DCM3623T50M13C2M00

DCM™ DC-DC Converter DCM3623x50M13C2yzz ® C S US  C NRTL US Isolated, Regulated DC Converter Features & Benefits Product Ratings • Isolated, regulated DC-DC converter • Up to 320W, 26.67A continuous • 92.9% peak efficiency • 823W/in3 VIN = 16 – 50V POUT = 320W VOUT = 12.0V (7.2 – 13.2V Trim) IOUT = 26.67A Power density • Wide input range 16 – 50VDC Product Description • Safety Extra Low Voltage (SELV) 12.0V Nominal Output The DCM Isolated, Regulated DC Converter is a DC-DC converter, operating from an unregulated, wide‑range input to generate an isolated 12.0VDC output. With its high‑frequency zero‑voltage switching (ZVS) topology, the DCM converter consistently delivers high efficiency across the input line range. Modular DCM converters and downstream DC-DC products support efficient power distribution, providing superior power system performance and connectivity from a variety of unregulated power sources to the point-of-load. • 2250VDC isolation • ZVS high-frequency switching „ Enables low-profile, high-density filtering • Optimized for array operation „ Up to 8 units – 2560W „ No power de-rating needed „ Sharing strategy permits dissimilar line voltages across an array • Fully operational current limit • OV, OC, UV, short circuit and thermal shut down • Military standard compliance: „ MIL-STD-810G Leveraging the thermal and density benefits of Vicor ChiP™ packaging technology, the DCM module offers flexible thermal management options with very low top and bottom side thermal impedances. Thermally-adept ChiP-based power components enable customers to achieve cost effective power system solutions with previously unattainable system size, weight and efficiency attributes, quickly and predictably. „ MIL-STD-202G Package Information „ MIL-STD-704E/F (DC power characteristics only) • Through-hole ChiP package „ MIL-STD-461E/F/G (Please contact Vicor Applications Engineering) „ 1.524 x 0.898 x 0.284in [38.72 x 22.80 x 7.21mm] „ MIL-STD-1275E (Applicable only for 16 – 50VIN range designs; please contact Vicor Applications Engineering) „ Weight: 24.0g [0.85oz] Typical Applications • Industrial • Process Control • Transportation / Heavy Equipment • Defense / Aerospace Note: Product images may not highlight current product markings. DCM™ DC-DC Converter Page 1 of 28 Rev 1.7 03/2022 DCM3623x50M13C2yzz Typical Applications DCM1 TR EN EMI_GND L1_1 F1_1 CY +IN VIN C1_1 Lb_1 Rdm_1 FT CY L2_1 +OUT Rd_1 RCOUT-EXT_1 Cd_1 COUT-EXT_1 –IN –OUT C2_1 C3 C4 Load CY CY DCM2 TR EN L1_2 F1_2 CY +IN C1_2 Lb_2 Rdm_2 FT CY L2_2 +OUT Rd_2 RCOUT-EXT_2 Cd_2 COUT-EXT_2 –IN –OUT CY CY ≈≈ C2_2 ≈≈ DCM4 TR EN L1_4 F1_4 CY +IN C1_4 Lb_4 Rdm_4 FT CY L2_4 +OUT RCOUT-EXT_4 Rd_4 Cd_4 –IN C2_4 COUT-EXT_4 –OUT CY CY Typical application 1: DCM3623x50M13C2yzz in an array of four units DCM TR EMI_GND EN FT F1 CY L1 VIN CY +IN C1 Rdm +OUT Rd RCOUT-EXT Cd COUT-EXT –IN –OUT CY Load 1 Lb L2 CY C2 Non-isolated Point-of-Load Regulator Load 2 Typical application 2: single DCM3623x50M13C2yzz, to a non-isolated regulator, and direct to load DCM™ DC-DC Converter Page 2 of 28 Rev 1.7 03/2022 DCM3623x50M13C2yzz Typical Applications (Cont.) DCM1 TR EMI_GND EN FT F1_1 CY CY T1_1 VIN C1_1 +IN +OUT –IN –OUT CY Lb_1 L2_1 RCOUT-EXT_1 Rd_1 Cd_1 Rdm_1 C2_1 COUT-EXT_1 C3 C4 Load CY DCM2 TR EN FT F1_2 CY T1_2 C1_2 CY +IN +OUT –IN –OUT CY Lb_2 L2_2 RCOUT-EXT_2 Rd_2 Cd_2 Rdm_2 C2_2 COUT-EXT_2 CY ≈≈ ≈≈ DCM8 TR EN FT F1_8 CY T1_8 CY +IN C1_8 +OUT Lb_8 Rdm_8 L2_8 Rd_8 RCOUT-EXT_8 Cd_8 COUT-EXT_8 –IN CY C2_8 –OUT CY Typical application 3: parallel operation of DCMs with common-mode chokes installed on the input side to suppress common-mode noise DCM™ DC-DC Converter Page 3 of 28 Rev 1.7 03/2022 DCM3623x50M13C2yzz Pin Configuration TOP VIEW 1 2 +IN A A’ +OUT B’ –OUT TR B EN C C’ +OUT FT D –IN E D’ –OUT DCM ChiP™ Pin Descriptions Pin Number Signal Name Type Function A1 +IN INPUT POWER B1 TR INPUT Enables and disables trim functionality; adjusts output voltage when trim active C1 EN INPUT Enables and disables power supply D1 FT OUTPUT E1 –IN INPUT POWER RETURN Negative input power terminal A’2, C’2 +OUT OUTPUT POWER Positive output power terminal B’2, D’2 –OUT OUTPUT POWER RETURN Negative output power terminal DCM™ DC-DC Converter Page 4 of 28 Positive input power terminal Fault monitoring Rev 1.7 03/2022 DCM3623x50M13C2yzz Part Ordering Information Part Number Temperature Grade DCM3623T50M13C2C00 C = –20 to ­125°C DCM3623T50M13C2T00 T = –40 to 125°C DCM3623T50M13C2M00 M = –55 to ­125°C Option Tray Size 00 = Analog Control Interface Version 24 parts per tray Previous Part Number MDCM28AP120M320A50, DCM28AP120T320A50 Storage and Handling Information Note: For compressive loading refer to Application Note AN:036, “Recommendations for Maximum Compressive Force of Heat Sinks.” For handling and assembly processing refer to Application Note AN:301, “Through-Hole ChiP™ Package Soldering Guidelines.” Parameter Comments Storage Temperature Range Operating Internal Temperature Range (TINT) Peak Temperature Top Case (Soldering) [a] Specification C-Grade –20 to 125°C T-Grade –40 to 125°C M-Grade –65 to 125°C C-Grade –20 to ­125°C T-Grade –40 to 125°C M-Grade –55 to 125°C For further information, please contact factory applications 135°C Nickel Lead Finish 0.51 – 2.03µm Palladium 0.02 – 0.15µm Gold 0.003 – 0.051µm Weight 24.0g [0.85oz] MSL Rating Not applicable to through-hole ChiP products Method per Human Body Model (HBM) Test ESDA / JEDEC JDS-001-2012 ESD Rating [a] N/A Class 1C Charged Device Model (CDM) JESD22-C101E Class 2 Product is not intended for reflow solder attach. Safety, Reliability and Agency Approvals Parameter Comments Min Typ Max Unit IN to OUT 2250 VDC IN to CASE 2250 VDC OUT to CASE 707 VDC Insulation Resistance IN to OUT, IN to CASE, OUT to CASE at 500VDC, 1 minute 10 MΩ MTBF MIL-HDBK-217 FN2 Parts Count  25°C Ground Benign, Stationary, Indoors / Computer 3.39 Telcordia Issue 2, Method I Case 3, 25°C, 100% D.C., GB, GC 5.68 Dielectric Withstand Test cURus, UL 60950-1 Agency Approvals/Standards cTÜVus, EN 62368-1 UKCA, electrical equipment (safety) regulations CE Marked for Low Voltage Directive and RoHS Recast Directive, as applicable DCM™ DC-DC Converter Page 5 of 28 Rev 1.7 03/2022 MHrs DCM3623x50M13C2yzz