產(chǎn)品線卡
Nexperia總部位于荷蘭,是一家在歐洲擁有豐富悠久發(fā)展歷史的全球性半導(dǎo)體公司,目前在歐洲、亞洲和美國(guó)共有14,000多名員工。作為基礎(chǔ)半導(dǎo)體器件開發(fā)和生產(chǎn)的領(lǐng)跑者,Nexperia的器件被廣泛應(yīng)用于汽車、工業(yè)、移動(dòng)和消費(fèi)等多個(gè)應(yīng)用領(lǐng)域,幾乎為世界上所有電子設(shè)計(jì)的基本功能提供支持。
Nexperia為全球客戶提供服務(wù),每年的產(chǎn)品出貨量超過(guò)1,000億件。這些產(chǎn)品在效率(如工藝、尺寸、功率及性能)方面成為行業(yè)基準(zhǔn),獲得廣泛認(rèn)可。Nexperia擁有豐富的IP產(chǎn)品組合和持續(xù)擴(kuò)充的產(chǎn)品范圍,并獲得了IATF 16949、ISO 9001、ISO 14001和ISO 45001標(biāo)準(zhǔn)認(rèn)證,充分體現(xiàn)了公司對(duì)于創(chuàng)新、高效和滿足行業(yè)嚴(yán)苛要求的堅(jiān)定承諾。
產(chǎn)品
Low voltage e-mode GaN FETs
Optimum flexibility for high-power
Delivering optimum flexibility in power systems, Nexperia e-mode GaN FETs are ideal for high-power <200 V applications. Offering superior switching performance due very low QC and QOSS values. Enabling faster charging for e-mobility and wired / wireless changing systems as well as significant space and BOM savings in LiDAR and lower noise in Class D audio amplifiers.
Delivering optimum flexibility in power systems, Nexperia e-mode GaN FETs are ideal for high-power <200 V applications. Offering superior switching performance due very low QC and QOSS values. Enabling faster charging for e-mobility and wired / wireless changing systems as well as significant space and BOM savings in LiDAR and lower noise in Class D audio amplifiers.
Optimum flexibility for high-power
Delivering optimum flexibility in power systems, Nexperia e-mode GaN FETs are ideal for high-power <200 V applications. Offering superior switching performance due very low QC and QOSS values. Enabling faster charging for e-mobility and wired / wireless changing systems as well as significant space and BOM savings in LiDAR and lower noise in Class D audio amplifiers.
Delivering optimum flexibility in power systems, Nexperia e-mode GaN FETs are ideal for high-power <200 V applications. Offering superior switching performance due very low QC and QOSS values. Enabling faster charging for e-mobility and wired / wireless changing systems as well as significant space and BOM savings in LiDAR and lower noise in Class D audio amplifiers.
650 V cascode GaN FETs
Performance, efficiency, reliability
The very high electron mobility of GaN enables the creation of devices with low on-resistance and exceptionally high switching frequency capability. These advantages are vital in next-generation power systems, such as industry 4.0 and renewable energy applications. Nexperia cascode GaN FETs are the enabler in these applications offering high power density, high performance, and high switching frequency. This unique solution facilitates the ease of driving the devices using well-known Si MOSFET gate drivers. Additionally, they deliver unmatched high junction temperature (Tj [max] 175 °C), ease of design freedom and improved reliability of power systems.
The very high electron mobility of GaN enables the creation of devices with low on-resistance and exceptionally high switching frequency capability. These advantages are vital in next-generation power systems, such as industry 4.0 and renewable energy applications. Nexperia cascode GaN FETs are the enabler in these applications offering high power density, high performance, and high switching frequency. This unique solution facilitates the ease of driving the devices using well-known Si MOSFET gate drivers. Additionally, they deliver unmatched high junction temperature (Tj [max] 175 °C), ease of design freedom and improved reliability of power systems.
