No external RLOW resistor is need in this design example since the trim is above the regulator set voltage. VOUT The PI3420 output voltage can only be trimmed higher than the factory 1V setting. The following Equation 3 can be used calculate RHIGH values for the PI3420 regulators. R4 REM R1 RLOW ADJ - RHIGH(1V) = + RHIGH R2 1.0VDC SGND The TRK pin offers a means to increase the regulator’s soft-start time or to track with additional regulators. The soft‑start slope is controlled by an internal capacitor and a fixed charge current to provide a Soft-Start Time tSS for all for all PI34xx-00 regulators. By adding an additional external capacitor to the TRK pin, the soft‑start time can be increased further. The following equation can be used to calculate the proper capacitor for a desired soft-start times: R1, R2, and R4 are all internal 1.0% resistors and RLOW and RHIGH are external resistors for which the designer can add to modify VOUT to a desired output. The internal resistor values for each regulator are listed next in Table 3. Device R1 R2 R4 PI3423-00-LGIZ 2.61kΩ 1.13kΩ 100Ω PI3424-00-LGIZ 4.53kΩ 1.13kΩ 100Ω CTRK = (tTRK • ITRK) – 100 x 10–9, where, tTRK is the soft-start time and ITRK is a 50µA internal charge current (see Electrical Characteristics for limits). Table 3 — PI34xx-00 internal divider values There is typically either a proportional or direct tracking method implemented within a tracking design. For proportional tracking between several regulators at start up, simply connect all devices TRK pins together. This type of tracking will force all connected regulators to start up and reach regulation at the same time (see Figure 18 (a)). By choosing an output voltage value within the ranges stated in Table 2, VOUT can simply be adjusted up or down by selecting the proper RHIGH or RLOW value, respectively. The following equations can be used to calculate RHIGH and RLOW values: RLOW = 1 (VOUT – 1) – 1 R1 R2 1 1 R2(VOUT – 1) – For Direct Tracking, choose the regulator with the highest output voltage as the parent and connect the parent TRK pin to the TRK pin of the other regulators through a divider (Figure 19) with the same ratio as the child’s feedback divider (see Table 3 for values). (1) ( ) 1 R1 (2) VOUT 1 VOUT 2 If, for example, a 4.0V output is needed, the user should choose the regulator with a trim range covering 4.0V from Table 2. For this example, the PI3423 is selected (3.3V set voltage). First step would be to use Equation 1 to calculate RHIGH since the required output voltage is higher than the regulator set voltage. The resistor-divider network values for the PI3423 can be found in Table 3 and are (a) Parent VOUT VOUT 2 R1 = 2.61kΩ and R2 = 1.13kΩ. Inserting these values into Equation 1, RHIGH is calculated as follows: 3.78k = 1 (4.0 – 1) 2.61k – 1 1.13 (3) Soft-Start Adjust and Tracking Figure 17 — Internal resistor divider network RHIGH = 1 V ( OUT – 1) R1 (b) t Figure 18 — PI34xx-00 tracking methods All connected regulators’ soft-start slopes will track with this method. Direct tracking timing is demonstrated in Figure 18 (b). ZVS Regulators Page 16 of 22 Rev 2.2 01/2022 PI34xx-00-LGIZ Thermal De-Rating Thermal de-rating curves are provided that are based on component temperature changes versus load current, input voltage and air flow. It is recommended to use these curves as a guideline for proper thermal de-rating. These curves represent the entire system and are inclusive to both the Vicor regulator and the external inductor. Maximum thermal operation is limited by either the MOSFETs or inductor depending upon line and load conditions. Parent VOUT R1 PI34xx TRK Child Thermal measurements were made using a standard PI34xx-00 evaluation board which is 3 x 4 inches in area and uses 4-layer, 2oz copper. Thermal measurements were made on the three main power devices, the two internal MOSFETs and the external inductor. R2 SGND Filter Considerations Figure 19 — Voltage divider connections for direct tracking All tracking regulators should have their Enable (EN) pins connected together to work properly. Inductor Pairing The PI34xx-00 utilizes an external inductor from Eaton Corporation. This inductor has been optimized for maximum efficiency performance. Table 4 details the specific inductor value and part number utilized for each PI34xx-00 device. Data sheets are available at: www.eaton.com.