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The process of converting analogue signals from an imaging sensor, such as a camera or scanner, into digital form is known as imaging A/D (Analog-to-Digital) conversion.
It is frequently used in a variety of imaging applications, including digital cameras, medical imaging equipment, industrial inspection systems, and more. It was created expressly for processing image data.
An image A/D converter’s main job is to periodically sample the continuous analogue signal coming from the imaging sensor and turn it into discrete digital values. This procedure is required because image sensors record continuous fluctuations of light or other physical phenomena whereas digital computers work with discrete binary data.
Wideband radio frequency, intermediate frequency signal processing, and general-purpose baseband classes are all examples of high-speed DA converters (DACs). These DACs are appropriate for instrumentation, radar, electronic warfare, wired and wireless communications, and other applications.
High-speed DA converters from Analogue Devices have resolutions that range from 8 bits to 16 bits and range in speed from 30 MSPS to multi-GSPS. These converters are suggested for use with ADI’s clocking, timing, RF, and power control devices.
The Global Imaging A/D Converter market accounted for $XX Billion in 2023 and is anticipated to reach $XX Billion by 2030, registering a CAGR of XX% from 2024 to 2030.
The ADAS1131 module embeds 256 low-power, low-noise, low-input-current integrators, simultaneous sample-and-hold circuitry, two high-speed A/D converters with programmable sampling rates, and all associated internal buffers, decoupling and by-pass capacitors for data acquisition, further reducing component count and streamlining board layout.
The new converter uses the same amount of power (3 mW) per channel at any throughput as rival devices that only incorporate 128 channels.
