11-Channel Spectral Sensor Frontend The AS7341-DLGM is a multi-channel spectral sensor developed by ams OSRAM, designed for advanced color measurement, spectral analysis, and ambient light sensing applications. The device integrates multiple optical channels covering visible and near-infrared wavelengths, enabling precise detection of light characteristics across a broad spectrum. Its compact surface-mount package, integrated analog front-end, and digital processing capabilities make it suitable for consumer electronics, industrial instrumentation, smart lighting systems, display calibration, agricultural sensing, and portable analytical devices. The sensor features highly sensitive photodiodes combined with optical filters that allow accurate spectral discrimination. Communication is performed through a standard digital interface, facilitating integration with microcontrollers, embedded systems, and IoT platforms. The AS7341 supports configurable measurement modes, programmable gain control, and interrupt functions for efficient system-level implementation. Key Features Multi-channel spectral sensing architecture Visible and near-infrared light detection capability Integrated optical interference filters High-sensitivity photodiode array Ambient light sensing functionality Advanced color measurement and analysis Programmable gain and integration settings Digital output with I²C communication interface Low-power operating characteristics Integrated interrupt and event detection functions Compact surface-mount package Suitable for portable and battery-powered designs High accuracy across varying lighting conditions Supports spectral identification and classification applications Optimized for display, lighting, and environmental monitoring systems Applications Color measurement instruments Spectral analysis equipment Smart lighting control systems Display color calibration Industrial automation sensors Agricultural monitoring devices Ambient light sensing applications Consumer electronics Wearable devices IoT sensing platforms Scientific and laboratory instruments Optical monitoring systems Electrical and Functional Characteristics Multi-channel optical sensing engine Digital signal processing architecture Configurable integration timing Adjustable sensitivity and gain control Low-noise measurement performance High dynamic range operation Fast measurement response capability Integrated spectral filtering technology Embedded register-based configuration Interrupt-driven event monitoring support Mechanical Characteristics Compact surface-mount package PCB-friendly footprint RoHS-compliant construction Suitable for automated assembly processes Optimized optical window design #commonpartslibrary #sensor #opticalsensor #spectralsensor #colorsensor #ambientlightsensor #amsosram #embeddedsystems #industrialelectronics #iot #measurement #environmentalsensing #consumerelectronics #smartlighting #electronicsdesign

The ams OSRAM TCS3448 is a highly versatile, multi-purpose spectral light sensor designed to sense the spectral components of ambient light in the visible range. This 14-channel sensor is optimized for applications requiring precise color sensing and ambient light classification, making it ideal for enhancing camera performance through improved color temperature (CCT), automatic white balance (AWB), and exposure time adjustments. The TCS3448 features individual channels covering approximately 380 nm to 1000 nm, including 11 channels centered in the visible spectrum, one near-infrared (NIR) channel, and a clear channel. Additionally, it integrates a flicker detection channel that can automatically flag ambient light flicker at 50/60 Hz and buffer data for calculating other flicker frequencies. The sensor's high-precision optical interference filters are directly deposited on photodiodes embedded in CMOS silicon, ensuring accurate spectral data. With a built-in aperture, programmable digital GPIO, and LED driver, the TCS3448 offers robust control and synchronization capabilities. The device is available in an ultra-low profile package, making it suitable for a wide range of applications, from industrial automation to mobile and wearable devices. Features: 14-channel spectral sensing Visible range coverage (380 nm to 1000 nm) 11 visible spectrum channels Near-infrared (NIR) channel Clear channel Flicker detection up to 1 kHz Integrated aperture for increased accuracy High-precision optical interference filters Programmable digital GPIO LED driver for light source control Serial I²C interface (1.2 V/1.8 V) Ultra-low profile package (3.1 mm x 2 mm x 1 mm) Field of view (FOV) ±40° 0.18 µ process technology Compatible with AS7343 software #CommonPartsLibrary #IntegratedCircuit #Sensor #Transducers #Optical-Sensor #Ambient-Light #IR #UV-Sensor

N-Channel 650 V 37A (Tc) 150W (Tc) Through Hole TO-247-3 This specification defines the requirements, structure, and intended use associated with the identifier C3M0060065D. It serves as a unique reference within an engineering system, enabling traceability, configuration control, and consistent identification across design, manufacturing, and operational contexts. The specification ensures that all stakeholders interpret the identifier uniformly and apply it correctly within technical documentation, system integration, and lifecycle management processes. Scope This document applies to all engineering activities where the identifier C3M0060065D is referenced, including design validation, component tracking, documentation control, and system integration. Requirements The identifier shall be used consistently across all engineering documents and systems. The identifier shall remain immutable once assigned. All associated components, assemblies, or records shall reference this identifier without alteration. Any updates related to the item represented by this identifier shall be documented while preserving the original reference. Configuration and Control The identifier shall be maintained under strict configuration management procedures. Changes to associated data shall be reviewed and approved according to established engineering change processes. Versioning and revision tracking shall be implemented where applicable, without modifying the base identifier. Usage Guidelines The identifier shall be clearly visible in all relevant documentation and system records. It shall be used as the primary reference for cross-functional coordination, including design, manufacturing, and quality assurance. Misuse or duplication of the identifier shall be prevented through validation mechanisms. Compliance All implementations referencing this identifier shall adhere to internal engineering standards and applicable regulatory requirements. #Commonpartslibrary #Transistor #MOSFET #FET #tht #C3M0075120