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| PRELIMINARY VTM V*I Chip - VTM Voltage Transformation Module TM V048F040T050 * 48 V to 4 V V*I Chip Converter * 50 A (75 A for 1 ms) * High density - 182 A/in3 * Small footprint - 45 A/in2 * Low weight - 0.5 oz (14 g) * Pick & Place / SMD * 125C operation * 1 s transient response * 3.5 million hours MTBF * Typical efficiency 94% * No output filtering required Vf = 26 - 55 V VOUT = 2.17 - 4.58 V IOUT = 50 A K = 1/12 ROUT = 3.9 m max (c) Actual size Product Description The V048F040T050 V*I Chip Voltage Transformation Module (VTM) excels at speed, density and efficiency to meet the demands of advanced power applications while providing isolation from input to output. It achieves a response time of less than 1 s and delivers up to 50 A in a volume of less than 0.274 in3 with unprecedented efficiency. It may be paralleled to deliver higher power levels at an output voltage settable from 2.17 to 4.58 Vdc. The VTM V048F040T050's nominal output voltage is 4 Vdc from a 48 Vdc input Factorized Bus, Vf, and is controllable from 2.17 to 4.58 Vdc at no load, and from 1.98 to 4.40 Vdc at full load, over a Vf input range of 26 to 55 Vdc. It can be operated either open- or closed-loop depending on the output regulation needs of the application. Operating open-loop, the output voltage tracks its Vf input voltage with a transformation ratio, K = 1/12, for applications requiring an isolated output voltage with high efficiency. Closing the loop back to an input Pre-Regulation Module (PRM) or DC-DC converter enables tight load regulation. The 4 V VTM achieves a current density of 182 A/in3 in a V*I Chip package compatible with standard pick-andplace and surface mount assembly processes. The VTM's fast dynamic response and low noise eliminate the need for bulk capacitance at the load, substantially increasing system density while improving reliability and decreasing cost. Absolute Maximum Ratings Parameter +In to -In +In to -In PC to -In VC to -In +Out to -Out Isolation voltage Output current Peak output current Output power Peak output power Case temperature Operating junction temperature (1) Storage temperature Note: (1) The referenced junction is defined as the semiconductor having the highest temperature. This temperature is monitored by a shutdown comparator. Values -1.0 to 60 100 -0.3 to 7.0 -0.3 to 19.0 -0.5 to 12 2,250 50 75 220 330 208 -40 to 125 -55 to 125 -40 to 150 -65 to 150 Unit Vdc Vdc Vdc Vdc Vdc Vdc A A W W C C C C C Notes For 100 ms Input to Output Continuous For 1 ms Continuous For 1 ms During reflow T - Grade M - Grade T - Grade M - Grade Part Numbering V Voltage Transformation Module 048 Input Voltage Designator F 040 Output Voltage Designator (=VOUT x10) T 050 Output Current Designator (=IOUT) Configuration Options F = On-board (Figure 10) Product Grade Temperatures (C) Grade Storage Operating T -40 to150 -40 to125 M -65 to150 -55 to125 vicorpower.com 800-735-6200 V*I Chip Voltage Transformation Module V048F040T050 Rev. 1.1 Page 1 of 13 PRELIMINARY Electrical Specifications Input Specs (Conditions are at 48 Vin, full load, and 25C ambient unless otherwise specified) Parameter Input voltage range Input dV/dt Input overvoltage turn-on Input overvoltage turn-off Input current Input reflected ripple current No load power dissipation Internal input capacitance Internal input inductance 114 4.10 1.9 5 5.10 55.0 59.0 4.6 V*I Chip Voltage Transformation Module Min 26 Typ 48 Max 55 1 Unit Vdc V/s Vdc Vdc Adc mA p-p W F nH Note Operable down to zero V with VC voltage applied Using test circuit in Figure 14; See Figure 1 Output Specs (Conditions are at 48 Vin, full load, and 25C ambient unless otherwise specified) Parameter Output voltage