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PSS30S71F6

PSS30S71F6

  • 厂商:

    POWEREX(鑫鸿)

  • 封装:

    DIP38

  • 描述:

  • 数据手册
  • 价格&库存
PSS30S71F6 数据手册
< DIPIPM > PSS30S71F6 TRANSFER MOLDING TYPE INSULATED TYPE OUTLINE MAIN FUNCTION AND RATINGS  3 phase DC/AC inverter  600V / 30A (CSTBT)  N-side IGBT open emitter  Built-in bootstrap diodes with current limiting resistor APPLICATION  AC 100~240Vrms(DC voltage:400V or below) class low power motor control TYPE NAME PSS30S71F6 With temperature output function INTEGRATED DRIVE, PROTECTION AND SYSTEM CONTROL FUNCTIONS ● For P-side : Drive circuit, High voltage high-speed level shifting, Control supply under-voltage (UV) protection ● For N-side : Drive circuit, Control supply under-voltage protection (UV), Short circuit protection (SC), ● Fault signaling : Corresponding to SC fault (N-side IGBT), UV fault (N-side supply) ● Temperature output : Outputting LVIC temperature by analog signal ● Input interface : 3, 5V line, Schmitt trigger receiver circuit (High Active) ● UL Recognized : UL1557 File E80276 INTERNAL CIRCUIT VUFS(1) VUFB(3) VP1(4) UP(6) DIPIPM P(37) HVIC1 IGBT1 Di1 HO U(36) VVFS(7) VVFB(9) HVIC2 IGBT2 VP1(10) VP(12) Di2 HO V(35) VWFS(13) VWFB(15) HVIC3 IGBT3 VP1(16) WP(18) Di3 HO W(34) IGBT4 LVIC VOT(20) Di4 UOUT NU(33) UN(21) IGBT5 VN(22) WN(23) Di5 VOUT NV(32) FO(24) IGBT6 CFO(25) CIN(26) Di6 WOUT NW(31) VNC(27) VN1(28) Publication Date : January 2021 ( 1 / 12 ) < DIPIPM > PSS30S71F6 TRANSFER MOLDING TYPE INSULATED TYPE MAXIMUM RATINGS (Tj = 25°C, unless otherwise noted) INVERTER PART Symbol VCC VCC(surge) VCES ±IC ±ICP PC Tj Parameter Supply voltage Supply voltage (surge) Collector-emitter voltage Each IGBT collector current Each IGBT collector current (peak) Collector dissipation Junction temperature Condition Applied between P-NU,NV,NW Applied between P-NU,NV,NW TC= 25°C TC= 25°C, less than 1ms TC= 25°C, per 1 chip (Note 1) Ratings 450 500 600 30 60 90.9 -20~+150 Unit V V V A A W °C Ratings 20 20 -0.5~VD+0.5 -0.5~VD+0.5 1 -0.5~VD+0.5 Unit V V V V mA V Ratings Unit 400 V -20~+100 -40~+125 °C °C 2500 Vrms Note1: Pulse width and period are limited due to junction temperature. CONTROL (PROTECTION) PART Symbol VD VDB VIN VFO IFO VSC Parameter Control supply voltage Control supply voltage Input voltage Fault output supply voltage Fault output current Current sensing input voltage Condition Applied between VP1-VNC, VN1-VNC Applied between VUFB-VUFS, VVFB-VVFS ,VWFB-VWFS Applied between UP, VP, WP-VPC, UN, VN, WN-VNC Applied between FO-VNC Sink current at FO terminal Applied between CIN-VNC TOTAL SYSTEM Symbol TC Tstg Parameter Self protection supply voltage limit (Short circuit protection capability) Module case operation temperature Storage temperature Viso Isolation voltage VCC(PROT) Condition VD = 13.5~16.5V, Inverter Part Tj = 125°C, non-repetitive, less than 2μs Measurement point of Tc is provided in Fig.1 60Hz, Sinusoidal, AC 1min, between connected all pins and heat sink plate Fig. 1: TC MEASUREMENT POINT Control terminals 17.7mm 18mm Groove IGBT chip position FWDi chip position Tc point Heat sink side Power terminals THERMAL RESISTANCE Symbol Rth(j-c)Q Rth(j-c)F Parameter Junction to case thermal resistance (Note 2) Condition Inverter IGBT part (per 1/6 module) Inverter FWDi part (per 1/6 module) Min. - Limits Typ. - Max. 1.1 2.8 Unit K/W K/W Note 2: Grease with good thermal conductivity and long-term endurance should be applied evenly with about +100μm~+200μm on the contacting surface of DIPIPM and heat sink. The contacting thermal resistance between DIPIPM case and heat sink Rth(c-f) is determined by the thickness and the thermal conductivity of the applied grease. For reference, Rth(c-f) is about 0.3K/W (per 1/6 