Absolute Maximum Ratings The absolute maximum ratings below are stress ratings only. Operation at or beyond these maximum ratings can cause permanent damage to the device. Electrical specifications do not apply when operating beyond rated operating conditions. Parameter Comments Min Max -0.5 65.0 V -1 1 V/µs TR to –IN -0.3 3.5 V EN to –IN -0.3 3.5 V -0.3 3.5 V 5 mA -0.5 16.0 V Input Voltage (+IN to –IN) Input Voltage Slew Rate FT to –IN Output Voltage (+OUT to –OUT) Dielectric Withstand (Input to Output) 2250 Basic insulation Average Output Current DCM™ DC-DC Converter Page 6 of 28 VDC 35.4 Rev 1.7 03/2022 Unit A DCM3623x50M13C2yzz Electrical Specifications Specifications apply over all line, trim and load conditions, internal temperature TINT = 25ºC, unless otherwise noted. Boldface specifications apply over the temperature range of –20°C < TINT < 125°C for C-Grade, –40°C < TINT < 125°C for T-Grade and –55°C < TINT < 125°C for M-Grade. Attribute Symbol Conditions / Notes Min Typ Max Unit 16 28 50 V 25.0 A Power Input Specifications Input Voltage Range VIN Continuous operation Inrush Current (Peak) IINRP With maximum COUT-EXT, full resistive load Input Capacitance (Internal) CIN-INT Effective value at nominal input voltage 29.7 Input Capacitance (Internal) ESR RCIN-INT At 1MHz 0.73 Input Inductance (External) LIN µF mΩ 1 Differential mode, with no further line bypassing µH No-Load Specifications Nominal line, see Figure 3; C-Grade Input Power – Disabled PQ 0.4 0.6 Worst case line, see Figure 3; C-Grade Nominal line, see Figure 3; T- and M-Grades 0.4 Input Power – Enabled with No Load PNL DCM™ DC-DC Converter Page 7 of 28 4.5 Nominal line, see Figure 4; T- and M-Grades Rev 1.7 03/2022 6.7 7.2 Worst case line, see Figure 4; C-Grade Worst case line, see Figure 4; T- and M-Grades 0.5 W 0.5 Worst case line, see Figure 3; T- and M-Grades Nominal line, see Figure 4; C-Grade 0.5 3.7 5.6 6.0 W W DCM3623x50M13C2yzz Electrical Specifications (Cont.) Specifications apply over all line, trim and load conditions, internal temperature TINT = 25ºC, unless otherwise noted. Boldface specifications apply over the temperature range of –20°C < TINT < 125°C for C-Grade, –40°C < TINT < 125°C for T-Grade and –55°C < TINT < 125°C for M-Grade. Attribute Symbol Conditions / Notes Min Typ Max Unit VOUT-NOM VIN = 28V, nominal trim, at 100% load, TINT = 25°C 11.94 12.0 12.06 V VOUT-TRIMMING Trim range over temp at full load. Specifies the low, nominal and high trim conditions. 7.2 12.0 13.2 V 0.5371 0.6316 0.7333 Power Output Specifications Output Voltage Set Point Rated Output Voltage Trim Range Output Voltage Load Regulation Output Voltage Light Load Regulation Output Voltage Temperature Coefficient Output Voltage Accuracy ΔVOUT-LOAD ΔVOUT-LL ΔVOUT-TEMP %VOUT-ACCURACY Linear load line. Output voltage increase from full rated load current to no load (does not include light-load regulation). See Figure 6 and Design Guidelines section; C-Grade Linear load line. Output voltage increase from full rated load current to no load (does not include light-load regulation). See Figure 6 and Design Guidelines section; T- and M-Grades 0 – 10% load, additional VOUT relative to calculated load-line point. See Figure 6 and Design Guidelines section. Nominal, linear temperature coefficient, relative to TINT = 25ºC. See Figure 5 and Design Guidelines Section. The total output voltage set-point accuracy from the calculated ideal VOUT based on load, temp and trim. Excludes ΔVOUT-LL; C-Grade The total output voltage set-point accuracy from the calculated ideal VOUT based on load, temp and trim. Excludes ΔVOUT-LL; T- and M-Grades V 0.5654 0.6316 0.00 0.6984 3.28 -1.60 -3.4 V mV / ºC 2.3 % -3.0 2.0 Rated Output Power POUT Continuous, VOUT ≥ 12.0V 320 W Rated Output Current IOUT Continuous, VOUT ≤ 12.0V 26.67 A Output Current Limit IOUT-LIM Of rated IOUT max. Fully operational current limit, for nominal trim and below. Current Limit Delay tIOUT-LIM The module will power limit in a fast transient event. Full load, nominal line, nominal trim Efficiency Output Voltage Ripple DCM™ DC-DC Converter Page 8 of 28 η VOUT-PP Full load, over line and temperature, nominal trim; C-Grade 50% load, over rated line, temperature and trim; C-Grade Full load, over line and temperature, nominal trim; T- and M-Grades 50% load, over rated line, temperature and trim; T- and M-Grades 20MHz bandwidth. At nominal trim, minimum COUT-EXT and at least 10% rated load Rev 1.7 03/2022 100 115 1 91.8 132 % ms 92.9 88.3 86.0 % 90.1 87.8 636 mV Electrical Specifications (Cont.) Specifications apply over all line, trim and load conditions, internal temperature TINT = 25ºC, unless otherwise noted. Boldface specifications apply over the temperature range of –20°C < TINT < 125°C for C-Grade, –40°C < TINT < 125°C for T-Grade and –55°C < TINT < 125°C for M-Grade. Attribute Symbol Conditions / Notes Min Typ Max Unit Power Output Specifications (Cont.) Output Capacitance (Internal) COUT-INT Effective value at nominal output voltage Output Capacitance ESR (Internal) RCOUT-INT At 1MHz COUT-EXT For load transients that remain >10% rated load; excludes component temperature coefficient 1000 10000 µF For load transients down to 0% rated load, with static trim; excludes component temperature coefficient 4000 10000 µF 10000 10000 µF Output Capacitance (External) COUT-EXT-TRANS For load transients down to 0% rated load, COUT-EXT-TRANS-TRIM with dynamic trimming; excludes component temperature coefficient Output Capacitance ESR (External) RCOUT-EXT At 10kHz, excludes component tolerances 135 µF 0.080 mΩ 10 mΩ tINIT See state diagram 25 Output Turn-On Delay tON From rising edge EN, with VIN pre-applied; see timing diagram 200 Output Turn-Off Delay tOFF From falling edge EN; see timing diagram Soft-Start Ramp Time tSS At full rated resistive load. Typical spec is 1-up with minimum COUT-EXT. Max spec is for arrays with max COUT-EXT Initialization Delay Output Voltage Threshold for Max Rated Load Current VOUT-FL-THRESH During start up, VOUT must achieve this threshold before output can support full rated current Output Current at Start Up IOUT-START Max load current at start up while VOUT is below VOUT-FL_THRESH Monotonic Soft-Start Threshold Voltage Minimum Required