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PT100MC0MP Phototransistor Feature, Application, and Datasheets
PT100MC0MP Phototransistor Feature, Application, and Datasheets
Optical crystals, laser crystals, nonlinear optical crystals, electro-optical crystals, piezoelectric crystals, scintillation crystals, and magneto-optical crystals are all examples of photoelectric functional crystals. Its job is to take in optical impulses and convert them to electrical ones.

Optical crystals, laser crystals, nonlinear optical crystals, electro-optical crystals, piezoelectric crystals, scintillation crystals, and magneto-optical crystals are all examples of photoelectric functional crystals. Its job is to take in optical impulses and convert them to electrical ones.

Features

  • Peak sensitivity wavelength: 910 nm TYP.

  • Narrow directivity angle (Δθ: ±15° TYP.) 

  • Lead-free and RoHS directive compliant

  • Compact and thin SMD package

  • Top view and side view mountable

 

 

Applications

  • Telecommunication equipment

  • Measuring equipment

  • Tooling machines/Factory automation

  • Touch Panels

 

 

Specification

 

Technical

  • Operating Temperature-30°C~85°C TA

  • Part StatusObsolete

  • Moisture Sensitivity Level (MSL)3 (168 Hours)

  • Max Power Dissipation75mW

  • PolarityNPN

  • ConfigurationSINGLE

  • Power Dissipation75mW

  • Output Current20mA

  • Viewing Angle30°

  • Rise Time5μs

  • Fall Time (Typ)6 μs

  • Collector-Emitter Voltage (VCEO)6V

  • Max Collector Current20mA

  • Wavelength - Peak900 nm

  • Collector-Emitter Breakdown Voltage35V

  • Power Consumption75mW

  • Collector-Emitter Saturation Voltage400mV

  • Max Breakdown Voltage35V

  • Dark Current100nA

  • Light Current-Nom2.9mA

Construction

How to Use

A voltage is provided to the two terminals of the emitter and collector to impart a reverse bias voltage to the collector junction, and the phototransistor is commonly employed in an open base condition (there are two external wires in many situations). A photocurrent (I) flows between the reversely biased base and the collector when light is incident on the surface of the base in this state, and the same is true for the transistor whose emitter is grounded. The photocurrent (Ic) flowing to the external terminal is amplified, and the current amplification rate of the current traveling through the transistor of the second stage is amplified. As a result, the first stage is the photocurrent flowing to the external wire. In the first and final stages, the product of the photocurrent flows between the base and the collector and the current amplification rate of the transistors.