Performance, efficiency, reliability
The very high electron mobility of GaN enables the creation of devices with low on-resistance and exceptionally high switching frequency capability. These advantages are vital in next-generation power systems, such as industry 4.0 and renewable energy applications. Nexperia cascode GaN FETs are the enabler in these applications offering high power density, high performance, and high switching frequency. This unique solution facilitates the ease of driving the devices using well-known Si MOSFET gate drivers. Additionally, they deliver unmatched high junction temperature (Tj [max] 175 °C), ease of design freedom and improved reliability of power systems.
The very high electron mobility of GaN enables the creation of devices with low on-resistance and exceptionally high switching frequency capability. These advantages are vital in next-generation power systems, such as industry 4.0 and renewable energy applications. Nexperia cascode GaN FETs are the enabler in these applications offering high power density, high performance, and high switching frequency. This unique solution facilitates the ease of driving the devices using well-known Si MOSFET gate drivers. Additionally, they deliver unmatched high junction temperature (Tj [max] 175 °C), ease of design freedom and improved reliability of power systems.
Bi-directional GaN FETs
Unconventional innovative GaN solution in BMS
Nexperia’s bi-directional GaN FETs are ideal for power applications where voltage blocking and current conduction are important functions. For example, they deliver a superior solution when replacing conventional back-to-back silicon MOSFETs in Battery Management Systems (BMS). Guaranteeing low conduction losses and ultra-high switching speed capability as well as delivering significant space savings (smallest footprint). They also bring these benefits when applied as over-voltage protection (OVP), switching circuits for multiple power sources and high side load switches in bidirectional converters.
Nexperia’s bi-directional GaN FETs are ideal for power applications where voltage blocking and current conduction are important functions. For example, they deliver a superior solution when replacing conventional back-to-back silicon MOSFETs in Battery Management Systems (BMS). Guaranteeing low conduction losses and ultra-high switching speed capability as well as delivering significant space savings (smallest footprint). They also bring these benefits when applied as over-voltage protection (OVP), switching circuits for multiple power sources and high side load switches in bidirectional converters.
Unconventional innovative GaN solution in BMS
Nexperia’s bi-directional GaN FETs are ideal for power applications where voltage blocking and current conduction are important functions. For example, they deliver a superior solution when replacing conventional back-to-back silicon MOSFETs in Battery Management Systems (BMS). Guaranteeing low conduction losses and ultra-high switching speed capability as well as delivering significant space savings (smallest footprint). They also bring these benefits when applied as over-voltage protection (OVP), switching circuits for multiple power sources and high side load switches in bidirectional converters.
Nexperia’s bi-directional GaN FETs are ideal for power applications where voltage blocking and current conduction are important functions. For example, they deliver a superior solution when replacing conventional back-to-back silicon MOSFETs in Battery Management Systems (BMS). Guaranteeing low conduction losses and ultra-high switching speed capability as well as delivering significant space savings (smallest footprint). They also bring these benefits when applied as over-voltage protection (OVP), switching circuits for multiple power sources and high side load switches in bidirectional converters.
650 V e-mode GaN FETs
Optimized balance of voltage and power
Delivering optimum flexibility in power systems, Nexperia e-mode GaN FETs are ideal for low-power 650 V applications. Offering superior switching performance due very low QC and QOSS values, they bring improved efficiency to 650 V AC/DC and DC/AC power conversion. As well as bringing significant space and BOM savings in BLDC and micro servo motor drives or LED drivers.
Delivering optimum flexibility in power systems, Nexperia e-mode GaN FETs are ideal for low-power 650 V applications. Offering superior switching performance due very low QC and QOSS values, they bring improved efficiency to 650 V AC/DC and DC/AC power conversion. As well as bringing significant space and BOM savings in BLDC and micro servo motor drives or LED drivers.
Optimized balance of voltage and power
Delivering optimum flexibility in power systems, Nexperia e-mode GaN FETs are ideal for low-power 650 V applications. Offering superior switching performance due very low QC and QOSS values, they bring improved efficiency to 650 V AC/DC and DC/AC power conversion. As well as bringing significant space and BOM savings in BLDC and micro servo motor drives or LED drivers.