Rated DC current Peak repetitive current Short circuit protection set point Current share accuracy Efficiency Half load Full load Internal output inductance Internal output capacitance Output overvoltage setpoint Output ripple voltage No external bypass 47 F bypass capacitor Effective switching frequency Line regulation K Load regulation ROUT Transient response Voltage overshoot Response time Recovery time 59.8 5 93.4 93.1 94.8 94.4 1.1 255 10 Min 2.17 1.98 0 Typ Max 4.58 4.40 50 75 Unit Vdc Vdc Adc A Adc % % % nH F Vdc Note No load Full load 26 - 55 VIN Max pulse width 1ms, max duty cycle 10%, baseline power 50% Module will shut down See Parallel Operation on Page 8 See Figure 3 See Figure 3 Effective value Module will shut down See Figures 2 and 5 See Figure 6 Fixed, 1.3 MHz per phase VOUT = K*VIN at no load 4.6 216 8 2.55 1/12 3.3 110 200 1 290 2.70 0.0842 3.9 2.40 0.0825 mV mV MHz m mV ns s See Figure 17 50 A load step with 100 F CIN; See Figures 7 and 8 See Figures 7 and 8 See Figures 7 and 8 vicorpower.com 800-735-6200 V*I Chip Voltage Transformation Module V048F040T050 Rev. 1.1 Page 2 of 13 PRELIMINARY Electrical Specifications (continued) Waveforms Ripple vs. Output Current 220 Output Ripple (mVpk-pk) 200 180 160 140 120 100 80 0 5 10 15 20 25 30 35 40 45 50 Output Current (A) Figure 1-- Input reflected ripple current at full load and 48 Vf. Figure 2-- Output voltage ripple vs. output current at 48 Vf with no POL bypass capacitance. Efficiency vs. Output Current 96 94 14 12 10 8 6 4 2 Power Dissipation Efficiency (%) 92 90 88 86 84 82 0 5 10 15 20 25 30 35 40 45 50 Power Dissipation (W) 0 5 10 15 20 25 30 35 40 45 50 Output Current (A) Figure 3-- Efficiency vs. output current. Output Current (A) Figure 4--Power dissipation vs. output current. Figure 5-- Output voltage ripple at full load and 48 Vf; with no POL bypass capacitance. Figure 6--Output voltage ripple at full load and 48 Vf with 47 F ceramic POL bypass capacitance and 20 nH distribution inductance. vicorpower.com 800-735-6200 V*I Chip Voltage Transformation Module V048F040T050 Rev. 1.1 Page 3 of 13 PRELIMINARY Electrical Specifications (continued) V*I Chip Voltage Transformation Module Figure 7-- 0-50 A load step with 100 F input capacitance and no output capacitance. Figure 8-- 50-0 A load step with 100 F input capacitance and no output capacitance. General Parameter MTBF MIL-HDBK-217F Isolation specifications Voltage Capacitance Resistance Agency approvals (pending) Mechanical parameters Weight Dimensions Length Width Height Min Typ 3.5 Max Unit Mhrs Vdc pF M Note 25C, GB Input to Output Input to Output Input to Output UL/CSA 60950, EN 60950 Low voltage directive See Mechanical Drawing, Figures 12 2,250 3,000 10 cTUVus CE Mark 0.5 / 14.0 1.26 / 32 0.87 / 22 0.25 / 6,2 oz / g in / mm in / mm in / mm Auxiliary Pins (Conditions are at 48 Vin, full load, and 25C ambient unless otherwise specified) Parameter Primary Control (PC) DC voltage Module disable voltage Module enable voltage Current limit Disable delay time VTM Control (VC) External boost voltage External boost duration Min 4.8 2.4 2.4 Typ 5.0 2.5 2.5 2.5 30 14 10 Max 5.2 2.6 2.9 Unit Vdc Vdc Vdc mA s Vdc ms Note VC voltage must be applied when module is enabled using PC Source only PC low to Vout low Required for VTM start up without PRM Vin > 26 Vdc. VC must be applied continuously if Vin < 26 Vdc. 12 19 vicorpower.com 800-735-6200 V*I Chip Voltage Transformation Module V048F040T050 Rev. 1.1 Page 4 of 13 PRELIMINARY Pin/Control Functions +IN/-IN DC Voltage Ports The VTM input should not exceed the maximum specified. Be aware of this limit in applications where the VTM is being driven above its nominal output voltage. If less than 26 Vdc is present at the +In