Surface Mount Schottky Rectifier

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Dual-In-Line Package Intelligent Power Module

TRANSFER-MOLD TYPE INSULATED TYPE INTEGRATED POWER FUNCTIONS 1200V/5A low-loss 4th generation IGBT inverter bridge for 3 phase DC-to-AC power conversion INTEGRATED DRIVE, PROTECTION AND SYSTEM CONTROL FUNCTIONS • For upper-leg IGBTS :Drive circuit, High voltage high-speed level shifting, Co

Intellimod??Module Dual-In-Line Intelligent Power Module 10 Amperes/1200 Volts

Description: DIP-IPMs are intelligent power modules that integrate power devices, drivers, and protection circuitry in an ultra compact dual-in-line transfer-mold package for use in driving small three phase motors. Use of 4th generation IGBTs, DIP packaging, and application specific HVICs allow

1200V/10A low-loss 4th generation IGBT inverter bridge for 3 phase DC-to-AC power conversion

INTEGRATED POWER FUNCTIONS 1200V/10A low-loss 4th generation IGBT inverter bridge for 3 phase DC-to-AC power conversion INTEGRATED DRIVE, PROTECTION AND SYSTEM CONTROL FUNCTIONS • For upper-leg IGBTS :Drive circuit, High voltage high-speed level shifting, Control supply under-voltage (UV) pr

1200V/15A low-loss 4th generation IGBT inverter bridge for 3 phase DC-to-AC power conversion

MITSUBISHI SEMICONDUCTOR INTEGRATED POWER FUNCTIONS 1200V/15A low-loss 4th generation IGBT inverter bridge for 3 phase DC-to-AC power conversion INTEGRATED DRIVE, PROTECTION AND SYSTEM CONTROL FUNCTIONS • For upper-leg IGBTS :Drive circuit, High voltage high-speed level shifting, Control

1200V/25A low-loss 4th generation IGBT inverter bridge

INTEGRATED POWER FUNCTIONS 1200V/25A low-loss 4th generation IGBT inverter bridge for 3 phase DC-to-AC power conversion INTEGRATED DRIVE, PROTECTION AND SYSTEM CONTROL FUNCTIONS • For upper-leg IGBTS :Drive circuit, High voltage high-speed level shifting, Control supply under-voltage (UV) prote

Phison Electronics Corporation USB 2.0 Flash Controller Specification

Controller Features ² Support Host Interfaces : USB 2.0 & 1.1 Interface — Fully compatible with USB Specification Version 2.0 & 1.1 — High speed 480Mbit/second supporting — Full speed 12Mbit/second supporting — Support one CONTROL transfer, one INTERRUPT transfer and two BULK transfer — Supp

Phison Electronics Corporation USB 2.0 Flash Controller Specification

Controller Features ² Support Host Interfaces : USB 2.0 & 1.1 Interface — Fully compatible with USB Specification Version 2.0 & 1.1 — High speed 480Mbit/second supporting — Full speed 12Mbit/second supporting — Support one CONTROL transfer, one INTERRUPT transfer and two BULK transfer — Supp

Useful of 4,000 hours at 85°C

Features • Higher ripple though use of low-ESR material consequently, the permissible ripple current is improved by 27% in the windless status or 40% in the ventilated condition (0.5m/s) as compared with conventional constructions (HP3 series). • Improvement in air exhaust (flow hole p

Useful of 4,000 hours at 85°C

Features • Higher ripple though use of low-ESR material consequently, the permissible ripple current is improved by 27% in the windless status or 40% in the ventilated condition (0.5m/s) as compared with conventional constructions (HP3 series). • Improvement in air exhaust (flow hole p

Useful of 4,000 hours at 85°C

Features • Higher ripple though use of low-ESR material consequently, the permissible ripple current is improved by 27% in the windless status or 40% in the ventilated condition (0.5m/s) as compared with conventional constructions (HP3 series). • Improvement in air exhaust (flow hole p

Useful of 4,000 hours at 85°C

Features • Higher ripple though use of low-ESR material consequently, the permissible ripple current is improved by 27% in the windless status or 40% in the ventilated condition (0.5m/s) as compared with conventional constructions (HP3 series). • Improvement in air exhaust (flow hole p

Useful of 4,000 hours at 85°C

Features • Higher ripple though use of low-ESR material consequently, the permissible ripple current is improved by 27% in the windless status or 40% in the ventilated condition (0.5m/s) as compared with conventional constructions (HP3 series). • Improvement in air exhaust (flow hole p