Disabled Duration Minimum Required Disabled Duration for Predictable Restart Voltage Deviation (Transient) Settling Time DCM™ DC-DC Converter Page 9 of 28 45 40 ms µs 600 µs 120 ms 6.0 V 2.66 A VOUT-MONOTONIC Output voltage rise becomes monotonic with 10% of preload once it crosses VOUT-MONOTONIC 6.0 V tOFF-MIN This refers to the minimum time a module needs to be in the disabled state before it will attempt to start via EN 2 ms tOFF-MONOTONIC This refers to the minimum time a module needs to be in the disabled state before it is guaranteed to exhibit monotonic soft-start and have predictable start‑up timing 100 ms %VOUT-TRANS tSETTLE Minimum COUT_EXT (10 ↔ 90% load step), excluding load line Rev 1.7 03/2022 VIN-INIT INITIALIZATION SEQUENCE EN = False tOFF-MIN delay NON LATCHED FAULT tOFF ult Fa oved m Re Powertrain: Stopped FT = True tINIT delay Powertrain: Stopped FT = True Powertrain: Stopped FT = True EN = True and No Faults tON delay EN = False tOFF delay In p In ut O pu V tU L VL O o O r VIN > VIN-UVLO+ and not Over-temp TR mode latched STANDBY or O VL LO t O UV u t p In npu I EN = False tOFF-MIN delay SOFT START VOUT Ramp Up tss delay Powertrain: Active FT = Unknown RUNNING tSS Expiry Ou tpu Regulates VOUT Powertrain: Active FT = False tO or mp r-te P Ove put UV Out REINITIALIZATION SEQUENCE tINIT delay Powertrain: Stopped FT = True Fault Removed Ov e Ou r-tem tpu p t U or VP VP tO pu ut O VP NON LATCHED FAULT tFAULT Powertrain: Stopped FT = True LATCHED FAULT EN = False DCM™ DC-DC Converter Rev 1.7 Page 12 of 28 03/2022 Powertrain: Stopped FT = True DCM™ DC-DC Converter Rev 1.7 Page 13 of 28 03/2022 Output Input FT ILOAD FULL LOAD IOUT VOUT VOUT-UVP FULL LOAD VOUT-NOM TR VTRIM-DIS-TH EN VIN VIN-UVLO+/VIN-INIT VIN-OVLO+/- tINIT tON 1 Input Power On - Trim Inactive tSS 2 3 Ramp to TR Full Load Ignored tOFF tOFF-MIN 4 EN Low tSS tON 5 EN High tOVLO 6 Input OVLO tSS tUVLO 7 Input UVLO tSS tUVLO 8 Input returned to zero DCM3623x50M13C2yzz Timing Diagrams Module inputs are shown in blue; module outputs are shown in brown. DCM™ DC-DC Converter Rev 1.7 Page 14 of 28 03/2022 Output Input FT ILOAD IOUT FULL LOAD VOUT VOUT-UVP VOUT-NOM FULL LOAD TR VTR = nom VTRIM-EN-TH EN VIN VIN-UVLO+/VIN-INIT VIN-OVLO+/- tINIT tON 9 Input Power On - Trim Active tSS VOUT-OVP 10 Vout based on VTR tOFF 11 Load dump and reverse current tINIT tON tSS 12 Vout OVP (primary sensed) 13 Latched fault cleared RLOAD tIOUT-LIM 14 Current Limit with Resistive Load tFAULT 15 Resistive Load with decresing R tINIT 16 Overload induced Output UVP tON tSS DCM3623x50M13C2yzz Timing Diagrams (Cont.) Module inputs are shown in blue; module outputs are shown in brown. DCM3623x50M13C2yzz Typical Performance Characteristics The following figures present typical performance at TC = 25ºC, unless otherwise noted. See associated figures for general trend data. 0.45 Power Dissipation (W) Power Dissipation (W) 0.50 0.40 0.35 0.30 0.25 0.20 10 20 30 40 50 Input Voltage (V) -40°C 25°C 60 14 Output Voltage (V) 14 12 10 8 6 40 20 0 20 40 60 Case Temperature (°C) Min Trim Low Trim Nom Trim High Trim 30 40 Input Voltage (V) 25°C 50 60 90°C Figure 4 — No-load power dissipation vs. VIN, at nominal trim 16 60 20 -40°C 16 4 10 90°C Figure 3 — Disabled power dissipation vs. VIN Output Voltage (V) 4.5 4.0 3.5 3.0 2.5 2.0 1.5 1.0 0.5 80 12 10 8 6 4 100 Max Trim 0 5 Min Trim Low Trim 10 15 20 Output Current (A) Nom Trim High Trim 25 Max Trim Figure 5 — Ideal VOUT vs. case temperature, at full load Figure 6 — Ideal VOUT vs. load current, at 25°C case Figure 7 — 100 – 10% load transient response, VIN = 28V, nominal trim, COUT_EXT = 1000µF Figure 8 — 10 – 100% load transient response, VIN = 28V, nominal trim, COUT_EXT = 1000µF DCM™ DC-DC Converter Rev 1.7 Page 15 of 28 03/2022 30 DCM3623x50M13C2yzz Typical Performance Characteristics (Cont.) The following figures present typical performance at TC = 25ºC, unless otherwise noted. See associated figures for general trend data. 92.5 Efficiency (%) Efficiency (%) 92.0 91.5 91.0 90.5 90.0 10 20 30 40 Input Voltage (V) -40°C 25°C 50 60 90°C 10 20 30 40 Input Voltage (V) Efficiency (%) -40°C 25°C 10 20 30 40 Input Voltage (V) -40°C Figure 9 — Full-load efficiency vs. VIN, at low trim 93.00 92.75 92.50 92.25 92.00 91.75 91.50 91.25 91.00 93.00 92.75 92.50 92.25 92.00 91.75 91.50 91.25 91.00 25°C 50 90°C Figure 10 — Full-load efficiency vs. VIN, at nominal trim 50 60 90°C Figure 11 — Full-load efficiency vs. VIN, at high trim DCM™ DC-DC Converter Rev 1.7 Page 16 of 28 03/2022 60 DCM3623x50M13C2yzz Typical Performance Characteristics (Cont.) The following figures present typical performance at TC = 25ºC, unless otherwise noted. See associated figures for general trend data. 94 35 Power Dissipation (W) Efficiency (%) 92 90 88 86 84 82 80 78 5 10 15 20 Load Current (A) 16V Input 28V Input 25 20 15 10 30 0 50V Input 5 10 15 20 Load Current (A) 16V Input Figure 12 — Efficiency vs. load at TCASE = -40°C, nominal trim 28V Input 25 30 50V Input Figure 13 — Power dissipation vs. load at TCASE = -40ºC, nominal trim 30 Power Dissipation (W) 94 92 Efficiency (%) 25 5 0 90 88 86 84 82 80 25 20 15 10 5 0 5 10 15 20 Load Current (A) 16V Input 28V Input 25 30 0 50V Input 5 10 15 20 Load Current (A) 16V Input Figure 14 — Efficiency vs. load at TCASE = 25°C, nominal trim 28V Input 25 30 50V Input Figure 15 — Power dissipation vs. load at TCASE = 25ºC, nominal trim 30 Power Dissipation (W) 94 92 Efficiency (%) 30 90 88 86 84 82 80 25 20 15 10 5 0 5 16V Input 10 15 20 Load Current (A) 28V Input 25 30 0 50V Input Figure 16 — Efficiency vs. load at TCASE = 90°C, nominal trim 5 16V Input 10 15 20 Load Current (A) 28V Input 25 50V Input Figure 17 — Power dissipation vs. load at TCASE = 90ºC, nominal trim DCM™ DC-DC Converter Rev 1.7 Page 17 of 28 03/2022 30 DCM3623x50M13C2yzz Typical Performance Characteristics (Cont.) The following figures present typical performance at TC = 25ºC, unless otherwise noted. See associated figures for general trend data. Switching Frequency (kHz) Switching Frequency (kHz) 800 700 600 500 400 300 200 100 0 10 20 40 60 80 800 700 600 500 400 300 200 100 0 100 Load (%) 16V Input 28V Input 10 20 Low Trim 50V Input Figure 18 — Nominal powertrain switching frequency vs. load, at nominal