Delivering optimum flexibility in power systems, Nexperia e-mode GaN FETs are ideal for low-power 650 V applications. Offering superior switching performance due very low QC and QOSS values, they bring improved efficiency to 650 V AC/DC and DC/AC power conversion. As well as bringing significant space and BOM savings in BLDC and micro servo motor drives or LED drivers.
NGW75T65M3DFP
650 V, 75 A trench field-stop IGBT with full rated silicon diode
The NGW75T65M3DFP is a robust Insulated-Gate Bipolar Transistor (IGBT) featuring third??-??generation technology. It combines carrier stored trench-gate and field-stop (FS) structures. The NGW75T65M3DFP is rated to 175 °C with optimized IGBT turn-off losses, and has a short-circuit withstand time of 5 μs. This hard?-?switching 650 V, 75 A IGBT is optimized for high?-?voltage, high?-?frequency industrial power inverter applications and servo motor drive applications.
The NGW75T65M3DFP is a robust Insulated-Gate Bipolar Transistor (IGBT) featuring third??-??generation technology. It combines carrier stored trench-gate and field-stop (FS) structures. The NGW75T65M3DFP is rated to 175 °C with optimized IGBT turn-off losses, and has a short-circuit withstand time of 5 μs. This hard?-?switching 650 V, 75 A IGBT is optimized for high?-?voltage, high?-?frequency industrial power inverter applications and servo motor drive applications.
650 V, 75 A trench field-stop IGBT with full rated silicon diode
The NGW75T65M3DFP is a robust Insulated-Gate Bipolar Transistor (IGBT) featuring third??-??generation technology. It combines carrier stored trench-gate and field-stop (FS) structures. The NGW75T65M3DFP is rated to 175 °C with optimized IGBT turn-off losses, and has a short-circuit withstand time of 5 μs. This hard?-?switching 650 V, 75 A IGBT is optimized for high?-?voltage, high?-?frequency industrial power inverter applications and servo motor drive applications.
The NGW75T65M3DFP is a robust Insulated-Gate Bipolar Transistor (IGBT) featuring third??-??generation technology. It combines carrier stored trench-gate and field-stop (FS) structures. The NGW75T65M3DFP is rated to 175 °C with optimized IGBT turn-off losses, and has a short-circuit withstand time of 5 μs. This hard?-?switching 650 V, 75 A IGBT is optimized for high?-?voltage, high?-?frequency industrial power inverter applications and servo motor drive applications.
NGW75T65H3DFP
650 V, 75 A trench field-stop IGBT with full rated silicon diode
The NGW75T65H3DFP is a robust Insulated-Gate Bipolar Transistor (IGBT) featuring third??-??generation technology. It combines carrier stored trench-gate and field-stop (FS) structures. The NGW75T65H3DFP is rated to 175 °C with optimized IGBT turn-off losses. This hard?-?switching 650 V, 75 A IGBT is optimized for high?-?voltage, high?-?frequency industrial power inverter applications.
The NGW75T65H3DFP is a robust Insulated-Gate Bipolar Transistor (IGBT) featuring third??-??generation technology. It combines carrier stored trench-gate and field-stop (FS) structures. The NGW75T65H3DFP is rated to 175 °C with optimized IGBT turn-off losses. This hard?-?switching 650 V, 75 A IGBT is optimized for high?-?voltage, high?-?frequency industrial power inverter applications.
650 V, 75 A trench field-stop IGBT with full rated silicon diode
The NGW75T65H3DFP is a robust Insulated-Gate Bipolar Transistor (IGBT) featuring third??-??generation technology. It combines carrier stored trench-gate and field-stop (FS) structures. The NGW75T65H3DFP is rated to 175 °C with optimized IGBT turn-off losses. This hard?-?switching 650 V, 75 A IGBT is optimized for high?-?voltage, high?-?frequency industrial power inverter applications.
The NGW75T65H3DFP is a robust Insulated-Gate Bipolar Transistor (IGBT) featuring third??-??generation technology. It combines carrier stored trench-gate and field-stop (FS) structures. The NGW75T65H3DFP is rated to 175 °C with optimized IGBT turn-off losses. This hard?-?switching 650 V, 75 A IGBT is optimized for high?-?voltage, high?-?frequency industrial power inverter applications.
