RU12279U1 - PHOTOELECTRIC CONVERTER OF REMOTE OPTICAL INDICATOR FOR RAST INDICATORS - Google Patents

Abstract

A photoelectric converter of a remote optical pointer for raster indicators, comprising a focusing lens optically coupled to a photodetector, the output of which is connected to the input of the amplifier, as well as a comparator, the output of which is the output of a photoelectric converter, characterized in that it further comprises a comb filter adapted to the horizontal frequency a raster indicator connected by its input to the output of the amplifier, and by its output - with the input of the comparator.

Description

PHOTOELECTRIC CONVERTER OF REMOTE OPTICAL INDICATOR FOR RAST INDICATORS

The inventive utility model relates to peripheral devices for inputting information into a computer, in particular to remote optical pointers (light pens) for displays with raster cathode ray tubes. Advantageously, the device can be used to remotely control a computer from a considerable distance from the display. The need for this type of computer control arises in cases where the user cannot or should not touch the display screen or keyboard.

The basic principle of operation of most light pens is as follows. The light pen is brought directly to the surface of the screen and captures the radiation of the screen at the time of passage of the scanning electron beam under the photodetector element of the light pen. To determine the position of the light pen, the electric signal from its output is compared with the signals of vertical and horizontal deviation of the electron beam from the cathode ray tube. Information about the position of the light pen can later be used in a computer to provide interactive changes to the graphic image on screen 1. Moreover, the normal functioning of the light pen is possible only if it is located in close proximity to the screen, so that the light pen responds only to very small radiation plot of the screen. If

IPC6: G09G1 / 18 light pen is at some distance from the screen, then the intensity

light when passing an electron beam decreases. In this case, the pen photodetector senses the glow of several adjacent lines of the raster, as well as light from external sources, in particular, light reflected from the glass surface of the screen. All this leads to a decrease in the signal-to-noise ratio at the output of the light pen and, as a result, to a decrease in accuracy in determining the location of the light pen.

There are a number of specialized computer remote control devices designed for people who have lost the ability to control their hands. Typically, such systems consist of an information display device (display) and a photodetector mounted on the head. Information display devices contain images of letters of the alphabet and numbers, and sometimes the most common words and expressions, which form the user's dictionary. There are systems in which, next to each element of the dictionary, a light-emitting diode is located on the display, which sequentially emits a light pulse. The photodetector senses the radiation of one of the LEDs, while the scanning of the LEDs stops, and the LED of the selected element lights up until the user changes the position of the photodetector. If the user does not change the position of the photodetector for some certain time, then the corresponding element of the dictionary is displayed on the screen or printed. Such LED systems have several drawbacks. One of them is the lack of continuous feedback on the position of the head, since separate LEDs are used to fix the selection of the element. The user does not know if the photodetector is directed directly at a certain LED.

2 or just to the area next to it, close enough to perceive

radiation from him. In the latter case, the user can change the position of the photodetector before the time required to select a dictionary element has passed. In addition, the display itself is limited in size, the number of dictionary elements, and the way they are displayed, which makes it impossible to customize the system in accordance with the requirements of a particular user. Due to the narrow specialization, and as a result of the limited use of such devices, their price is quite high, since the costs of development and production should be covered with a relatively small volume of production.

Other types of devices use light beam control. At the same time, a small pulsed light emitter is generated on the user's head, generating a narrow light beam. The beam is directed to a special photosensitive communication panel. As such a panel, for example, a matrix of photoconductive elements can be used, each element of which corresponds to a certain key of the keyboard. The disadvantage of such photoconductive matrices is their relatively high cost, due to the need to produce matrices in small batches for a special order, as well as the complexity of the electronic decoding circuit of the selected element. In addition, the source of interference in the system is external lighting, which can introduce photodetectors into the saturation region, as a result of which the device either does not respond at all to the user's choice of an element or displays the wrong element.