trim 40 60 Load (%) Nom Trim 80 100 High Trim Figure 19 — Nominal powertrain switching frequency vs. load, at nominal VIN Input Capacitance (µF) 50 45 40 35 30 25 20 15 10 5 0 0 8 16 24 32 40 48 56 64 72 80 Input Voltage (V) Figure 20 — Start up from EN, VIN = 28V, COUT_EXT = 10000µF, RLOAD = 0.450Ω Figure 21 — Effective internal input capacitance vs. applied voltage Figure 22 — Output voltage ripple, VIN = 28V, VOUT = 12.0V, COUT_EXT = 1000µF, RLOAD = 0.450Ω DCM™ DC-DC Converter Rev 1.7 Page 18 of 28 03/2022 DCM3623x50M13C2yzz Pin Functions The DCM will latch trim behavior at application of VIN (once VIN exceeds VIN-UVLO+), and persist in that same behavior until loss of input voltage +IN, –IN n At application of VIN, if TR is sampled at above VTRIM-DIS-TH, the module will latch in a non-trim mode, and will ignore the TR input for as long as VIN is present. Input power pins. –IN is the reference for all control pins, and therefore a Kelvin connection for the control signals is recommended as close as possible to the pin on the package, to reduce effects of voltage drop due to –IN currents. n At application of VIN, if TR is sampled at below VTRIM-EN-TH, the TR will serve as an input to control the real‑time output voltage, relative to full load, 25°C. It will persist in this behavior until VIN is no longer present. +OUT, –OUT Output power pins. If trim is active when the DCM is operating, the TR pin provides dynamic trim control at a typical 30Hz of –3dB bandwidth over the output voltage. TR also decreases the current limit threshold when trimming above VOUT-NOM. EN (Enable) This pin enables and disables the DCM converter; when held low the unit will be disabled. It is referenced to the –IN pin of the converter. The EN pin has an internal pull-up to VCC through a 10kΩ resistor. FT (Fault) n Output enable: When EN is allowed to pull up above the enable threshold, VENABLE-EN-TH, the module will be enabled. If leaving EN floating, it is pulled up to VCC and the module will be enabled. n Output disable: EN may be pulled down externally below VENABLE‑DIS‑TH in order to disable the module. n EN is an input only, it does not pull low in the event of a fault. n The EN pins of multiple units should be driven high concurrently to permit the array to start in to maximum rated load. However, the direct interconnection of multiple EN pins requires additional considerations, as discussed in the section on Array Operation. TR (Trim) The TR pin is used to select the trim mode and to trim the output voltage of the DCM converter. The TR pin has an internal pull-up to VCC through a 10.0kΩ resistor. The FT pin provides a Fault signal. Any time the module is enabled and has not recognized a fault, the FT pin is inactive. FT has an internal 499kΩ pull-up to VCC, therefore a shunt resistor, RSHUNT, of approximately 50kΩ can be used to ensure the LED is completely off when there is no fault, per the diagram below. Whenever the powertrain stops (due to a fault protection or disabling the module by pulling EN low), the FT pin becomes active and provides current to drive an external circuit. When active, FT pin drives to VCC, with up to 4mA of external loading. Module may be damaged from an overcurrent FT drive, thus a resistor in series for current limiting is recommended. The FT pin becomes active momentarily when the module starts up. During the output voltage soft-start ramp, the FT pin output toggles. Typical External Circuits for Signal Pins (TR, EN, FT) DCM VCC 10kΩ 10kΩ Output Voltage Reference, Current Limit Reference and Soft Start control TR Soft Start and Fault Monitoring EN RTRIM 499kΩ Fault Monitoring FT RSERIES SW RSHUNT Kelvin –IN connection DCM™ DC-DC Converter Rev 1.7 Page 19 of 28 03/2022 D DCM3623x50M13C2yzz Design Guidelines Building Blocks and System Design The DCM converter input accepts the full 16 – 50V range, and it generates an isolated trimmable 12.0VDC output. Multiple DCMs may be paralleled for higher power capacity via wireless load sharing, even when they are operating off of different input voltage supplies. The DCM converter provides a regulated output voltage around defined nominal load line and temperature coefficients. The load line and temperature coefficients enable configuration of an array of DCM converters which manage the output load with no share bus among modules. Downstream regulators may be used to provide tighter voltage regulation, if required. The DCM3623x50M13C2yzz may be used in standalone applications where the output power requirements are up to 320W. However, it is easily deployed as arrays of modules to increase power handling capacity. Arrays of up to eight units have been qualified for 2560W capacity. Application of DCM converters in an array requires no de‑rating of the maximum available power versus what is specified for a single module. Note: For more information on operation of single DCM, refer to “Single DCM as an Isolated, Regulated DC-DC Converter” application note AN:029. For more information on designing a power system using the DCMs, refer to the DCM Design Guide. Soft Start When the DCM starts, it will go through a soft start. The soft-start routine ramps the output voltage by modulating the internal error amplifier reference. This causes the output voltage to approximate a piecewise linear ramp. The output ramp finishes when the voltage reaches either the nominal output voltage, or the trimmed output voltage in cases where trim mode is active. During soft start, the maximum load current capability is reduced. Until VOUT achieves at least VOUT-FL-THRESH, the output current must be less than IOUT-START in order to guarantee start up. Note that this is current available to the load, above that which is required to charge the output capacitor. Nominal Output Voltage Load Line Throughout this document, the programmed output voltage, (either the specified nominal output voltage if trim is inactive or the trimmed output voltage if trim is active), is specified at full load and at room temperature. The actual output voltage of the DCM is given by the programmed trimmed output voltage, with modification based on load and temperature. The nominal output voltage is 12.0V, and the actual output voltage will match this at full