module, grease thickness: 20μm, thermal conductivity: 1.0W/m•k). Publication Date :January 2021 ( 2 / 12 ) < DIPIPM > PSS30S71F6 TRANSFER MOLDING TYPE INSULATED TYPE ELECTRICAL CHARACTERISTICS (Tj = 25°C, unless otherwise noted) INVERTER PART Symbol VCE(sat) VEC ton tC(on) toff tC(off) trr ICES Parameter Condition IC= 30A, Tj= 25°C IC= 30A, Tj= 125°C Collector-emitter saturation voltage VD=VDB = 15V, VIN= 5V FWDi forward voltage VIN= 0V, -IC= 30A Switching times VCC= 300V, VD= VDB= 15V IC= 30A, Tj= 125°C, VIN= 0↔5V Inductive Load (upper-lower arm) Collector-emitter cut-off current VCE=VCES Tj= 25°C Tj= 125°C Min. 0.95 - Limits Typ. 1.40 1.50 1.50 1.55 0.50 1.75 0.40 0.30 - Max. 1.90 2.00 2.00 2.15 0.80 2.35 0.60 1 10 Min. 0.45 10.0 10.5 10.3 10.8 2.51 4.9 1.6 0.70 0.80 Limits Typ. 0.48 2.64 2.4 1.00 2.10 1.30 Max. 6.00 6.00 0.55 0.55 0.51 12.0 12.5 12.5 13.0 2.76 0.95 1.50 2.60 - 0.35 0.80 - 0.5 16 0.9 20 1.3 24 Unit V V μs μs μs μs μs mA CONTROL (PROTECTION) PART Symbol Parameter Condition ID Total of VP1-VNC, VN1-VNC Circuit current Each part of VUFB- VUFS, VVFB- VVFS, VWFB- VWFS IDB VSC(ref) UVDBt UVDBr UVDt UVDr VOT VFOH VFOL tFO IIN Vth(on) Vth(off) Vth(hys) VF R Short circuit trip level VD=15V, VIN=0V VD=15V, VIN=5V VD=VDB=15V, VIN=0V VD=VDB=15V, VIN=5V VD = 15V P-side Control supply under-voltage protection(UV) N-side Control supply under-voltage protection(UV) Temperature Output Fault output voltage Fault output pulse width Input current ON threshold voltage OFF threshold voltage ON/OFF threshold hysteresis voltage Bootstrap Di forward voltage Built-in limiting resistance (Note 3) Trip level Reset level Trip level Reset level Tj ≤125°C Pull down R=5kΩ (Note 4) LVIC Temperature=85C VSC = 0V, FO terminal pulled up to 5V by 10kΩ VSC = 1V, IFO = 1mA (Note 5) CFO=22nF VIN = 5V Applied between UP, VP, WP, UN, VN, WN-VNC IF=10mA including voltage drop by limiting resistor (Note 6) Included in bootstrap Di Unit mA V V V V V V V V ms mA V V Ω Note 3 : SC protection works only for N-side IGBT. Please select the external shunt resistance such that the SC trip-level is less than 2.0 times of the current rating. 4 : DIPIPM don't shutdown IGBTs and output fault signal automatically when temperature rises excessively. When temperature exceeds the protective level that user defined, controller (MCU) should stop the DIPIPM. Temperature of LVIC vs. VOT output characteristics is described in Fig. 3. 5 : Fault signal Fo outputs when SC or UV protection works. Fo pulse width is different for each protection modes. At SC failure, Fo pulse width is a fixed width which is specified by the capacitor connected to CFO terminal. (CFO=9.1 x 10-6 x tFO [F]), but at UV failure, Fo outputs continuously until recovering from UV state. (But minimum Fo pulse width is the specified time by CFO.) 6 : The characteristics of bootstrap Di is described in Fig.2. Fig. 2 Characteristics of bootstrap Di VF-IF curve (@Ta=25C) including voltage drop by limiting resistor (Right chart is enlarged chart.) 800 50 700 45 40 600 35 IF [mA] IF [mA] 500 400 300 30 25 20 15 200 10 100 5 0 0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 VF [V] Publication Date :January 2021 ( 3 / 12 ) 0 0.0 0.2 0.4 0.6 0.8 1.0 VF [V] 1.2 1.4 1.6 1.8 < DIPIPM > PSS30S71F6 TRANSFER MOLDING TYPE INSULATED TYPE Fig. 3 Temperature of LVIC vs. VOT output characteristics 3.5 Max. 3.3 Typ. Min. 3.1 2.9 VOT output (V)_ 2.7 2.76 2.64 2.5 2.51 2.3 2.1 1.9 1.7 1.5 55 65 75 85 95 105 115 LVIC temperature (°C) Fig. 4 VOT output circuit Inside LVIC of DIPIPM Temperature Signal VOT Ref VNC MCU 5kΩ (1) It is recommended to insert 5kΩ (5.1kΩ is recommended) pull down resistor for getting linear output characteristics at low temperature below room temperature. When