and -In ports, a continuous VC voltage must be applied for the VTM to process power. Otherwise VC voltage need only be applied for 10 ms after the voltage at the +In and -In ports has reached or exceeded 26 Vdc. If the input voltage exceeds the overvoltage turn-off, the VTM will shutdown. The VTM does not have internal input reverse polarity protection. Adding a properly sized diode in series with the positive input or a fused reverse-shunt diode will provide reverse polarity protection. TM - For Factory Use Only -Out 4 A 3 2 1 A B C D E +Out B C D E +In -Out F G H H J J K K TM VC PC +Out L M N P R T L M N P R T -In VC - VTM Control The VC port is multiplexed. It receives the initial VCC voltage from an upstream PRM, synchronizing the output rise of the VTM with the output rise of the PRM. Additionally, the VC port provides feedback to the PRM to compensate for the VTM output resistance. In typical applications using VTMs powered from PRMs, the PRM's VC port should be connected to the VTM VC port. In applications where a VTM is being used without a PRM, 14 V must be supplied to the VC port for as long as the input voltage is below 26 V and for 10 ms after the input voltage has reached or exceeded 26 V. The VTM is not designed for extended operation below 26 V. The VC port should only be used to provide VCC voltage to the VTM during startup. PC - Primary Control Figure 9--VTM pin configuration Bottom View Signal Name +In -In TM VC PC +Out -Out Pin Designation A1-E1, A2-E2 L1-T1, L2-T2 H1, H2 J1, J2 K1, K2 A3-D3, A4-D4, J3-M3, J4-M4 E3-H3, E4-H4, N3-T3, N4-T4 The Primary Control (PC) port is a multifunction port for controlling the VTM as follows: Disable - If PC is left floating, the VTM output is enabled. To disable the output, the PC port must be pulled lower than 2.4 V, referenced to -In. Optocouplers, open collector transistors or relays can be used to control the PC port. Once disabled, 14 V must be re-applied to the VC port to restart the VTM. Primary Auxiliary Supply - The PC port can source up to 2.4 mA at 5 Vdc. +OUT/-OUT DC Voltage Output Ports The output and output return are through two sets of contact locations. The respective +Out and -Out groups must be connected in parallel with as low an interconnect resistance as possible. Within the specified input voltage range, the Level 1 DC behavioral model shown in Figure 17 defines the output voltage of the VTM. The current source capability of the VTM is shown in the specification table. To take full advantage of the VTM, the user should note the low output impedance of the device. The low output impedance provides fast transient response without the need for bulk POL capacitance. Limitedlife electrolytic capacitors required with conventional converters can be reduced or even eliminated, saving cost and valuable board real estate. vicorpower.com 800-735-6200 V*I Chip Voltage Transformation Module V048F040T050 Rev. 1.1 Page 5 of 13 PRELIMINARY Configuration Options Standard(1) (Figure 15) 2.4 C/W 1.1 C/W 6.8 C/W V*I Chip Voltage Transformation Module CONFIGURATION Junction-Board Thermal Resistance Junction-Case Thermal Resistance Junction-Ambient Thermal Resistance 300LFM Notes: (1) Surface mounted to a 2" x 2" FR4 board, 4 layers 2 oz Cu Standard with 0.25" heatsink 2.4 C/W N/A 5.0 C/W 22.0 0.87 32.0 1.26 6.3 0.25 STANDARD MOUNT Figure 10--Onboard mounting - package F Figure 11--Hole location for push pin heatsink relative to VIC Thermal Symbol Parameter Over temperature shutdown Thermal capacity Junction-to-case thermal impedance Junction-to-board thermal impedance Junction-to-ambient (1) Junction-to-ambient (2) Min 125 Typ 130 0.61 1.1 2.1 6.5 5.0 Max 135 Unit C Ws/C C/W C/W C/W C/W Note Junction temperature RJC RJB RJA