load and room temperature with trim inactive. For a given programmed output voltage, the actual output voltage versus load current at nominal trim and room temperature is given by the following equation: VOUT at 25ºC = 12.0 + 0.6316 • (1 – IOUT / 26.67) (1) Nominal Output Voltage Temperature Coefficient A second additive term to the programmed output voltage is based on the temperature of the module. This term permits improved thermal balancing among modules in an array, especially when the factory nominal trim point is utilized (trim mode inactive). This term is much smaller than the load line described above, representing only a -1.60mV / °C change. Regulation coefficient is relative to 25°C. For nominal trim and full load, the output voltage relates to the temperature according to the following equation: VOUT-FL = 12.0 -1.600 • 0.001 • (TINT – 25) (2) Where TINT is in ºC The impact of temperature coefficient on the output voltage is absolute, and does not scale with trim or load. Trim Mode and Output Trim Control When the input voltage is initially applied to a DCM, and after tINIT elapses, the trim pin voltage V TR is sampled. The TR pin has an internal pull‑up resistor to VCC, so unless external circuitry pulls the pin voltage lower, it will pull up to VCC. If the initially sampled trim pin voltage is higher than V TRIM-DIS-TH, then the DCM will disable trimming as long as the VIN remains applied. In this case, for all subsequent operation the output voltage will be programmed to the nominal. This minimizes the support components required for applications that only require the nominal rated VOUT, and also provides the best output setpoint accuracy, as there are no additional errors from external trim components. If at initial application of VIN, the TR pin voltage is prevented from exceeding V TRIM-EN-TH, then the DCM will activate trim mode, and it will remain active for as long as VIN is applied. VOUT set point under full load and room temperature can be calculated using the equation below: VOUT-FL @ 25ºC = 4.99 + (9.390 • VTR / VCC) (3) Note that the trim mode is not changed when a DCM recovers from any fault condition or being disabled. Module performance is guaranteed through output voltage trim range VOUT-TRIMMING. If VOUT is trimmed above this range, then certain combinations of line and load transient conditions may trigger the output OVP. The largest modification to the actual output voltage compared to the programmed output is due to the 5.263% VOUT-NOM load line, which for this model corresponds to ΔVOUT-LOAD of 0.6316V. As the load is reduced, the internal error amplifier reference, and by extension the output voltage, rises in response. This load line is the primary enabler of the wireless current sharing among an array of DCMs. The load line impact on the output voltage is absolute, and does not scale with programmed trim voltage. DCM™ DC-DC Converter Rev 1.7 Page 20 of 28 03/2022 DCM3623x50M13C2yzz Overall Output Voltage Transfer Function Taking load line (Equation 1), temperature coefficient (Equation 2) and trim (Equation 3) into account, the general equation relating the DC VOUT to programmed trim (when active), load and temperature is given by: VOUT = 4.99 + (9.390 • VTR / VCC) + 0.6316 • (1 – IOUT / 26.67) -1.600 • 0.001 • (TINT – 25) + ΔVOUT-LL (4) Finally, note that when the load current is below 10% of the rated capacity, there is an additional ΔV which may add to the output voltage, depending on the line voltage which is related to light-load boosting. Please see the section on light-load boosting below for details. Use 0V for ΔVOUT-LL when load is above 10% of rated load. See section on light-load boosting operation for light-load effects on output voltage. Output Current Limit The DCM features a fully operational current limit which effectively keeps the module operating inside the Safe Operating Area (SOA) for all valid trim and load profiles. The current limit approximates a “brick wall” limit, where the output current is prevented from exceeding the current limit threshold by reducing the output voltage via the internal error amplifier reference. The current limit threshold at nominal trim and below is typically 115% of rated output current, but it can vary between 100% to 132%. In order to preserve the SOA, when the converter is trimmed above the nominal output voltage, the current limit threshold is automatically reduced to limit the available output power. When the output current exceeds the current limit threshold, current limit action is held off by 1ms, which permits the DCM to momentarily deliver higher peak output currents to the load. Peak output power during this time is still constrained by the internal Power Limit of the module. The fast Power Limit and relatively slow Current Limit work together to keep the module inside the SOA. Delaying entry into current limit also permits the DCM to minimize droop voltage for load steps. Sustained operation in current limit is permitted, and no de‑rating of output power is required, even in an array configuration. Line Impedance, Input Slew Rate and Input Stability Requirements Connect a high-quality, low-noise power supply to the +IN and –IN terminals. Additional capacitance may have to be added between +IN and –IN to make up for impedances in the interconnect cables as well as deficiencies in the source. Excessive source impedance can bring about system stability issues for a regulated DC-DC converter, and must either be avoided or compensated by filtering components. A 1000µF input capacitor is the minimum recommended in case the source impedance is insufficient to satisfy stability requirements. For selecting optimum value of decoupling capacitor, refer to section 2 of the DCM Design Guide. Additional information can be found in the filter design application note AN:023. Please refer to this input filter design tool to ensure input stability. Ensure that the input voltage slew rate is less than 1V/µs, otherwise a pre-charge circuit is required for the DCM input to control the input voltage slew rate and prevent overstress to input stage components. Input Fuse Selection The DCM is not internally fused in order to provide flexibility in configuring power systems. Input line