the pull down resistor is inserted between VOT and VNC(control GND), the extra circuit current, which is calculated approximately by VOT output voltage divided by pull down resistance, flows as LVIC circuit current continuously. In the case of using VOT for detecting high temperature over room temperature only, it is unnecessary to insert the pull down resistor. (2) In the case of using VOT with low voltage controller like 3.3V MCU, VOT output might exceed control supply voltage 3.3V when temperature rises excessively. If system uses low voltage controller, it is recommended to insert a clamp Di between control supply of the controller and VOT output for preventing over voltage destruction. (3) In the case of not using VOT, leave VOT output NC (No Connection). Refer the application note for this product about the usage of VOT. Publication Date :January 2021 ( 4 / 12 ) < DIPIPM > PSS30S71F6 TRANSFER MOLDING TYPE INSULATED TYPE MECHANICAL CHARACTERISTICS AND RATINGS Parameter Condition Mounting torque Terminal pulling strength Terminal bending strength Mounting screw : M3 (Note 7) Load 9.8N Load 4.9N, 90deg. bend Recommended 0.78Nꞏm JEITA-ED-4701 JEITA-ED-4701 Min. 0.59 10 2 Limits Typ. - - 21 - g -50 - 100 μm Weight Heat-sink flatness (Note 8) Max. 0.98 - Unit Nꞏm s times Note 7: Plain washers (ISO 7089~7094) are recommended. Note 8: Measurement point of heat sink flatness 12.78mm Measurement position -+ 4.65mm 13.5mm 23mm Heat sink side + - Heat sink side RECOMMENDED OPERATION CONDITIONS Symbol Parameter VCC VD VDB ΔVD, ΔVDB tdead fPWM Supply voltage Control supply voltage Control supply voltage Control supply variation Arm shoot-through blocking time PWM input frequency IO Allowable r.m.s. current VNC Tj Limits Typ. 300 15.0 15.0 - Max. 400 16.5 18.5 +1 20 fPWM= 5kHz - - 21.0 fPWM= 15kHz - - 16.0 0.7 1.5 - - 3.0 - - 3.6 - - -5.0 -20 - +5.0 +125 Applied between P-NU, NV, NW Applied between VP1-VNC, VN1-VNC Applied between VUFB-VUFS, VVFB-VVFS, VWFB-VWFS For each input signal TC ≤ 100°C, Tj ≤ 125°C VCC = 300V, VD = 15V, P.F = 0.8, Sinusoidal PWM (Note9) TC ≤ 100°C, Tj ≤ 125°C PWIN(on) PWIN(off) Min. 0 13.5 13.0 -1 1.5 - Condition (Note 10) Minimum input pulse width VNC variation Junction temperature Below rated current 200VVCC350V, Between rated current 13.5VVD16.5V, and 1.7 times of rated 13.0VVDB18.5V, current -20CTc100C, Between 1.7 times and N-line wiring inductance 2.0 times of rated current less than 10nH (Note 11) Between VNC-NU, NV, NW (including surge) Unit V V V V/μs μs kHz Arms μs V °C Note 9: Allowable r.m.s. current depends on the actual application conditions. 10: DIPIPM might not make response if the input signal pulse width is less than PWIN(on) 11: IPM might make delayed response or no response for the input signal with off pulse width less than PWIN(off). Please refer below about delayed response. Delayed Response against Shorter Input Off Signal than PWIN(off) (P-side only) P Side Control Input Real line: off pulse width > PWIN(off); turn on time t1 Broken line: off pulse width < PWIN(off); turn on time t2 (t1:Normal switching time) Internal IGBT Gate Output Current Ic t2 t1 Publication Date :January 2021 ( 5 / 12 ) < DIPIPM > PSS30S71F6 TRANSFER MOLDING TYPE INSULATED TYPE Fig. 5 Timing Charts of The DIPIPM Protective Functions [A] Short-Circuit Protection (N-side only with the external shunt resistor and RC filter) a1. Normal operation: IGBT ON and outputs current. a2. Short circuit current detection (SC trigger) (It is recommended to set RC time constant 1.5~2.0μs so that IGBT shut down within 2.0μs when SC.) a3. All N-side IGBT's gates are hard interrupted. a4. All N-side IGBTs turn OFF. a5. FO outputs. The pulse width of the Fo signal is set by the external