NGW75T65H3DF
IGBT with trench construction, fast recovery diode
The NGW75T65H3DF is a robust Insulated-Gate Bipolar Transistor (IGBT) featuring third?-?generation technology. It combines carrier stored trench-gate and field-stop (FS) structures. The NGW75T65H3DF is rated to 175 °C with optimized IGBT turn-off losses. This hard?-?switching 650 V, 75 A IGBT is optimized for high?-?voltage, high?-?frequency industrial power inverter applications.
The NGW75T65H3DF is a robust Insulated-Gate Bipolar Transistor (IGBT) featuring third?-?generation technology. It combines carrier stored trench-gate and field-stop (FS) structures. The NGW75T65H3DF is rated to 175 °C with optimized IGBT turn-off losses. This hard?-?switching 650 V, 75 A IGBT is optimized for high?-?voltage, high?-?frequency industrial power inverter applications.
IGBT with trench construction, fast recovery diode
The NGW75T65H3DF is a robust Insulated-Gate Bipolar Transistor (IGBT) featuring third?-?generation technology. It combines carrier stored trench-gate and field-stop (FS) structures. The NGW75T65H3DF is rated to 175 °C with optimized IGBT turn-off losses. This hard?-?switching 650 V, 75 A IGBT is optimized for high?-?voltage, high?-?frequency industrial power inverter applications.
The NGW75T65H3DF is a robust Insulated-Gate Bipolar Transistor (IGBT) featuring third?-?generation technology. It combines carrier stored trench-gate and field-stop (FS) structures. The NGW75T65H3DF is rated to 175 °C with optimized IGBT turn-off losses. This hard?-?switching 650 V, 75 A IGBT is optimized for high?-?voltage, high?-?frequency industrial power inverter applications.
NGW60T65M3DFP
650 V, 60 A trench field-stop IGBT with full rated silicon diode
The NGW60T65M3DFP is a robust Insulated-Gate Bipolar Transistor (IGBT) featuring third??-??generation technology. It combines carrier stored trench-gate and field-stop (FS) structures. The NGW60T65M3DFP is rated to 175 °C with optimized IGBT turn-off losses, and has a short-circuit withstand time of 5 μs. This hard?-?switching 650 V, 60 A IGBT is optimized for high?-?voltage, high?-?frequency industrial power inverter applications and servo motor drive applications.
The NGW60T65M3DFP is a robust Insulated-Gate Bipolar Transistor (IGBT) featuring third??-??generation technology. It combines carrier stored trench-gate and field-stop (FS) structures. The NGW60T65M3DFP is rated to 175 °C with optimized IGBT turn-off losses, and has a short-circuit withstand time of 5 μs. This hard?-?switching 650 V, 60 A IGBT is optimized for high?-?voltage, high?-?frequency industrial power inverter applications and servo motor drive applications.
650 V, 60 A trench field-stop IGBT with full rated silicon diode
The NGW60T65M3DFP is a robust Insulated-Gate Bipolar Transistor (IGBT) featuring third??-??generation technology. It combines carrier stored trench-gate and field-stop (FS) structures. The NGW60T65M3DFP is rated to 175 °C with optimized IGBT turn-off losses, and has a short-circuit withstand time of 5 μs. This hard?-?switching 650 V, 60 A IGBT is optimized for high?-?voltage, high?-?frequency industrial power inverter applications and servo motor drive applications.
The NGW60T65M3DFP is a robust Insulated-Gate Bipolar Transistor (IGBT) featuring third??-??generation technology. It combines carrier stored trench-gate and field-stop (FS) structures. The NGW60T65M3DFP is rated to 175 °C with optimized IGBT turn-off losses, and has a short-circuit withstand time of 5 μs. This hard?-?switching 650 V, 60 A IGBT is optimized for high?-?voltage, high?-?frequency industrial power inverter applications and servo motor drive applications.