RJA Notes: (1) V048F040T050 surface mounted to a 2" x 2" FR4 board, 4 layers 2 oz Cu, 300 LFM. (2) V048F040T050 with a 0.25"H heatsink mounted on FR4 board, 300 LFM. vicorpower.com 800-735-6200 V*I Chip Voltage Transformation Module V048F040T050 Rev. 1.1 Page 6 of 13 PRELIMINARY Mechanical Drawings (continued) 22,0 0.87 6,2 0.25 3,01 0.118 15,99 0.630 3,01 0.118 (4) PL. 7,10 0.280 (3) X 1.22 0.48 8,56 0.337 OUTPUT OUTPUT INPUT 32,0 1.26 INPUT 24,00 0.945 16,00 0.630 15,35 0.604 C L 8,00 0.315 C L 12,94 0.509 14,94 0.588 16,94 0.667 22,54 0.887 TOP VIEW (COMPONENT SIDE) BOTTOM VIEW NOTES: 1- DIMENSIONS ARE mm/[INCH]. 2- UNLESS OTHERWISE SPECIFIED, TOLERANCES ARE: .X/[.XX] = +/-0.25/[.01]; .XX/[.XXX] = +/-0.13/[.005] 3- PRODUCT MARKING ON TOP SURFACE. Figure 12-- V T M J-Lead mechanical outline; Onboard mounting 3,26 0.128 1,38 0.054 TYP 15,74 0.620 3,26 0.128 0,51 TYP 0.020 (2) X 8,94 0.352 (6) X 1,60 0.063 +OUT +IN -OUT1 7,48 (8) X 0.295 22,54 (2) X 0.887 (2) X16,94 0.667 (2) X14,94 0.588 12,94 (2) X 0.509 11,48 (2) X 0.452 TM VC PC +OUT2 (2) X 16,00 0.630 -OUT2 8,00 (2) X 0.315 (2) X 24,00 0.945 -IN RECOMMENDED LAND PATTERN (COMPONENT SIDE SHOWN) NOTES: 1- DIMENSIONS ARE mm/[INCH]. 2- UNLESS OTHERWISE SPECIFIED, TOLERANCES ARE: .X/[.XX] = +/-0.25/[.01]; .XX/[.XXX] = +/-0.13/[.005] Figure 13-- VTM J-Lead PCB land layout information; Onboard mounting vicorpower.com 800-735-6200 V*I Chip Voltage Transformation Module V048F040T050 Rev. 1.1 Page 7 of 13 PRELIMINARY CONFIGURATION OPTIONS (continued) V*I Chip Voltage Transformation Module Input reflected ripple measurement point F1 6A Fuse +In +Out + R3 10 m Load C3 47 F - Notes: C3 should be placed close to the load R3 may be ESR of C3 or a separate damping resistor. -Out C1 47 F Al electrolytic C2 0.47 F ceramic TM VC PC VTM +Out 14 V + - -In K Ro -Out Figure 14--VTM test circuit Application Note Parallel Operation In applications requiring higher current or redundancy, VTMs can be operated in parallel without adding control circuitry or signal lines. To maximize current sharing accuracy, it is imperative that the source and load impedance on each VTM in a parallel array be equal. If VTMs are being fed by an upstream PRM, the VC nodes of all VTMs must be connected to the PRM VC. To achieve matched impedances, dedicated power planes within the PC board should be used for the output and output return paths to the array of paralleled VTMs. This technique is preferable to using traces of varying size and length. The VTM power train and control architecture allow bi-directional power transfer when the VTM is operating within its specified ranges. Bi-directional power processing improves transient response in the event of an output load dump. The VTM may operate in reverse, returning output power back to the input source. It does so efficiently. Thermal Management The high efficiency of the VTM results in low power dissipation minimizing temperature rise, even at full output current. The heat generated within the internal semiconductor junctions is coupled through very low thermal resistances, RJC and RJB (see Figure 15), to the PC board allowing flexible thermal management. CASE 1 Convection via optional Heat Sink to air. In an environment with forced convection over the surface of a PCB with 0.4" of headroom, a VTM with a 0.25" heat sink offers a simple thermal management option. The total Junction to Ambient thermal resistance of a surface mounted V048F040T050 with a heat sink attached is 4.8 C/W in 300 LFM airflow, (see Figure 16). At 4 Vout and full rated current (50A), the VTM dissipates approximately 12 W per Figure 4. This results in a temperature rise of approximately 58 C, allowing operation in an air temperature of 67 C without