capacitor CFO. a6. Input = “L”: IGBT OFF a7. Fo finishes output, but IGBTs don't turn on until inputting next ON signal (LH). (IGBT of each phase can return to normal state by inputting ON signal to each phase.) a8. Normal operation: IGBT ON and outputs current. Lower-side control input a6 SET Protection circuit state RESET a3 Internal IGBT gate a4 SC trip current level Output current Ic a8 a1 a7 a2 SC reference voltage Sense voltage of the shunt resistor Delay by RC filtering Error output Fo a5 [B] Under-Voltage Protection (N-side, UVD) b1. Control supply voltage V D exceeds under voltage reset level (UVDr), but IGBT turns ON by next ON signal (LH). (IGBT of each phase can return to normal state by inputting ON signal to each phase.) b2. Normal operation: IGBT ON and outputs current. b3. VD level drops to under voltage trip level. (UVDt). b4. All N-side IGBTs turn OFF in spite of control input condition. b5. Fo outputs for the period set by the capacitance CFO, but output is extended during VD keeps below UVDr. b6. VD level reaches UVDr. b7. Normal operation: IGBT ON and outputs current. Control input RESET Protection circuit state Control supply voltage VD UVDr SET b1 UVDt b2 b3 b4 Output current Ic Error output Fo b5 Publication Date :January 2021 ( 6 / 12 ) RESET b6 b7 < DIPIPM > PSS30S71F6 TRANSFER MOLDING TYPE INSULATED TYPE [C] Under-Voltage Protection (P-side, UVDB) c1. Control supply voltage VDB rises. After the voltage reaches under voltage reset level UVDBr, IGBT turns on by next ON signal (LH). c2. Normal operation: IGBT ON and outputs current. c3. VDB level drops to under voltage trip level (UVDBt). c4. IGBT of the correspond phase only turns OFF in spite of control input signal level, but there is no FO signal output. c5. VDB level reaches UVDBr. c6. Normal operation: IGBT ON and outputs current. Control input RESET Protection circuit state SET UVDBr Control supply voltage VDB RESET c3 c1 c5 UVDBt c2 c4 c6 Output current Ic Error output Fo Keep High-level (no fault output) Publication Date :January 2021 ( 7 / 12 ) < DIPIPM > PSS30S71F6 TRANSFER MOLDING TYPE INSULATED TYPE Fig. 6 Example of Application Circuit P VUFB(3) + IGBT1 Di1 VUFS(1) C1 D1 C2 HVIC VP1(4) C2 U UP(6) VVFB(9) + IGBT2 Di2 VVFS(7) C1 D1 C2 HVIC VP1(10) C2 V VP(12) VWFB(15) IGBT3 + M Di3 VWFS(13) C1 D1 C2 C2 HVIC VP1(16) W MCU WP(18) + Di4 IGBT4 C3 VOT(20) 5kΩ UN(21) NU VN(22) IGBT5 Di5 WN(23) 5V NV R2 LVIC Fo(24) IGBT6 Di6 CFO(25) 15V VD C1 + D1 NW VN1(28) C2 Long wiring here might cause short circuit failure VNC(27) Long wiring here might cause SC level fluctuation and malfunction. CIN(26) Long GND wiring here might generate noise to input signal and cause IGBT malfunction. B C4 C D R1 Shunt resistor A Control GND wiring N1 Power GND wiring (1) If control GND is connected with power GND by common broad pattern, it may cause malfunction by power GND fluctuation. It is recommended to connect control GND and power GND at only a point N1 (near the terminal of shunt resistor). (2) It is recommended to insert a Zener diode D1(24V/1W) between each pair of control supply terminals to prevent surge destruction. (3) To prevent surge destruction, the wiring between the smoothing capacitor and the P, N1 terminals should be as short as possible. Generally a 0.1-0.22μF snubber capacitor C3 between the P-N1 terminals is recommended. (4) R1, C4 of RC filter for preventing protection circuit malfunction is recommended to select tight tolerance, temp-compensated type. The time constant R1C4 should be set so that SC current is shut down within 2μs. (1.5μs~2μs is recommended generally.) SC interrupting time might vary with the wiring pattern, so the enough evaluation on the real system is necessary. (5) To prevent malfunction, the