­ Device Inductor (nH) Inductor Part Number Manufacturer PI3423-00 150 FPV1006-150-R Eaton PI3424-00 150 FPV1006-150-R Eaton Table 4 — PI34xx-00 inductor pairing Device VIN (V) PI3423 12 PI3424 12 ILOAD (A) 15 7.5 15 7.5 The PI34xx-00 requires input bulk storage capacitance as well as low‑impedance ceramic X5R input capacitors to ensure proper start up and high-frequency decoupling for the power stage. The PI34xx-00 will draw nearly all of the high‑frequency current from the low‑impedance ceramic capacitors when the main high‑side MOSFET is conducting. During the time the high-side MOSFET is off, they are replenished from the bulk capacitor. If the input impedance is high at the switching frequency of the regulator, the bulk capacitor must supply all of the average current into the regulator, including replenishing the ceramic capacitors. This value has been chosen to be 100µF so that the PI34xx-00 can start up into a full resistive load and supply the output capacitive load with the default minimum soft‑start capacitor when the input source impedance is 50Ω at 1MHz. The ESR for this capacitor should be approximately 20mΩ. The RMS ripple current in this capacitor is small, so it should not be a concern if the input recommended ceramic capacitors are used. Table 5 shows the recommended input and output capacitors to be used for the various models as well as expected transient response, RMS ripple currents per capacitor, and input and output ripple voltages. Table 6 includes the recommended input and output ceramic capacitors. CINPUT Bulk Electrolytic CINPUT Ceramic X5R COUTPUT Ceramic X5R CINPUT Ripple Current (IRMS) COUTPUT Ripple Current (IRMS) 100µF 50V 6 x 22µF 8 x 100µF 2 x 1µF 1 x 0.1µF 1.20 1.15 100µF 50V 6 x 22µF 8 x 100µF 2 x 1µF 1 x 0.1µF 1.29 1.13 Table 5 — Recommended input and output capacitance ZVS Regulators Page 17 of 22 Rev 2.2 01/2022 Input Ripple (mVP-P) Output Ripple (mVP-P) 179 26 97 17 209 34 98 24.8 Output Ripple (mVPK) Recovery Load Step Time (A) (µs) [Slew/µs] ±73 70 7.5 [5A/µs] ±98 60 7.5 [5A/µs] PI34xx-00-LGIZ Murata Part Number Description GRM188R71C105KA12D 1µF 16V 0603 X7R GRM319R71H104KA01D 0.1µF 50V 1206 X7R GRM31CR60J107ME39L 100µF 6.3V 1206 X5R GRM31CR61A476ME15L 47µF 10V 1206 X5R GRM31CR61E226KE15L 22µF 25V 1206 X5R When Q1 is on and Q2 is off, the majority of CIN’s current is used to satisfy the output load and to recharge the COUT capacitors. When Q1 is off and Q2 is on, the load current is supplied by the inductor and the COUT capacitor as shown in Figure 22. During this period CIN is also being recharged by the VIN. Minimizing CIN loop inductance is important to reduce peak voltage excursions when Q1 turns off. Also, the difference in area between the CIN loop and COUT loop is vital to minimize switching and GND noise. Table 5 — Capacitor manufacturer part numbers Layout Guidelines To achieve maximum efficiency and low‑noise performance from a PI34xx-00 design, layout considerations are necessary. Reducing trace resistance and minimizing high‑current loop returns along with proper component placement will contribute to optimal performance. VIN A typical buck regulator circuit is shown in Figure 20. The potential areas of high parasitic inductance and resistance are the circuit return paths, shown as LR below. CIN COUT Figure 22 — Current flow: Q2 closed VIN COUT CIN The recommended component placement, shown in Figure 23, illustrates the tight path between CIN and COUT (and VIN and VOUT ) for the high AC return current. This optimized layout is used on the PI34xx-00 evaluation board. VOUT COUT Figure 20 — Typical buck regulator GND The path between the COUT and CIN capacitors is of particular importance since the AC currents are flowing through both of them when Q1 is turned on. CIN VIN Figure 21, schematically, shows the reduced trace length between input and output capacitors. The shorter path lessens the effects that copper trace parasitics can have on the PI34xx-00 performance. VIN CIN GND Figure 23 — Recommended component placement and metal routing COUT Figure 21 — Current flow: Q1 closed ZVS Regulators Page 18 of 22 VSW Rev 2.2 01/2022 PI34xx-00-LGIZ Recommended PCB Footprint and Stencil L PI34xx-00 L Recommended receiving footprint for PI34xx‑00 10 x 14mm package. All pads should have a final copper size of 0.55 x 0.55mm, whether they are solder-mask defined or copper defined, on a 1 x 1mm grid. All stencil openings are 0.45mm when using either a 5 or 6mil stencil. ZVS Regulators Page 19 of 22 Rev 2.2 01/2022 PI34xx-00-LGIZ Package Drawings A K G E D A D B E DETAIL A M L DETAIL B A SEATING PLANE METALLIZED PAD M M A M SOLDER MASK DETAIL A A L D E AND POSITION ZVS Regulators Page 20 of 22 Rev 2.2 01/2022 A PI34xx-00-LGIZ Revision History Revision Date 1.0 02/13 1.1 08/03/15 