Computer vision lecture describe about that.pptx
- 1. University Institute of Engineering DEPARTMENT OF COMPUTER SCIENCE & ENGINEERING Bachelor of Engineering (Computer Science & Engineering) Subject Name : Computer Vision Subject Code : CSH-422 Topic : Image Acquisition Lecture – 1.1.4 By- Er. Anju DISCOVER.LEARN.EMPOWER
- 2. Syllabus Introduction to image processing Digital Image Representation Sampling and Quantization Steps in image processing Image acquisition Color Image representation Intensity transform functions Histogram processing Spatial filtering Fourier transforms and its properties Frequency domain filters Hough transformation Image noise and restoration
- 3. Image Sensing and Acquisition Sensing : to grasp or to perceive Acquisition : to obtain or to acquire Image sensing and Acquisition : It means to perceive or grasp the image and obtain it for digital image processing. It is the very first step in digital image processing. Image sensing is done by sensor(also called as transducer), which will convert the optical energy into electrical energy and these electrical signals are converted into digital signals by using digitizer.
- 4. Image Sensing and Acquisition (Cont.) In Image Acquisition there are three components : (a) Illumination (b) Optical system (lens system) (c) Sensor system
- 5. Image Sensing and Acquisition (Cont.) Fig. 1. Image sensing and acquisition
- 6. Image Sensing and Acquisition (Cont.) In fig. 1. you can see that energy is falling on the object and the light is reflected from the object. After that light is falling on the lense (to focus the reflected energy) , this is called the optical system. Lense passes it to image sensor where the image is sensed. Illumination may be either from light source or from a source of electromagnetic energy such as RADAR , infrared or x-ray energy. An image sensor consists of 2D array of cells and each of these cells is denoted as a pixel and is capable of measuring the amount of incident light and convert that into a voltage which in turn converted into a digital number by a digitizer.
- 7. Image Sensing and Acquisition (Cont.) Image sensor is the part of digital camera. So before a camera captures an image , all the cells are emptied meaning that there are no charges present. When the camera captures an image , light is allowed to enter and charges each cell.
- 8. Types of image sensors The three principal sensor arrangements used to transform illumination energy into digital images are: (a) Single sensor (b) Line sensor or sensor strips(line of single sensors) (c) Array sensor(grid of single sensors) The incoming energy is transformed into voltage by the combination of input electrical power and sensor material that is responsible for the particular type of energy being detected. The output voltage waveform is the response of the sensor and digital quantity is obtained from each sensor by digitizing its response.
- 10. Image Acquisition using single sensor Figure shows the components of a single sensor. Perhaps the most familiar sensor of this type is the photodiode, which is constructed of silicon materials and whose output voltage waveform is proportional to light. The use of a filter in front of a sensor improves selectivity. For example, a green (pass) filter in front of a light sensor favors light in the green band of the color spectrum. As a consequence, the sensor output will be stronger for green light than for other components in the visible spectrum. Power in is used to activate sensor. Housing is used to protect sensing material.
- 11. Image Acquisition using single sensor (Cont.)
- 12. Image Acquisition using single sensor (Cont.) In order to generate a 2-D image using a single sensor, there has to be relative displacements in both the x- and y-directions between the sensor and the area to be imaged. Figure shows an arrangement used in high-precision scanning, where a film negative is mounted onto a drum whose mechanical rotation provides displacement in one dimension. The single sensor is mounted on a lead screw that provides motion in the perpendicular direction. Because mechanical motion can be controlled with high precision, this method is an inexpensive (but slow) way to obtain high-resolution images.
- 13. Image Acquisition using single sensor (Cont.) Other similar mechanical arrangements use a flat bed, with the sensor moving in two linear directions. These types of mechanical digitizers sometimes are referred to as microdensitometers. Another example of imaging with a single sensor places a laser source coincident with the sensor. Moving mirrors are used to control the outgoing beam in a scanning pattern and to direct the reflected laser signal onto the sensor. This arrangement can be used also to acquire images using strip and array sensors, which are discussed in the following two sections.
- 14. Image Acquisition using Line sensor (sensor strips) The sensor strip provides imaging in one direction. To gather a complete 2D image , the sensor (or object) must move in a direction perpendicular to the strip. As the sensor moves perpendicular to its strip, it captures successive lines of data. By combining these lines, a full 2D image is formed. Sensor strips mounted in a ring configuration are used in medical and industrial imaging to obtain a cross sectional image of 3D objects. A geometry that is used much more frequently than single sensors consists of an in-line arrangement of sensors in the form of a sensor strip
- 15. Image Acquisition using line sensor (Cont.)
- 16. Image Acquisition using line sensor (Cont.) This is the type of arrangement used in most flat bed scanners. Sensing devices with 4000 or more in-line sensors are possible. In-line sensors are used routinely in airborne imaging applications, in which the imaging system is mounted on an aircraft that flies at a constant altitude and speed over the geographical area to be imaged. One-dimensional imaging sensor strips that respond to various bands of the electromagnetic spectrum are mounted perpendicular to the direction of flight. The imaging strip gives one line of an image at a time, and the motion of the strip completes the other dimension of a two-dimensional image. Lenses or other focusing schemes are used to project the area to be scanned onto the sensors.
- 17. Image Acquisition using Line sensor(Cont.) Sensor strips mounted in a ring configuration are used in medical and industrial imaging to obtain cross-sectional (“slice”) images of 3-D objects, as Fig. shows. A rotating X-ray source provides illumination and the sensors opposite the source collect the X-ray energy that passes through the object (the sensors obviously have to be sensitive to X-ray energy). It is important to note that the output of the sensors must be processed by reconstruction algorithms whose objective is to transform the sensed data into meaningful cross-sectional images. In other words, images are not obtained directly from the sensors by motion alone; they require extensive processing. A 3-D digital volume consisting of stacked images is generated as the object is moved in a direction perpendicular to the sensor ring. Other modalities of imaging based on the CAT principle include magnetic resonance imaging (MRI) and positron emission tomography (PET).The illumination sources, sensors, and types of images are different, but conceptually they are very similar to the basic imaging approach shown in Fig.
- 18. Image Acquisition using Array sensor In this, individual sensors are arranged in the form of a 2-D array. This type of arrangement is found in digital cameras. e.g. CCD array.
- 19. Image Acquisition using array sensor(Cont.) In this, the response of each sensor is proportional to the integral of the light energy projected onto the surface of the sensor. Noise reduction is achieved by letting the sensor integrate the input light signal over minutes or ever hours. Advantage: Since sensor array is 2D, a complete image can be obtained by focusing the energy pattern onto the surface of the array. The sensor array is coincident with the focal plane, it produces an output proportional to the integral of light received at each sensor. Digital and analog circuitry sweep these outputs and convert them to a video signal which is then digitized by another section of the imaging system. The output is a digital image.