fusing is recommended at the system level, in order to provide thermal protection in case of catastrophic failure. The fuse shall be selected by closely matching system requirements with the following characteristics: n Current rating (usually greater than the DCM converter’s maximum current) n Maximum voltage rating (usually greater than the maximum possible input voltage) n Ambient temperature n Breaking capacity per application requirements n Nominal melting I2t n Recommended fuse: See Safety Approvals for recommended fuse Some applications may benefit from well matched current distribution, in which case fine tuning sharing via the trim pins permits control over sharing. The DCM does not require this for proper operation, due to the power limit and current limit behaviors described here. Current limit can reduce the output voltage to as little as the UVP threshold (VOUT-UVP). Below this minimum output voltage compliance level, further loading will cause the module to shut down due to the output undervoltage fault protection. DCM™ DC-DC Converter Rev 1.7 Page 21 of 28 03/2022 DCM3623x50M13C2yzz Fault Handling Output Overvoltage Fault Protection (OVP) Input Undervoltage Fault Protection (UVLO) The converter monitors the output voltage during each switching cycle by a corresponding voltage reflected to the primary side control circuitry. If the primary sensed output voltage exceeds VOUT‑OVP, the OVP fault protection is triggered. The control logic disables the powertrain, and the output voltage of the converter falls. The converter’s input voltage is monitored to detect an input undervoltage condition. If the converter is not already running, then it will ignore enable commands until the input voltage is greater than VIN‑UVLO+. If the converter is running and the input voltage falls below VIN‑UVLO–, the converter recognizes a fault condition, the powertrain stops switching, and the output voltage of the unit falls. Input voltage transients which fall below UVLO for less than tUVLO may not be detected by the fault protection logic, in which case the converter will continue regular operation. No protection is required in this case. Once the UVLO fault is detected by the fault protection logic, the converter shuts down and waits for the input voltage to rise above VIN-UVLO+. Provided the converter is still enabled, it will then restart. Input Overvoltage Fault Protection (OVLO) The converter’s input voltage is monitored to detect an input overvoltage condition. When the input voltage is more than the VIN‑OVLO+, a fault is detected, the powertrain stops switching, and the output voltage of the converter falls. After an OVLO fault occurs, the converter will wait for the input voltage to fall below VIN‑OVLO–. Provided the converter is still enabled, the powertrain will restart. The powertrain controller itself also monitors the input voltage. Transient OVLO events which have not yet been detected by the fault sequence logic may first be detected by the controller if the input slew rate is sufficiently large. In this case, powertrain switching will immediately stop. If the input voltage falls back in range before the fault sequence logic detects the out of range condition, the powertrain will resume switching and the fault logic will not interrupt operation. Regardless of whether the powertrain is running at the time or not, if the input voltage does not recover from OVLO before tOVLO, the converter fault logic will detect the fault. Output Undervoltage Fault Protection (UVP) The converter determines that an output overload or short circuit condition exists by measuring its primary sensed output voltage and the output of the internal error amplifier. In general, whenever the powertrain is switching and the primary-sensed output voltage falls below VOUT‑UVP threshold, a short circuit fault will be registered. Once an output undervoltage condition is detected, the powertrain immediately stops switching, and the output voltage of the converter falls. The converter remains disabled for a time tFAULT. Once recovered and provided the converter is still enabled, the powertrain will again enter the soft‑start sequence after tINIT and tON. This type of fault is latched, and the converter will not start again until the latch is cleared. Clearing the fault latch is achieved by either disabling the converter via the EN pin, or else by removing the input power such that the input voltage falls below VIN‑INIT. External Output Capacitance The DCM converter internal compensation requires a minimum external output capacitor. An external capacitor in the range of 1000 – 10000µF with ESR of 10mΩ is required, per DCM for control loop compensation purposes. However some DCM models require an increase in the minimum external output capacitor value in certain loading and trim conditions. In applications where the load can go below 10% of rated load but the output trim is held constant, the range of output capacitor required is given by COUT‑EXT‑TRANS in the Electrical Specifications table. If the load can go below 10% of rated load and the DCM output trim is also dynamically varied, the range of output capacitor required is given by COUT‑EXT‑TRANS‑TRIM in the Electrical Specifications table.­ Light-Load Boosting Under light-load conditions, the DCM converter may operate in light‑load boosting depending on the line voltage. Light‑load boosting occurs whenever the internal power consumption of the converter combined with the external output load is less than the minimum power transfer per switching cycle. In order to maintain regulation, the error amplifier will switch the powertrain off and on repeatedly, to effectively lower the average switching frequency, and permit operation with no external load. During the time when the powertrain is off, the module internal consumption is significantly reduced, and so there is a notable reduction in no-load input power in light‑load boosting. When the load is less than 10% of rated IOUT, the output voltage may rise by a maximum of 3.28V, above the output voltage calculated from trim, temperature and load line conditions. Temperature Fault Protections (OTP) The fault logic monitors the internal temperature of the converter. If the measured temperature