wiring of A, B, C should be as short as possible. (6) The point D at which the wiring to CIN filter is divided should be near the terminal of shunt resistor. NU, NV, NW terminals should be connected at near NU, NV, NW terminals when it is used by one shunt operation. Low inductance SMD type with tight tolerance, temp-compensated type is recommended for shunt resistor. (7) All capacitors should be mounted as close to the terminals as possible. (C1: good temperature, frequency characteristic electrolytic type and C2:0.22μ-2μF, good temperature, frequency and DC bias characteristic ceramic type are recommended.) (8) Input logic is High-active. There is a 3.3kΩ(min.) pull-down resistor in the input circuit of IC. To prevent malfunction, the input wiring should be as short as possible. When using RC coupling, make the input signal level meet the turn-on and turn-off threshold voltage. (9) Fo output is open drain type. It should be pulled up to power supply of MCU (e.g. 5V,3.3V) by a resistor that makes IFo up to 1mA. (IFO is estimated roughly by the formula of control power supply voltage divided by pull-up resistance. In the case of pulled up to 5V, 10kΩ (5kΩ or more) is recommended.) When using opto coupler, Fo also can be pulled up to 15V (control supply of DIPIPM) by the resistor. (10) Fo pulse width can be set by the capacitor connected to CFO terminal. CFO(F) = 9.1 x 10-6 x tFO (Required Fo pulse width). (11) If high frequency noise superimposed to the control supply line, IC malfunction might happen and cause DIPIPM erroneous operation. To avoid such problem, line ripple voltage should meet dV/dt ≤+/-1V/μs, Vripple≤2Vp-p. (12) For DIPIPM, it isn't recommended to drive same load by parallel connection with other phase IGBT or other DIPIPM. Publication Date :January 2021 ( 8 / 12 ) < DIPIPM > PSS30S71F6 TRANSFER MOLDING TYPE INSULATED TYPE Fig. 7 MCU I/O Interface Circuit 5V line 10kΩ Note) Design for input RC filter depends on PWM control scheme used in the application and wiring impedance of the printed circuit board. DIPIPM input signal interface integrates a minimum 3.3kΩ pull-down resistor. Therefore, when inserting RC filter, it is necessary to satisfy turn-on threshold voltage requirement. Fo output is open drain type. It should be pulled up to control power supply (e.g. 5V, 15V) with a resistor that makes Fo sink current IFo 1mA or less. In the case of pulled up to 5V supply, 10kΩ (5kΩ or more) is recommended. DIPIPM UP,VP,WP,UN,VN,WN MCU 3.3kΩ(min) Fo VNC(Logic) Fig. 8 Pattern Wiring Around the Shunt Resistor NU, NV, NW should be connected each other at near terminals. DIPIPM DIPIPM Each wiring Inductance should be less than 10nH. Wiring Inductance should be less than 10nH. Inductance of a copper pattern with length=17mm, width=3mm is about 10nH. Inductance of a copper pattern with length=17mm, width=3mm is about 10nH. NU NV NW VNC N1 Shunt resistor NU NV NW VNC GND wiring from VNC should be connected close to the terminal of shunt resistor. N1 Shunt resistors GND wiring from VNC should be connected close to the terminal of shunt resistor. Low inductance shunt resistor like surface mounted (SMD) type is recommended. Fig. 9 Pattern Wiring Around the Shunt Resistor (for the case of open emitter) When DIPIPM is operated with three shunt resistors, voltage of each shunt resistor cannot be input to CIN terminal directly. In that case, it is necessary to use the external protection circuit as below. DIPIPM Drive circuit P P-side IGBT U V W External protection circuit Comparators (Open collector output type) N-side IGBT Rf C Drive circuit VNC NW NV NU Protection circuit CIN Cf B - Vref + Vref + Vref + 5V D Shunt resistors A OR output - N1 (1) It is necessary to set the time constant RfCf