Product Overview: NOIP1SE1300A-QTI Image Sensor

The NOIP1SE1300A-QTI is a high-performance CMOS image sensor from ON Semiconductor, designed to deliver exceptional image quality with its 1.3-megapixel resolution. This sensor is engineered to cater to a broad range of industrial and commercial applications where image clarity and accuracy are paramount.

Key Features

• High Resolution: With a native resolution of 1280 x 1024 pixels, this sensor captures images with exquisite detail, making it ideal for precise imaging requirements.
• Pixel Size: The 9.9 µm x 9.9 µm pixel size ensures high sensitivity and low noise, providing excellent image quality even in low-light conditions.
• Frame Rate: The NOIP1SE1300A-QTI supports a maximum frame rate of 30 frames per second (fps) at full resolution, which is suitable for capturing fast-moving objects without motion blur.
• Dynamic Range: It offers a wide dynamic range that ensures clear images in scenes with varying levels of brightness.
• Shutter Type: The sensor features a global shutter, which captures the entire image simultaneously, eliminating the distortion typically seen with rolling shutters in fast-moving scenes.
• Interface: The sensor is equipped with a simple, yet robust, digital interface for easy integration into a variety of systems.
• Operating Temperature: It operates within a temperature range of -40°C to +85°C, making it reliable in extreme environmental conditions.

Applications

The versatility of the NOIP1SE1300A-QTI allows it to be used in a wide array of applications, including but not limited to:

• Machine vision and factory automation
• Medical imaging and diagnostics
• Security and surveillance systems
• Intelligent transportation systems (ITS)
• Agricultural and environmental monitoring

Summary

The NOIP1SE1300A-QTI from ON Semiconductor is a robust and reliable image sensor that provides superior image quality, flexibility, and performance for a multitude of imaging applications. Its advanced features ensure that it can meet the needs of even the most demanding imaging tasks.