Description Last release in old format n/a Reformatted in new template n/a 1.2 09/03/15 Inductor pairing table updates 1.3 12/21/15 Clarifications made in Enable Pin Conditions 02/03/20 Formatting changes Changed PGD pin name to PWRGD Removed continuous output current range min Corrected UVLO stop hysteresis, OVLO stop threshold, OVLO start hysteresis Updated sink current Added TRK to EAIN offset spec, revised soft-start charge current, TRK enable threshold Updated input quiescent current enabled Updated output voltage total regulation Updated mechanical drawings 1.4 1.5 02/26/20 Added CDM ESD rating 1.6 05/14/20 Corrected REM absolute maximum rating 1.7 08/11/20 Updated terminology 1.8 12/31/20 Removed end-of-life part numbers (for PI3420-00, PI3421-00 and PI3422-00 data, see separate document) Revised PI3424-00 switching frequency vs. load current plot 1.9 01/04/21 Revised switching frequency typical specification 2.0 02/24/21 Revised UVLO start threshold Added SYNCI input impedance specification 2.1 09/01/21 Corrected figure 1 plot 01/14/22 Corrections to figures 1, 2, 4, 7, 8, 10 removed irrelevant figures 2.2 6, 7 & 25 7, 8, 11, 14, 17 & 28 All 3, 4, 5, 7 7, 10, 13, 16, 19 8 8, 11, 14, 17, 20 10 10, 16 28, 29 3 3 25, 26 1–3 12 11 7, 10 8, 11 9 Note: page added in Rev 1.4, pages removed in Rev 1.8. ZVS Regulators Page 21 of 22 Page Number(s) Rev 2.2 01/2022 9, 12 13 PI34xx-00-LGIZ Vicor’s comprehensive line of power solutions includes high density AC-DC and DC-DC modules and accessory components, fully configurable AC-DC and DC-DC power supplies, and complete custom power systems. Information furnished by Vicor is believed to be accurate and reliable. However, no responsibility is assumed by Vicor for its use. Vicor makes no representations or warranties with respect to the accuracy or completeness of the contents of this publication. Vicor reserves the right to make changes to any products, specifications, and product descriptions at any time without notice. Information published by Vicor has been checked and is believed to be accurate at the time it was printed; however, Vicor assumes no responsibility for inaccuracies. Testing and other quality controls are used to the extent Vicor deems necessary to support Vicor’s product warranty. Except where mandated by government requirements, testing of all parameters of each product is not necessarily performed. Specifications are subject to change without notice. Visit http://www.vicorpower.com/dc-dc-converters-board-mount/cool-power-pi33xx-and-pi34xx for the latest product information. Vicor’s Standard Terms and Conditions and Product Warranty All sales are subject to Vicor’s Standard Terms and Conditions of Sale, and Product Warranty which are available on Vicor’s webpage (http://www.vicorpower.com/termsconditionswarranty) or upon request. Life Support Policy VICOR’S PRODUCTS ARE NOT AUTHORIZED FOR USE AS CRITICAL COMPONENTS IN LIFE SUPPORT DEVICES OR SYSTEMS WITHOUT THE EXPRESS PRIOR WRITTEN APPROVAL OF THE CHIEF EXECUTIVE OFFICER AND GENERAL COUNSEL OF VICOR CORPORATION. As used herein, life support devices or systems are devices 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. A critical component is any component in 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. Per Vicor Terms and Conditions of Sale, the user of Vicor products and components in life support applications assumes all risks of such use and indemnifies Vicor against all liability and damages. Intellectual Property Notice Vicor and its subsidiaries own Intellectual Property (including issued U.S. and Foreign Patents and pending patent applications) relating to the products described in this data sheet. No license, whether express, implied, or arising by estoppel or otherwise, to any intellectual property rights is granted by this document. Interested parties should contact Vicor’s Intellectual Property Department. The products described on this data sheet are protected by U.S. Patents. Please see www.vicorpower.com/patents for the latest patent information. Contact Us: http://www.vicorpower.com/contact-us Vicor Corporation 25 Frontage Road Andover, MA, USA 01810 Tel: 800-735-6200 Fax: 978-475-6715 www.vicorpower.com email Customer Service: custserv@vicorpower.com Technical Support: apps@vicorpower.com ©2018 – 2022 Vicor Corporation. All rights reserved. The Vicor name is a registered trademark of Vicor Corporation. I2C™ is a trademark of NXP semiconductor. All other trademarks, product names, logos and brands are property of their respective owners. ZVS Regulators Page 22 of 22 Rev 2.2 01/2022