3 self remote optical photoelectric converter

pointer for video screens (raster indicators), which consists of a focusing lens, optically coupled to a photodetector, the output of which is connected to the input of the amplifier, to the output of which a comparator is connected. The output of the comparator is the output of the photoelectric converter.

In General, the known device allows you to position the cursor on the screen without directly physically touching its surface, as required by traditional systems with a light pen. To do this, use a remote optical pointer, which registers the radiation of a portion of the screen falling into the field of sight of the optical pointer. The radiation of this part of the screen is focused and converted by a photoelectric converter of the pointer into a series of pulses combined in separate packets. The number of pulses in each packet corresponds to the number of raster lines recorded by the photoelectric converter. The pulsed signals from the optical pointer are sent to the processing unit, where they are compared in time with the field synchronization pulses and horizontal synchronization pulses extracted from the video signal to determine the vertical and horizontal position of the center of the field of view of the optical pointer. The data on the coordinates of the field of view obtained at the output of the processing unit can be used by a computer to generate a cursor in the corresponding location on the screen. The user can optionally move the cursor around the screen by manipulating the pointer and thus use the pointer to provide interaction with the computer in the traditional way, as when working with a mouse or light pen.

4 However, the described photoelectric converter provides

confident recognition or specified accuracy only at a distance not exceeding 80 cm, due to a decrease in the signal-to-noise ratio with increasing range.

The problem solved by the claimed utility model is to increase the working distance of the optical remote pointer for raster indicators.

The essence of the claimed utility model is as follows. In the known photoelectric converter of an optical indicator for raster indicators, comprising a focusing lens optically coupled to a photodetector, the output of which is connected to the input of the amplifier, as well as a comparator, the output of which is the output of the photoelectric converter, an additional comb filter adapted to the horizontal frequency of the raster indicator is introduced, connected by its input to the output of the amplifier, and by its output to the input of the comparator.

The technical result of the claimed utility model is to increase the noise immunity of the photoelectric converter of the optical remote pointer by using an adaptable comb filter, which leads to an increase in the working distance of the optical pointer to 10 m

The achievement of the technical result is due to an increase in the signal-to-noise ratio by using the principle of coordinated filtering 3.4. The spectrum of the useful signal from the raster indicator has characteristic components that are multiples of the horizontal scanning frequency of the indicator. The signal received by the photoelectric converter consists of a useful signal and

5

noise. To increase the signal-to-noise ratio, a comb filter 5 is introduced into the photoelectric converter, the amplitude-frequency characteristic of which is consistent with the spectrum of the useful signal from the raster indicator. The frequency response of the comb filter in this case is consistent with the horizontal frequency of the raster indicator.

The essence of the claimed device is illustrated by the following graphic materials:

FIG. 1.-Functional diagram of the inventive photoelectric converter.

FIG. 2.-Functional diagram of the remote control cursor on the screen of the raster indicator.

A photoelectric converter of a remote optical pointer for raster indicators (Fig. 1) comprises a focusing lens 1 optically coupled to a photodetector 2, the output of which is connected to an amplifier 3, also connected to a comb filter 4, which is adaptable to the horizontal frequency of the raster indicator, the output of which is connected to comparator 5. The output of comparator 5 is the output of the photoelectric converter. An avalanche photodiode can be used as a photodetector.

The proposed photovoltaic converter operates as follows. If the optical pointer is directed to the indicator screen, then the focusing lens 1 focuses on the photodetector 2 the radiation of the fragment consisting of sections of several lines of the raster and falling into the field of sight of the optical pointer. Photodetector 2, in turn, converts this radiation into an electrical signal corresponding to the radiation intensity of the indicator screen. Signal from photodetector 2

It is transmitted to amplifier 3. After the necessary amplification, the signal enters the comb filter 4, where a useful signal is extracted. After that, the signal is supplied to the comparator 5, which operates as a threshold device and compares the value of the input signal with a certain given level and generates a rectangular pulse if the input signal exceeds the threshold value. The signal from the output of the comparator 5 is the output signal of the photoelectric Converter and, accordingly, the optical pointer. Further, this signal is used to form the cursor on the screen of the raster indicator, which requires its corresponding processing. Processing methods may vary. In FIG. 2 shows a functional diagram of one of the possible remote control devices for the cursor on the screen of the raster indicator. The screen cursor forming circuit included with this device is similar to the processing unit of Patent 2.