of external comparator input so that IGBT stops within 2μs when short circuit occurs. SC interrupting time might vary with the wiring pattern, comparator speed and so on. (2) It is recommended for the threshold voltage Vref to set to the same rating of short circuit trip level (Vsc(ref): typ. 0.48V). (3) Select the external shunt resistance so that SC trip-level is less than specified value (=2.0 times of rating current). (4) To avoid malfunction, the wiring A, B, C should be as short as possible. (5) The point D at which the wiring to comparator is divided should be close to the terminal of shunt resistor. (6) OR output high level when protection works should be over 0.51V (=maximum Vsc(ref) rating). (7) GND of Comparator, GND of Vref circuit and Cf should be not connected to power GND but to control GND wiring. Publication Date :January 2021 ( 9 / 12 ) < DIPIPM > PSS30S71F6 TRANSFER MOLDING TYPE INSULATED TYPE Fig. 10 Package Outlines 2D CODE Terminal of ( ) is the dummy terminal for internal use. This terminal should be kept NC (no connection). Dimensions in mm Publication Date :January 2021 ( 10 / 12 ) < DIPIPM > PSS30S71F6 TRANSFER MOLDING TYPE INSULATED TYPE Important Notice The information contained in this datasheet shall in no event be regarded as a guarantee of conditions or characteristics. This product has to be used within its specified maximum ratings, and is subject to customer’s compliance with any applicable legal requirement, norms and standards. Except as otherwise explicitly approved by Mitsubishi Electric Corporation in a written document signed by authorized representatives of Mitsubishi Electric Corporation, our products may not be used in any applications where a failure of the product or any consequences of the use thereof can reasonably be expected to result in personal injury. In usage of power semiconductor, there is always the possibility that trouble may occur with them by the reliability lifetime such as Power Cycle, Thermal Cycle or others, or when used under special circumstances (e.g. condensation, high humidity, dusty, salty, highlands, environment with lots of organic matter / corrosive gas / explosive gas, or situations which terminals of semiconductor products receive strong mechanical stress). Therefore, please pay sufficient attention to such circumstances. Further, depending on the technical requirements, our semiconductor products may contain environmental regulation substances, etc. If there is necessity of detailed confirmation, please contact our nearest sales branch or distributor. The contents or data contained in this datasheet are exclusively intended for technically trained staff. Customer's technical departments should take responsibility to evaluate the suitability of Mitsubishi Electric Corporation product for the intended application and the completeness of the product data with respect to such application. In the customer's research and development, please evaluate it not only with a single semiconductor product but also in the entire system, and judge whether it's applicable. As required, pay close attention to the safety design by installing appropriate fuse or circuit breaker between a power supply and semiconductor products to prevent secondary damage. Please also pay attention to the application note and the related technical information. Publication Date :January 2021 ( 11 / 12 ) < DIPIPM > PSS30S71F6 TRANSFER MOLDING TYPE INSULATED TYPE Keep safety first in your circuit designs! Mitsubishi Electric Corporation puts the maximum effort into making semiconductor products better and more reliable, but there is always the possibility that trouble may occur with them. Trouble with semiconductors may lead to personal injury, fire or