Useful of 4,000 hours at 85°C

Features • Higher ripple though use of low-ESR material consequently, the permissible ripple current is improved by 27% in the windless status or 40% in the ventilated condition (0.5m/s) as compared with conventional constructions (HP3 series). • Improvement in air exhaust (flow hole p

Useful of 4,000 hours at 85°C

Features • Higher ripple though use of low-ESR material consequently, the permissible ripple current is improved by 27% in the windless status or 40% in the ventilated condition (0.5m/s) as compared with conventional constructions (HP3 series). • Improvement in air exhaust (flow hole p

Useful of 4,000 hours at 85°C

Features • Higher ripple though use of low-ESR material consequently, the permissible ripple current is improved by 27% in the windless status or 40% in the ventilated condition (0.5m/s) as compared with conventional constructions (HP3 series). • Improvement in air exhaust (flow hole p

Useful of 4,000 hours at 85°C

Features • Higher ripple though use of low-ESR material consequently, the permissible ripple current is improved by 27% in the windless status or 40% in the ventilated condition (0.5m/s) as compared with conventional constructions (HP3 series). • Improvement in air exhaust (flow hole p

Useful of 4,000 hours at 85°C

Features • Higher ripple though use of low-ESR material consequently, the permissible ripple current is improved by 27% in the windless status or 40% in the ventilated condition (0.5m/s) as compared with conventional constructions (HP3 series). • Improvement in air exhaust (flow hole p

Useful of 4,000 hours at 85°C

Features • Higher ripple though use of low-ESR material consequently, the permissible ripple current is improved by 27% in the windless status or 40% in the ventilated condition (0.5m/s) as compared with conventional constructions (HP3 series). • Improvement in air exhaust (flow hole p

Useful of 4,000 hours at 85°C

Features • Higher ripple though use of low-ESR material consequently, the permissible ripple current is improved by 27% in the windless status or 40% in the ventilated condition (0.5m/s) as compared with conventional constructions (HP3 series). • Improvement in air exhaust (flow hole p

Useful of 4,000 hours at 85°C

Features • Higher ripple though use of low-ESR material consequently, the permissible ripple current is improved by 27% in the windless status or 40% in the ventilated condition (0.5m/s) as compared with conventional constructions (HP3 series). • Improvement in air exhaust (flow hole p

Useful of 4,000 hours at 85°C

Features • Higher ripple though use of low-ESR material consequently, the permissible ripple current is improved by 27% in the windless status or 40% in the ventilated condition (0.5m/s) as compared with conventional constructions (HP3 series). • Improvement in air exhaust (flow hole p

Useful of 4,000 hours at 85°C

Features • Higher ripple though use of low-ESR material consequently, the permissible ripple current is improved by 27% in the windless status or 40% in the ventilated condition (0.5m/s) as compared with conventional constructions (HP3 series). • Improvement in air exhaust (flow hole p

Useful of 4,000 hours at 85°C

Features • Higher ripple though use of low-ESR material consequently, the permissible ripple current is improved by 27% in the windless status or 40% in the ventilated condition (0.5m/s) as compared with conventional constructions (HP3 series). • Improvement in air exhaust (flow hole p

Useful of 4,000 hours at 85°C

Features • Higher ripple though use of low-ESR material consequently, the permissible ripple current is improved by 27% in the windless status or 40% in the ventilated condition (0.5m/s) as compared with conventional constructions (HP3 series). • Improvement in air exhaust (flow hole p

Useful of 4,000 hours at 85°C

Features • Higher ripple though use of low-ESR material consequently, the permissible ripple current is improved by 27% in the windless status or 40% in the ventilated condition (0.5m/s) as compared with conventional constructions (HP3 series). • Improvement in air exhaust (flow hole p

Useful of 4,000 hours at 85°C

Features • Higher ripple though use of low-ESR material consequently, the permissible ripple current is improved by 27% in the windless status or 40% in the ventilated condition (0.5m/s) as compared with conventional constructions (HP3 series). • Improvement in air exhaust (flow hole p

Useful of 4,000 hours at 85°C

Features • Higher ripple though use of low-ESR material consequently, the permissible ripple current is improved by 27% in the windless status or 40% in the ventilated condition (0.5m/s) as compared with conventional constructions (HP3 series). • Improvement in air exhaust (flow hole p

Useful of 4,000 hours at 85°C

Features • Higher ripple though use of low-ESR material consequently, the permissible ripple current is improved by 27% in the windless status or 40% in the ventilated condition (0.5m/s) as compared with conventional constructions (HP3 series). • Improvement in air exhaust (flow hole p

