Does this come under electrical engineering ?DaveE said:I guess from your title you are asking about the ADC part of the signal processing. There are several different types of ADCs and I'm not sure all cameras use the same type. I would guess SAR and Σ-Δ are the most common for still pictures. Here's one of about a million articles about ADCs on the web.
https://www.analog.com/en/analog-dialogue/articles/the-right-adc-architecture.html
Yes. Analog EE, really.rudransh verma said:Does this come under electrical engineering ?
There is a lot of information out there about this. The link I gave may be a bit too advanced initially. But I'm sure there are others that start more slowly. Search the web for ADCs and you'll find the appropriate level for your knowledge and interest. However, one problem is that there are some quite different solutions to this. You may not care enough to study all of the different versions, since they all do the same job at the basic level.rudransh verma said:I read it and it Looks difficult to understand completely. I found about it in “How computer works” book and was curious to understand it. But I think I have to go back a bit and first understand the basics.
It's 'painting by numbers'. Each element on the sensor (pixel) is a 'sample' of the image of the scene that's on the sensor array. (Those are 'samples') The Analogue values of the light signal on the sensors are changed (quantised) into digital numbers and all those millions of numbers are fed to (mapped into) the camera memory memory.rudransh verma said:So how is light ultimately get transformed into a beautiful picture on screen in a digital camera?
An analog to digital signal converter in digital cameras works by converting the continuous analog signals captured by the camera's image sensor into discrete digital values. This conversion process allows the camera to capture, process, and store images in a digital format.
The analog to digital signal converter is crucial in digital cameras as it enables the camera to accurately capture and reproduce images in a digital format. Without this converter, the camera would not be able to process and store images in a way that can be easily viewed, edited, and shared digitally.
The resolution of an analog to digital signal converter in a digital camera determines the level of detail and clarity in the captured images. A higher resolution converter can capture more data points, resulting in sharper images with more vibrant colors and finer details. Conversely, a lower resolution converter may produce images with less detail and clarity.
Yes, the analog to digital signal converter in digital cameras can be upgraded or improved to enhance image quality and performance. Camera manufacturers often introduce advancements in converter technology to produce better image quality, faster processing speeds, and improved low-light performance in their cameras.
While analog to digital signal converters in digital cameras have significantly improved over the years, there are still limitations to consider. Factors such as dynamic range, noise levels, and processing speed can impact the overall performance and image quality of the converter. Manufacturers continue to work on overcoming these limitations to provide users with the best possible image quality.