The device of FIG. 2 consists of a photovoltaic converter 6, a screen cursor forming circuit 7, which contains a clock allocation unit 8, a microprocessor 9, triggers 10, 11, 12, a synchronizer 13, a clock 14, a selector 15, a serial-parallel counter 16, a buffer device 17 and serial interface 18.

The principle of operation of the cursor formation circuit 7 coincides with the principle of operation of the prototype processing unit and is described in detail in the description of Patent 2. Scheme 7 provides the determination of the coordinates of the center of the field of view of the optical pointer, which are also the coordinates of the center of the cursor. The coordinates are determined in accordance with the pulsed signals from the photoelectric transducer 6, the synchronization pulses of the fields and

7 horizontal synchronization pulses coming from block 8. Scheme 7

ignores the pulses from the photoelectric transducer 6, following the first pulse, which corresponds to the registration of the first line of the fragment of the raster, which fell into the field of sight of the optical pointer. In addition, the circuit 7 does not perceive the pulses that were preceded or followed by a break in the raster structure, i.e. when not a single line is logged. Such insensitivity of the circuit 7 to random discontinuities and a large number of pulses from the photoelectric transducer 6 when detecting radiation from a certain portion of the image allows you to determine the coordinates of the cursor more accurately and stably. To determine the horizontal coordinate in scheme 7, using a clock generator 14, a time pulse is generated, the leading edge of which coincides with the moment of arrival of the signal from the photoelectric converter 6, and the trailing edge - with the moment of arrival of the horizontal synchronization pulse from block 8. The duration of this pulse is estimated by counting in the counter 16 consecutive short pulses, the number of which is proportional to the pulse duration. The input of pulses from the photoelectric converter 6 is controlled by a microprocessor 9, which blocks the first and last pulse packets, in which the manifestation of interference is most likely. Thus, greater reliability of the data is provided. For each recorded line of the raster in the counter 16, the total number of short pulses is calculated. After processing all the lines of the fragment, the total amount is divided by the number of registered lines of the raster - as a result, the average value of the horizontal coordinate is obtained.

8 The microprocessor also counts the number of pulses of the lowercase

synchronization, received from the moment of arrival of the field synchronization pulse at the beginning of each frame until the moment the pulses from the photoelectric converter begin to arrive. The average vertical coordinate is defined as the half-sum of the positions of the first and last lines that were used to estimate the horizontal coordinate.

Next, the process of determining the coordinates of the center of the cursor is carried out programmatically using a microprocessor 9, which receives data on vertical coordinates from counter 16, and data on horizontal coordinates from trigger 12, as well as field synchronization pulses and horizontal synchronization pulses from block 8.

Sources of information

1. Tompkins, W., Webster, J. Pairing input sensors with computers IBM PC / Per. from English - M .: Mir, 1992.- S. 485-492.

2. US patent No. 4591841. Remote optical pointer for video screens, 1986. - Prototype

3.Tikhonov V.I. Statistical radio engineering. - M .: Radio and communications, 1982. S. 421-428.

4.Gonorovsky I.S. Radio engineering circuits and signals: Textbook for universities. 4th ed., Revised. and add. - M .: Radio and communications, 1986.- S.356-366.

5.Khokhlov B.N. Decoding devices for color televisions. - M .: Radio and communications, 1992.-S.259-260.

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Claims (1)

A photoelectric converter of a remote optical pointer for raster indicators, comprising a focusing lens optically coupled to a photodetector, the output of which is connected to the input of the amplifier, and a comparator, the output of which is the output of a photoelectric converter, characterized in that it further comprises a comb filter adapted to the horizontal frequency a raster indicator connected by its input to the output of the amplifier, and by its output - with the input of the comparator.