Useful of 4,000 hours at 85°C

Features • Higher ripple though use of low-ESR material consequently, the permissible ripple current is improved by 27% in the windless status or 40% in the ventilated condition (0.5m/s) as compared with conventional constructions (HP3 series). • Improvement in air exhaust (flow hole p

Useful of 4,000 hours at 85°C

Features • Higher ripple though use of low-ESR material consequently, the permissible ripple current is improved by 27% in the windless status or 40% in the ventilated condition (0.5m/s) as compared with conventional constructions (HP3 series). • Improvement in air exhaust (flow hole p

Useful of 4,000 hours at 85°C

Features • Higher ripple though use of low-ESR material consequently, the permissible ripple current is improved by 27% in the windless status or 40% in the ventilated condition (0.5m/s) as compared with conventional constructions (HP3 series). • Improvement in air exhaust (flow hole p

Useful of 4,000 hours at 85°C

Features • Higher ripple though use of low-ESR material consequently, the permissible ripple current is improved by 27% in the windless status or 40% in the ventilated condition (0.5m/s) as compared with conventional constructions (HP3 series). • Improvement in air exhaust (flow hole p

Useful of 4,000 hours at 85°C

Features • Higher ripple though use of low-ESR material consequently, the permissible ripple current is improved by 27% in the windless status or 40% in the ventilated condition (0.5m/s) as compared with conventional constructions (HP3 series). • Improvement in air exhaust (flow hole p

Useful of 4,000 hours at 85°C

Features • Higher ripple though use of low-ESR material consequently, the permissible ripple current is improved by 27% in the windless status or 40% in the ventilated condition (0.5m/s) as compared with conventional constructions (HP3 series). • Improvement in air exhaust (flow hole p

Useful of 4,000 hours at 85°C

Features • Higher ripple though use of low-ESR material consequently, the permissible ripple current is improved by 27% in the windless status or 40% in the ventilated condition (0.5m/s) as compared with conventional constructions (HP3 series). • Improvement in air exhaust (flow hole p

Useful of 4,000 hours at 85°C

Features • Higher ripple though use of low-ESR material consequently, the permissible ripple current is improved by 27% in the windless status or 40% in the ventilated condition (0.5m/s) as compared with conventional constructions (HP3 series). • Improvement in air exhaust (flow hole p

Useful of 4,000 hours at 85°C

Features • Higher ripple though use of low-ESR material consequently, the permissible ripple current is improved by 27% in the windless status or 40% in the ventilated condition (0.5m/s) as compared with conventional constructions (HP3 series). • Improvement in air exhaust (flow hole p

Useful of 4,000 hours at 85°C

Features • Higher ripple though use of low-ESR material consequently, the permissible ripple current is improved by 27% in the windless status or 40% in the ventilated condition (0.5m/s) as compared with conventional constructions (HP3 series). • Improvement in air exhaust (flow hole p

Useful of 4,000 hours at 85°C

Features • Higher ripple though use of low-ESR material consequently, the permissible ripple current is improved by 27% in the windless status or 40% in the ventilated condition (0.5m/s) as compared with conventional constructions (HP3 series). • Improvement in air exhaust (flow hole p

Useful of 4,000 hours at 85°C

Features • Higher ripple though use of low-ESR material consequently, the permissible ripple current is improved by 27% in the windless status or 40% in the ventilated condition (0.5m/s) as compared with conventional constructions (HP3 series). • Improvement in air exhaust (flow hole p

Useful of 4,000 hours at 85°C

Features • Higher ripple though use of low-ESR material consequently, the permissible ripple current is improved by 27% in the windless status or 40% in the ventilated condition (0.5m/s) as compared with conventional constructions (HP3 series). • Improvement in air exhaust (flow hole p

Useful of 4,000 hours at 85°C

Features • Higher ripple though use of low-ESR material consequently, the permissible ripple current is improved by 27% in the windless status or 40% in the ventilated condition (0.5m/s) as compared with conventional constructions (HP3 series). • Improvement in air exhaust (flow hole p

Useful of 4,000 hours at 85°C

Features • Higher ripple though use of low-ESR material consequently, the permissible ripple current is improved by 27% in the windless status or 40% in the ventilated condition (0.5m/s) as compared with conventional constructions (HP3 series). • Improvement in air exhaust (flow hole p