exceeds TINT‑OTP, a temperature fault is registered. As with the undervoltage fault protection, once a temperature fault is registered, the powertrain immediately stops switching, the output voltage of the converter falls, and the converter remains disabled for at least time tFAULT. Then, the converter waits for the internal temperature to return to below TINT‑OTP before recovering. Provided the converter is still enabled, the DCM will restart after tINIT and tON. DCM™ DC-DC Converter Rev 1.7 Page 22 of 28 03/2022 DCM3623x50M13C2yzz Thermal Considerations Based on the safe thermal operating area shown on Page 5, the full rated power of the DCM3623x50M13C2yzz can be processed provided that the top, bottom and leads are all held below 95ºC. These curves highlight the benefits of dual‑sided thermal management, but also demonstrate the flexibility of the Vicor ChiP™ platform for customers who are limited to cooling only the top or the bottom surface. The OTP sensor is located on the top side of the internal PCB structure. Therefore in order to ensure effective overtemperature fault protection, the case bottom temperature must be constrained by the thermal solution such that it does not exceed the temperature of the case top. The ChiP package provides a high degree of flexibility in that it presents three pathways to remove heat from internal power dissipating components. Heat may be removed from the top surface, the bottom surface and the leads. The extent to which these three surfaces are cooled is a key component for determining the maximum power that is available from a ChiP, as can be seen from Figure 23. Since the ChiP has a maximum internal temperature rating, it is necessary to estimate this internal temperature based on a real thermal solution. Given that there are three pathways to remove heat from the ChiP, it is helpful to simplify the thermal solution into a roughly equivalent circuit where power dissipation is modeled as a current source, isothermal surface temperatures are represented as voltage sources and the thermal resistances are represented as resistors. Figure 23 shows the “thermal circuit” for a 3623 ChiP DCM, in an application where both case top and case bottom and leads are cooled. In this case, the DCM power dissipation is PDTOTAL and the three surface temperatures are represented as TCASE_TOP, TCASE_BOTTOM and TLEADS. This thermal system can now be very easily analyzed with simple resistors, voltage sources, and a current source. This analysis provides an estimate of heat flow through the various pathways as well as internal temperature. Thermal Resistance Bottom θINT-BOTTOM ºC / W Power Dissipation (W) TCASE_BOTTOM(°C) Thermal Resistance Bottom θINT-BOTTOM ºC / W TLEADS(°C) + – TLEADS(°C) + – TCASE_TOP(°C) + – Figure 24 — One-side cooling and leads thermal model Figure 24 shows a scenario where there is no bottom‑side cooling. In this case, the heat flow path to the bottom is left open and the equations now simplify to: TINT – PD1 • θINT-TOP = TCASE_TOP TINT – PD3 • θINT-LEADS = TLEADS PDTOTAL = PD1+ PD3 Thermal Resistance Top θINT-TOP ºC / W Thermal Resistance Bottom θINT-BOTTOM ºC / W MAX INTERNAL TEMP Thermal Resistance Leads θINT-LEADS ºC / W TCASE_BOTTOM(°C) Power Dissipation (W) TLEADS(°C) TCASE_TOP(°C) + – Figure 25 — One-side cooling thermal model Figure 25 shows a scenario where there is no bottom‑side and leads cooling. In this case, the heat flow path to the bottom is left open and the equations now simplify to: TINT – PD1 • θINT-TOP = TCASE_TOP PDTOTAL = PD1 Thermal Resistance Leads θINT-LEADS ºC / W + – Thermal Resistance Leads θINT-LEADS ºC / W TCASE_BOTTOM(°C) Power Dissipation (W) MAX INTERNAL TEMP Thermal Resistance Top θINT-TOP ºC / W MAX INTERNAL TEMP Thermal Resistance Top θINT-TOP ºC / W TCASE_TOP(°C) + – Vicor provides a suite of online tools, including a simulator and thermal estimator which greatly simplify the task of determining whether or not a DCM thermal configuration is sufficient for a given condition. These tools can be found at: www.vicorpower.com/powerbench. Figure 23 — Double-side cooling and leads thermal model Symbol Thermal Impedance (°C/W) θINT-TOP 2.0 to maximum-temperature internal component from isothermal top θINT-LEADS 4.4 to maximum-temperature internal component from isothermal leads θINT-BOTTOM 2.4 to maximum-temperature internal component from isothermal bottom Alternatively, equations can be written around this circuit and analyzed algebraically: TINT – PD1 • θINT-TOP = TCASE_TOP TINT – PD2 • θINT-BOTTOM = TCASE_BOTTOM TINT – PD3 • θINT-LEADS = TLEADS PDTOTAL = PD1+ PD2+ PD3 Where TINT represents the internal temperature and PD1, PD2 and PD3 represent the heat flow through the top side, bottom side and leads respectively. Definition of Estimated Thermal Resistance Thermal Capacity 17.7Ws/°C Table 1 — Thermal data DCM™ DC-DC Converter Rev 1.7 Page 23 of 28 03/2022 DCM3623x50M13C2yzz Array Operation COUT-EXT-x: electrolytic or tantalum capacitor with at least 10mΩ ESR, 1000µF ≤ COUT-EXT ≤ 10000µF; additional ceramic /electrolytic capacitors, if needed C3, C 4: for output ripple filtering; In order to help sensitive signal circuits reject potential noise, additional components are recommended: A decoupling network is needed to facilitate paralleling: n An output inductor should be added to each DCM, before the outputs are bussed together to provide decoupling. n Each DCM needs a separate input filter, even if the multiple DCMs share the same input voltage source. These filters limit the ripple current reflected from each DCM, and also help suppress generation of beat frequency currents that can result when multiple powertrains input stages are permitted to directly interact. R2_x: FB1_x, C2_x: If signal pins (TR, EN, FT) are not used, they can be left floating, and DCM will work in the nominal output condition. 