MT9V135L12STCES Micron Technology Inc, MT9V135L12STCES Datasheet - Page 12

MT9V135L12STCES

Manufacturer Part Number

MT9V135L12STCES

Description

Manufacturer

Micron Technology Inc

Datasheet

1.MT9V135L12STCES.pdf (17 pages)

Specifications of MT9V135L12STCES

Lead Free Status / RoHS Status

Compliant

Current page: 12 of 17
Download datasheet (573Kb)

Image Flow Processor

Black Level Conditioning

Digital Gain

Test Pattern

Lens Shading Correction

Interpolation and Aperture Correction

PDF: 09005aef82c99cd/Source:09005aef824c99db

MT9V135_LDS_2.fm - Rev. B 3/07 EN

The MT9V135 IFP consists of a color processing pipeline, and a measurement and

control logic block (the camera controller). The stream of raw data from the sensor

enters the pipeline and undergoes several transformations. Image stream processing

starts with conditioning the black level and applying a digital gain. The lens shading

block compensates for signal loss caused by the lens.

Next, the data is interpolated to recover missing color components for each pixel. The

resulting interpolated RGB data passes through the current color correction matrix

(CCM), gamma, and saturation corrections, and is formatted for final output.

The measurement and control logic continuously accumulate image brightness and

color statistics. Based on these measurements, the IFP calculates updated values for

exposure time and sensor analog gains that are sent to the sensor core through the

control bus.

The sensor core black level calibration works to maintain black pixel values at a constant

level, independent of analog gain, reference current, voltage settings, and temperature

conditions. If this black level is above zero, it must be reduced before color processing

can begin. The black level subtraction block in the IFP re-maps the black level of the

sensor to zero prior to lens shading correction. Following lens shading correction, the

black level addition block provides capability for another black level adjustment.

However, for good contrast, this level should be set to zero.

Controlled by auto exposure logic, the input digital gain stage amplifies the raw image in

low-light conditions. (Range: x1–x8).

A built-in test pattern generator produces a test image stream that can be multiplexed

with the gain stage. The test pattern can be selected through register settings.

Inexpensive lenses tend to attenuate image intensity near the edges of pixel arrays.

Other factors also cause signal and coloration differences across the image. The net

result of all these factors is known as lens shading. Lens shading correction (LC)

compensates for these differences.

Typically, the profile of lens shading induced anomalies across the frame is different for

each color component. Lens shading correction is independently calibrated for the color

channels.

A demosaic engine converts the single color per pixel Bayer data from the sensor into

RGB (10-bit per color channel). The demosaic algorithm analyzes neighboring pixels to

generate a best guess for the missing color components. Edge sharpness is preserved as

much as possible.

Aperture correction sharpens the image by an adjustable amount. Sharpening can be

programmed to phase out as light levels drop to avoid amplifying noise.

MT9V135: SOC VGA Digital Image Sensor

Micron Technology, Inc., reserves the right to change products or specifications without notice.

Detailed Architecture Overview

Preliminary

MT9V135L12STCES Micron Technology Inc, MT9V135L12STCES Datasheet - Page 12

MT9V135L12STCES

Specifications of MT9V135L12STCES

Related parts for MT9V135L12STCES