property damage. Remember to give due consideration to safety when making your circuit designs, with appropriate measures such as (i) placement of substitutive, auxiliary circuits, (ii) use of non-flammable material or (iii) prevention against any malfunction or mishap. Notes regarding these materials •These materials are intended as a reference to assist our customers in the selection of the Mitsubishi Electric Semiconductor product best suited to the customer’s application; they do not convey any license under any intellectual property rights, or any other rights, belonging to Mitsubishi Electric Corporation or a third party. •Mitsubishi Electric Corporation assumes no responsibility for any damage, or infringement of any third-party’s rights, originating in the use of any product data, diagrams, charts, programs, algorithms, or circuit application examples contained in these materials. •All information contained in these materials, including product data, diagrams, charts, programs and algorithms represents information on products at the time of publication of these materials, and are subject to change by Mitsubishi Electric Corporation without notice due to product improvements or other reasons. It is therefore recommended that customers contact Mitsubishi Electric Corporation or an authorized Mitsubishi Electric Semiconductor product distributor for the latest product information before purchasing a product listed herein. The information described here may contain technical inaccuracies or typographical errors. Mitsubishi Electric Corporation assumes no responsibility for any damage, liability, or other loss rising from these inaccuracies or errors. Please also pay attention to information published by Mitsubishi Electric Corporation by various means, including the Mitsubishi Electric Semiconductor home page (http://www.MitsubishiElectric.com/semiconductors/). •When using any or all of the information contained in these materials, including product data, diagrams, charts, programs, and algorithms, please be sure to evaluate all information as a total system before making a final decision on the applicability of the information and products. Mitsubishi Electric Corporation assumes no responsibility for any damage, liability or other loss resulting from the information contained herein. •Mitsubishi Electric Corporation semiconductors are not designed or manufactured for use in a device or system that is used under circumstances in which human life is potentially at stake. Please contact Mitsubishi Electric Corporation or an authorized Mitsubishi Electric Semiconductor product distributor when considering the use of a product contained herein for any specific purposes, such as apparatus or systems for transportation, vehicular, medical, aerospace, nuclear, or undersea repeater use. •The prior written approval of Mitsubishi Electric Corporation is necessary to reprint or reproduce in whole or in part these materials. •If these products or technologies are subject to the Japanese export control restrictions, they must be exported under a license from the Japanese government and cannot be imported into a country other than the approved destination. Any diversion or re-export contrary to the export control laws and regulations of Japan and/or the country of destination is prohibited. •Please contact Mitsubishi Electric Corporation or an authorized Mitsubishi Electric Semiconductor product distributor for further details on these materials or the products contained therein. © MITSUBISHI ELECTRIC CORPORATION. ALL RIGHTS RESERVED. DIPIPM and CSTBT are trademarks of MITSUBISHI ELECTRIC CORPORATION. Publication Date :January 2021 ( 12 / 12 )
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