exceeding the 125 C max junction temperature. CASE 2 Conduction via the PC board to air The low Junction to board thermal resistance allows the use of the PC board as a means of removing heat from the VTM. Convection from the PC board to ambient, or conduction to a cold plate, enable flexible thermal management options. With a VTM mounted on a 2.0 in2 area of a multi-layer PC board with appropriate power planes resulting in 8 oz of effective copper weight, the Junction-to-ambient thermal resistance, RJA, is 6.5 C/W in 300 LFM of air. With a maximum junction temperature of 125 C and 12 W of dissipation at full current of 50 A, the resulting temperature rise of 78 C allows the VTM to operate at full rated current up to a 47 C ambient temperature. Adding low-profile heat sinks to the PC board can lower the thermal resistance of the PC board surrounding the VTM. Additional cooling may be added by coupling a cold plate to the PC board with low thermal resistance stand offs. CASE 3 Combined direct convection to the air and conduction to the PC board. A combination of cooling techniques that utilize the power planes and dissipation to the air will also reduce the total thermal impedance. This is the most effective cooling method. To estimate the total effect of the combination, treat each cooling branch as one leg of a parallel resistor network. vicorpower.com 800-735-6200 V*I Chip Voltage Transformation Module V048F040T050 Rev. 1.1 Page 8 of 13 PRELIMINARY Application Note (continued) VTM with 0.25'' heat sink 10 9 8 Tja 7 6 5 4 3 0 100 200 300 400 500 600 Airflow (LFM) Figure 15--Thermal resistance Figure 16--Junction-to-ambient thermal resistance of VTM with 0.25" Heat Sink. V*I Chip VTM Level 1 DC Behavioral Model for 48 V to 4 V, 50 A IOUT ROUT 3.3 m 1/12* Iout + V*I + VIN IQ 85 mA + - K + - 1/12* Vin VOUT - - (c) Figure 17--This model characterizes the DC operation of the V*I Chip VTM, including the converter transfer function and its losses. The model enables estimates or simulations of output voltage as a function of input voltage and output load, as well as total converter power dissipation or heat generation. V*I Chip VTM Level 2 Transient Behavioral Model for 48 V to 4 V, 50 A 8.5 nH LIN = 5 nH IOUT ROUT 3.3 m LOUT = 1.1 nH + CIN VIN RCIN RCIN 1.3 m 1/12* Iout 1.9 F V*I IQ 40 m RCOUT RCOUT 0.7 m 255 F + 85 mA + - K + - 1/12* Vin COUT VOUT - - (c) Figure 18--This model characterizes the AC operation of the V*I Chip VTM including response to output load or input voltage transients or steady state modulations. The model enables estimates or simulations of input and output voltages under transient conditions, including response to a stepped load with or without external filtering elements. vicorpower.com 800-735-6200 V*I Chip Voltage Transformation Module V048F040T050 Rev. 1.1 Page 9 of 13 PRELIMINARY Application Note (continued) In figures below; K = VTM Transformation Ratio RO = VTM Output Resistance V*I Chip Voltage Transformation Module Vf = PRM Output (Factorized Bus Voltage) VO = VTM Output VL = Desired Load Voltage FPA Adaptive Loop Vo = VL 1.0% VC PC TM IL NC PR VH SC SG OS NC CD ROS RCD PRM-AL +In +Out Factorized Bus (Vf) Vf = VL (Io*Ro) + K K +In +Out -Out TM VC PC VTM +Out Vin -In -Out -In K Ro L O A D -Out Figure 19 -- The PRM controls the factorized bus voltage, Vf, in proportion to output current to compensate for the output resistance, Ro, of the VTM. The VTM output voltage is typically within 1% of the desired load voltage (VL) over all line and load conditions. FPA Non-isolated Remote Loop Remote Loop Control VC PC TM IL NC PR VH SC SG OS NC CD Vo = VL 0.4% PRM-AL +In +Out Factorized Power Bus Vf = f (Vs) +In +Out +S -Out TM VC PC VTM +Out Vin -In -Out -In K Ro -S -Out