Useful of 4,000 hours at 85°C

Features • Higher ripple though use of low-ESR material consequently, the permissible ripple current is improved by 27% in the windless status or 40% in the ventilated condition (0.5m/s) as compared with conventional constructions (HP3 series). • Improvement in air exhaust (flow hole p

Useful of 4,000 hours at 85°C

Features • Higher ripple though use of low-ESR material consequently, the permissible ripple current is improved by 27% in the windless status or 40% in the ventilated condition (0.5m/s) as compared with conventional constructions (HP3 series). • Improvement in air exhaust (flow hole p

Useful of 4,000 hours at 85°C

Features • Higher ripple though use of low-ESR material consequently, the permissible ripple current is improved by 27% in the windless status or 40% in the ventilated condition (0.5m/s) as compared with conventional constructions (HP3 series). • Improvement in air exhaust (flow hole p

Useful of 4,000 hours at 85°C

Features • Higher ripple though use of low-ESR material consequently, the permissible ripple current is improved by 27% in the windless status or 40% in the ventilated condition (0.5m/s) as compared with conventional constructions (HP3 series). • Improvement in air exhaust (flow hole p

Useful of 4,000 hours at 85°C

Features • Higher ripple though use of low-ESR material consequently, the permissible ripple current is improved by 27% in the windless status or 40% in the ventilated condition (0.5m/s) as compared with conventional constructions (HP3 series). • Improvement in air exhaust (flow hole p

Useful of 4,000 hours at 85°C

Features • Higher ripple though use of low-ESR material consequently, the permissible ripple current is improved by 27% in the windless status or 40% in the ventilated condition (0.5m/s) as compared with conventional constructions (HP3 series). • Improvement in air exhaust (flow hole p

Useful of 4,000 hours at 85°C

Features • Higher ripple though use of low-ESR material consequently, the permissible ripple current is improved by 27% in the windless status or 40% in the ventilated condition (0.5m/s) as compared with conventional constructions (HP3 series). • Improvement in air exhaust (flow hole p

Useful of 4,000 hours at 85°C

Features • Higher ripple though use of low-ESR material consequently, the permissible ripple current is improved by 27% in the windless status or 40% in the ventilated condition (0.5m/s) as compared with conventional constructions (HP3 series). • Improvement in air exhaust (flow hole p

Useful of 4,000 hours at 85°C

Features • Higher ripple though use of low-ESR material consequently, the permissible ripple current is improved by 27% in the windless status or 40% in the ventilated condition (0.5m/s) as compared with conventional constructions (HP3 series). • Improvement in air exhaust (flow hole p

Useful of 4,000 hours at 85°C

Features • Higher ripple though use of low-ESR material consequently, the permissible ripple current is improved by 27% in the windless status or 40% in the ventilated condition (0.5m/s) as compared with conventional constructions (HP3 series). • Improvement in air exhaust (flow hole p

Useful of 4,000 hours at 85°C

Features • Higher ripple though use of low-ESR material consequently, the permissible ripple current is improved by 27% in the windless status or 40% in the ventilated condition (0.5m/s) as compared with conventional constructions (HP3 series). • Improvement in air exhaust (flow hole p

Useful of 4,000 hours at 85°C

Features • Higher ripple though use of low-ESR material consequently, the permissible ripple current is improved by 27% in the windless status or 40% in the ventilated condition (0.5m/s) as compared with conventional constructions (HP3 series). • Improvement in air exhaust (flow hole p

Useful of 4,000 hours at 85°C

Features • Higher ripple though use of low-ESR material consequently, the permissible ripple current is improved by 27% in the windless status or 40% in the ventilated condition (0.5m/s) as compared with conventional constructions (HP3 series). • Improvement in air exhaust (flow hole p

Useful of 4,000 hours at 85°C

Features • Higher ripple though use of low-ESR material consequently, the permissible ripple current is improved by 27% in the windless status or 40% in the ventilated condition (0.5m/s) as compared with conventional constructions (HP3 series). • Improvement in air exhaust (flow hole p

Useful of 4,000 hours at 85°C

Features • Higher ripple though use of low-ESR material consequently, the permissible ripple current is improved by 27% in the windless status or 40% in the ventilated condition (0.5m/s) as compared with conventional constructions (HP3 series). • Improvement in air exhaust (flow hole p

Useful of 4,000 hours at 85°C

Features • Higher ripple though use of low-ESR material consequently, the permissible ripple current is improved by 27% in the windless status or 40% in the ventilated condition (0.5m/s) as compared with conventional constructions (HP3 series). • Improvement in air exhaust (flow hole p