SU966710A1 - Device for reading-out and selecting object images - Google Patents

Description

(5) DEVICE FOR READING AND SELECTION OF IMAGES OF OBJECTS

. 1 - The invention relates to automation and computational techniques, in particular, devices for reading and selecting images of objects, and can be used. For counting and sampling, successively arranged images, one scan line is enough to recognize which one-to-one is unambiguous.

A device for reading and selection of images of objects, containing a photosensitive sensor; connected to a video amplifier and through a single-input driver of the shift register, a figure beginning selection unit connected to the shift registers and with a counter, a figure number input unit, a control unit and logic; 1: 1 elements.

The disadvantage of this device is its low accuracy. The closest technical solution to the present invention is a device comprising a television sensor connected to a control unit connected to the AND element, and to a video amplifier connected to the image edge selection unit, the outputs of which are connected to the imagers named after it. pulses connected to the reversible counter, memory block and logic elements.

10 A disadvantage of the prior art is also insufficient accuracy.

 The purpose of the invention is to increase the point; device.

15 The goal is achieved by the fact that in a known device comprising a control unit connected to

output of the element And with the input of the photo sensor, the output of which is connected to

20, a video amplifier, an image edge selection unit connected to the video amplifier and to the first and second pulse conditioners, the outputs of which are connected to a reversible counter, and a memory unit, are entered into a comparison unit whose inputs are connected to a reversible counter and memory unit, and the output connected to one input element And, the other input of which is connected to the output of the second pulse generator. The drawing shows the block diagram of the device. It includes a photo sensor 1, a video amplifier 2, an image edge selection unit 3, a first pulse shaper 4, a reversible counter 5, a comparison unit 6, a memory block 7, an And element 8, a second pulse shaper 9, and a control unit 10. The device works as follows. The photosensor 1 scans the media in a sequential series of individual images deposited on it of a simple configuration, for which a single scanning line is sufficient to uniquely identify. The continuous signal from the photo sensor 1, which has converted the reflected beam, is amplified in video amplifier 2 and enters block 3, which is sensitive to image sections, since the values of optical density in the images and in the intervals between them are significantly different. In block 3 with. The binary scan of the input signal occurs, and as a result, a binary signal is generated at its output in such a way that its high level corresponds to the location of the photosensor 1 in the image area, and a low one in the section area. The digital signal from block 3 is supplied to two drivers, and driver 9 processes the leading edges of the signal from block 3, and driver k generates short pulses from the decay of this signal. The pulses of the imaging unit 4 are fed to the summing input of the reversible counter 5, while the pulses of the imaging unit 9 arrive at its subtracting input; so, depending on the control potential of the block 6, the counter 5 can either increase or decrease its content. Consider the operation of the device in more detail. In the initial state, the photosensor 1 is out of the image array and the counter 5 is set to zero by a clock pulse (for simplicity of the circuit, the zero setting circuit is not shown). In block 7, the number of the desired image is entered, the code of which is transmitted to the second input of the comparison block 6, and the code of the counter 5 is fed to its first input. After analyzing the codes received by block 6, the latter generates inequality signals, which, without passing through element 8, the control unit 10 is converted into commands for moving the photosensor 1 in one of the two scanning directions. So, if the number of the image entered in block 7 exceeds the current code of the counter 5, then the images are scanned in the direction which is conventionally called direct. In this case, the control potential of the unit 6 commutes the input circuits of the counter 5 and the counting pulses are received only by summing its input from the driver k. As a result, the contents of the counter increase. If the number of the specified image is less than the contents of counter 5, then in the same way scanning is performed in the opposite direction, and estimated pulses pass only to the subtractive input from the imaging unit 9. Thus, an unambiguous correspondence of the counter code to the number of scanned images is achieved and the scanner moves to the required zone. With further movement of the photo sensor in the direction of the specified image, there comes a moment when the binary codes of the counter 5 and block 7 are jointly. fall, which is the fact that the scanning beam has reached the boundary of the information sampling zone. At this time, unit 6 generates an equality signal, which, through element 8, passes to control unit 10, and unit 10 issues a command to stop scanning when the scanning beam belongs to the starting point of the sample. However, the equality signal enters the control unit 10 only in the presence of a gating pulse of the driver 9 on. the first input, element 8 And, and now the appearance at its output of the signal of equality indicates membership. ti scanning beam starting point

Claims (1)

¹⁰ The claims as an equal signal and a gate pulse of the shaper 9 coming! on element 8 And almost simultaneously. When scanning in the opposite direction to the given image, the counting pulses from the shaper 4 are fed to the subtracting input of the counter 5 until block 6 gives an equality signal. This fixes the first beam cross section with the boundary of the desired zone. However, due to the fact that the initial sampling point lies on the opposite edge of the image, the scanner continues to move in the same direction 25 due to the lack of a resolving gate of the former 9. This pulse appears only in the interface between adjacent images when the input signal is switched from high 30 to low level. After finding-. After starting the sampling point, block 10 generates a Read command, which selects information from a given array zone. 35 Thus, the introduction of a comparison unit and new constituents into the device A device for reading and selecting images of objects containing a control unit connected to the output of the And element and to the input of the photosensor, the output of which is connected to the video amplifier, an edge detection unit connected to the video amplifier and to the first and second pulse shapers, the outputs of which are connected to a reversible counter, and a memory unit, characterized in that, in order to improve accuracy, it contains a comparison unit, the inputs of which are connected to a reversible counter and to a memory unit, and the output is connected to one input to the element And, the other input of which is connected to the output of the second pulse shaper. Sources of information taken into account during the examination