301Ω, facilitate noise attenuation for TR pin; FB1 is a ferrite bead with an impedance of at least 10Ω at 100MHz. C2_x can be a ceramic capacitor of 0.1µF. Facilitate noise attenuation for EN pin. Note: Use an RCR filter network as suggested in the application note AN:030 to reduce the noise on the signal pins. When common‑mode noise in the input side is not a concern, TR and EN can be driven and FT received using a single Kelvin connection to the shared –IN as a reference. Note: In case of the excessive line inductance, a properly sized decoupling capacitor CDECOUPLE is required as shown in Figure 26 and Figure 27. Note: For more information on parallel operation of DCMs, refer to “Parallel DCMs” application note AN:030. When common‑mode noise rejection in the input side is needed, common‑mode chokes can be added in the input side of each DCM. An example of DCM paralleling circuit is shown in Figure 27. An example of DCM paralleling circuit is shown in Figure 26. Notice that each group of control pins need to be individually driven and isolated from the other groups control pins. This is because –IN of each DCM can be at a different voltage due to the common mode chokes. Attempting to share control pin circuitry could lead to incorrect behavior of the DCMs. Filter components Input filter: The choice of the input filter components varies up on the low line and maximum output power of the DCM. Refer to the Filtering Guidelines Introduction section in the DCM Design Guide to design an input filter. Output filter: Reference Designator Value Mfg. Part Number & Count/DCM C2_1 80μF L2_1, L2_2 0.33μH 744309033, #1 Rd_1, Rd_2 0.05Ω RL2512FK-070R05L, #1 Lb_1, Lb_2 72nH IFLR2727EZER72NM01, #1 GRM32EC72A106KE05L, #8 VTR VEN EMI_GND F1_1 VIN CDECOUPLE C1_1 DCM1 TR EN FB1_1 Rdm_1 FT C5_1 CY L1_1 R2_1 CY Rd_1 Cd_1 +IN +OUT –IN –OUT CY DCM2 EN Rd_2 Cd_2 ≈≈ CY ≈≈ CY C1_8 Rd_8 –IN –OUT C5_8 Lb1_2 L2_2 ROUT-EXT_2 C2_2 COUT-EXT_2 ≈≈ CY DCM8 EN R3 R4 D1 Cd_8 +OUT CY TR FB1_8 L1_8 +IN ≈ R2_8 F1_8 Rdm_2 FT C5_2 CY C1_2 C2_1 COUT-EXT_1 TR FB1_2 L1_2 ROUT-EXT_1 CY R2_2 F1_2 Lb1_1 L2_1 Rdm_8 FT CY +IN +OUT –IN –OUT ROUT-EXT_8 COUT-EXT_8 Shared –IN Kelvin CY Figure 26 — DCM paralleling configuration circuit 1 DCM™ DC-DC Converter Rev 1.7 Page 24 of 28 03/2022 CY Lb1_8 L2_8 C2_8 C3 C4 Load DCM3623x50M13C2yzz R2_1 + EMI_GND F1_1 VIN VTR1 CY T1_1 CDECOUPLE C1_1 + FB1_1 C5_1 VEN1 _ Rd_1 _ DCM1 TR EN R3_1 FT CY +IN +OUT –IN –OUT CY R2_2 VTR2 CY T1_2 C1_2 + FB 1_2 C5_2 VEN2 _ Rd_2 _ R3_2 R4_2 D1_2 Cd_2 DCM2 EN FT CY +IN +OUT –IN –OUT CY R2_8 + VTR8 CY C1_8 _ Rd_8 FB1_8 VEN8 C5_8 _ R3_8 R4_8 Cd_8 D1_8 FT CY +IN +OUT –IN –OUT Maximum Power Dissipation (W) 50 40 30 20 10 Top only at temperature 40 60 Top and leads at temperature 80 ≈≈ 100 Top, leads and bottom at temperature Figure 28 — Thermal specified operating area: max power dissipation vs. case temp for arrays or current‑limited operation DCM™ DC-DC Converter Rev 1.7 Page 25 of 28 03/2022 Rdm_8 Lb_8 L1_8 RCOUT-EXT_8 COUT-EXT_8 CY DCMs in current limit will operate with higher output current or power than the rated levels. Therefore the following Thermal Safe Operating Area plot should be used for arrays or loads that drive the DCM in to current limit for sustained operation. Temperature (°C) C2_2 DCM8 An array of DCMs used at the full array rated power may generally have one or more DCMs operating at current limit, due to sharing errors. Load sharing is functionally managed by the load line. Thermal balancing is improved by the nominal effective temperature coefficient of the output voltage set point. 20 RCOUT-EXT_2 COUT-EXT_2 EN Figure 27 — DCM paralleling configuration circuit 2 0 Lb_2 L1_2 TR CY 0 Rdm_2 CY + T1_8 C3 C2_1 COUT-EXT_1 TR ≈≈ F1_8 RCOUT-EXT_1 CY + F1_2 Lb_1 L1_1 R4_1 D1_1 Cd_1 Rdm_1 C2_8 C4 Load DCM3623x50M13C2yzz DCM Module Product Outline Drawing Recommended PCB Footprint and Pinout 3623 THRU HOLE (Reference DWG # 40260 Rev 5) 38.72±.38 1.524±.015 11.43 .450 19.36 .762 0 1.52 .060 (2) PL. 11.40 .449 0 0 22.80±.13 .898±.005 1.02 .040 (3) PL. 0 1.52 .060 (4) PL. TOP VIEW (COMPONENT SIDE) .05 [.002] 7.21±.10 .284±.004 SEATING . PLANE 4.17 .164 (9) PL. 0 18.60 .732 18.60 .732 .41 .016 (9) PL. 8.25 .325 8.00 .315 2.75 .108 0 0 2.75 .108 1.38 .054 4.13 .162 1.38 .054 8.00 .315 0 8.25 .325 8.00±.08 .315±.003 4.13±.08 .162±.003 1.38±.08 .054±.003 +IN 0 2.03 .080 PLATED THRU .25 [.010] ANNULAR RING (2) PL. 2.75±.08 .108±.003 -OUT TR 0 EN FT 8.00±.08 .315±.003 8.25±.08 .325±.003 +OUT -IN +OUT 2.75±.08 .108±.003 -OUT 8.25±.08 .325±.003 0 1.38±.08 .054±.003 0 18.60±.08 .732±.003 1.52 .060 PLATED THRU .25 [.010] ANNULAR RING (3) PL. 18.60±.08 .732±.003 BOTTOM VIEW RECOMMENDED HOLE PATTERN (COMPONENT SIDE) NOTES: 1- UNLESS OTHERWISE SPECIFIED DIMENSIONS ARE MM [INCH] 2- TOLERANCES ARE: DECIMALS X.XX [X.XX] = ±0.25 [0.01] X.XXX [X.XXX] = ±0.127 [0.005] ANGLES = ±1° DCM™ DC-DC Converter Rev 1.7 Page 26 of 28 03/2022 2.03 .080 PLATED THRU .38 [.015] ANNULAR RING (4) PL. DCM3623x50M13C2yzz Revision History Revision Date Description Page Number(s) 1.0 09/19/16 Release of current data sheet with new part number 1.1 01/20/17 Updated powertrain protection specs 7 1.2 04/28/17 Added 2 decimal points to the UVLO and OVLO powertrain protection specifications 7 Updated typical applications Updated height and length specifications Updated mechanical drawing Updated typical applications Updated timing diagrams Updated figures 15&18 Updated rated output voltage trim range note Updated typical applications, added MIL-STD info Added insulation resistance specification Updated high level functional state diagram 1.3 09/15/17 1.4 01/30/18 1.5 06/29/20 1.6 10/27/20 Typo correction 03/01/22 Updated agency approvals Updated input undervoltage lockout threshold Revised array operation section Added C-grade part number and related specs Updated format, pages added 1.7 DCM™ DC-DC Converter Rev 1.7 Page 27 of 28 03/2022 n/a 1 15 23 1 10, 11 14 6 1 16 9 1 1, 5 10 23 5, 7, 8 ALL DCM3623x50M13C2yzz 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. 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The products described on this data sheet are protected by the following U.S. Patents Numbers: RE40,072; 7,561,446; 7,920,391; 7,782,639; 8,427,269; 6,421,262; 9,516,761 and other patents pending. 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.co Technical Support: apps@vicorpower.com ©2017 – 2022 Vicor Corporation. All rights reserved. The Vicor name is a registered trademark of Vicor Corporation. All other trademarks, product names, logos and brands are property of their respective owners. DCM™ DC-DC Converter Rev 1.7 Page 28 of 28 03/2022