L O A D Figure 20 -- An external error amplifier or Point-of-Load IC (POLIC) senses the load voltage and controls the PRM output - the Factorized Bus - as a function of output current, compensating for the output resistance of the VTM and for distribution resistance. vicorpower.com 800-735-6200 V*I Chip Voltage Transformation Module V048F040T050 Rev. 1.1 Page 10 of 13 PRELIMINARY Application Note (continued) V*I Chip soldering recommendations V*I Chip modules are intended for reflow soldering processes. The following information defines the processing conditions required for successful attachment of a V*I Chip to a PCB. Failure to follow the recommendations provided can result in aesthetic or functional failure of the module. Storage V*I Chip modules are currently rated at MSL 5. Exposure to ambient conditions for more than 48 hours requires a 24 hour bake at 125C to remove moisture from the package. Solder paste stencil design Solder paste is recommended for a number of reasons, including overcoming minor solder sphere co-planarity issues as well as simpler integration into overall SMD process. 63/37 SnPb, either no-clean or water-washable, solder paste should be used. Pb-free development is underway. The recommended stencil thickness is 6 mils. The apertures should be 0.9-0.9:1. Pick and place Modules should be placed within 5 mils.to maintain placement position, the modules should not be subjected to acceleration greater than 500 in/sec2 prior to reflow. Reflow There are two temperatures critical to the reflow process; the solder joint temperature and the module's case temperature. The solder joint's temperature should reach at least 220C, with a time above liquidus (183C) of ~30 seconds. The module's case temperature must not exceed 208 C at anytime during reflow. Because of the T needed between the pin and the case, a forced-air convection oven is preferred for reflow soldering. This reflow method generally transfers heat from the PCB to the solder joint. The module's large mass also reduces its temperature rise. Care should be taken to prevent smaller devices from excessive temperatures. Reflow of modules onto a PCB using Air-Vac-type equipment is not recommended due to the high temperature the module will experience. Inspection The solder joints should conform to IPC 12.2 * Properly wetted fillet must be evident. * Heel fillet height must exceed lead thickness plus solder thickness. Figure 22 -- Properly reflowed V*I Chip J-Lead 16 Soldering Time Removal and rework V*I Chip modules can be removed from PCBs using special tools such as those made by Air-Vac. These tools heat a very localized region of the board with a hot gas while applying a tensile force to the component (using vacuum). Prior to component heating and removal, the entire board should be heated to 80-100C to decrease the component heating time as well as local PCB warping. If there are adjacent moisture-sensitive components, a 125C bake should be used prior to component removal to prevent popcorning. V*I Chip modules should not be expected to survive a removal operation. 239 Joint Temperature, 220C Case Temperature, 208C 183 165 degC 91 Figure 21 -- Thermal profile diagram vicorpower.com 800-735-6200 V*I Chip Voltage Transformation Module V048F040T050 Rev. 1.1 Page 11 of 13 PRELIMINARY Application Note (continued) Input Impedance Recommendations To take full advantage of the VTM's capabilities, the impedance of the source (input source plus the PC board impedance) must be low over a range from DC to 5 MHz. The input of the VTM (factorized bus) should be locally bypassed with a 8 F low Q aluminum electrolytic capacitor. Additional input capacitance may be added to improve transient performance or compensate for high source impedance. The VTM has extremely wide bandwidth so the source response to transients is usually the limiting factor in overall output response of the VTM. Anomalies in the response of the source will appear at the output of the VTM, multiplied by its K factor of 1/12. The DC resistance of the source should be kept as low as possible to minimize voltage deviations on the input to the VTM. If the VTM is going to be operating close to the high limit of its input range, make sure input voltage deviations will not trigger the input overvoltage turn-off threshold. V*I Chip Voltage Transformation Module Input Fuse Recommendations V*I Chips are not internally fused in order to provide flexibility in configuring power systems. However, input line fusing of V*I Chips must always be incorporated within the power system. A fast acting fuse is required to meet safety agency Conditions of Acceptability. The input line fuse should be placed in series with the +In port. Warranty Vicor products are guaranteed for two years from date of shipment against defects in material or workmanship when in normal use and service. This warranty does not extend to products subjected to misuse, accident, or improper application or maintenance. Vicor shall not be liable for collateral or consequential damage. This warranty is extended to the original purchaser only. EXCEPT FOR THE FOREGOING EXPRESS WARRANTY, VICOR MAKES NO WARRANTY, EXPRESS OR IMPLIED, INCLUDING, BUT NOT LIMITED TO, THE WARRANTY OF MERCHANTABILITY OR FITNESS FOR A PARTICULAR PURPOSE. Vicor will repair or replace defective products in accordance with its own best judgement. For service under this warranty, the buyer must contact Vicor to obtain a Return Material Authorization (RMA) number and shipping instructions. Products returned without prior authorization will be returned to the buyer. The buyer will pay all charges incurred in returning the product to the factory. Vicor will pay all reshipment charges if the product was defective within the terms of this warranty. Information published by Vicor has been carefully checked and is believed to be accurate; however, no responsibility is assumed for inaccuracies. Vicor reserves the right to make changes to any products without further notice to improve reliability, function, or design. Vicor does not assume any liability arising out of the application or use of any product or circuit; neither does it convey any license under its patent rights nor the rights of others. Vicor general policy does not recommend the use of its components in life support applications wherein a failure or malfunction may directly threaten life or injury. Per Vicor Terms and Conditions of Sale, the user of Vicor components in life support applications assumes all risks of such use and indemnifies Vicor against all damages. vicorpower.com 800-735-6200 V*I Chip Voltage Transformation Module V048F040T050 Rev. 1.1 Page 12 of 13 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 components are not designed to be used in applications, such as life support systems, wherein a failure or malfunction could result in injury or death. All sales are subject to Vicor's Terms and Conditions of Sale, which are available upon request. Specifications are subject to change without notice. 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. Interested parties should contact Vicor's Intellectual Property Department. Vicor Corporation 25 Frontage Road Andover, MA, USA 01810 Tel: 800-735-6200 Fax: 978-475-6715 email Vicor Express: vicorexp@vicr.com Technical Support: apps@vicr.com vicorpower.com 800-735-6200 V*I Chip Voltage Transformation Module V048F040T050 Rev. 1.1 11/05 |
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