KR19990024336U - Proximity Sensing Device in Eye Protection TV Using Ultrasonic Sensor - Google Patents

Abstract

The present invention relates to a device for improving proximity distance detection in an eye care TV using an ultrasonic sensor. The inverter outputs a spike and an adder by inverting the polarity of the ultrasonic signal input from the microcomputer. A spike generator that generates a spike signal from the inverted transmission signal, a sawtooth generator that generates sawtooth waves in synchronization with the spike signal, a level adjuster that adjusts the output signal of the sawtooth waves to a level of an appropriate magnitude, Directly from the ultrasonic transmitter close to the interference signal eliminator comprising a summation unit for adding the inverted signal and the sawtooth wave level adjusted to a certain size, and a gain control unit for gain control of the signal introduced into the receiver by the output signal of the summation unit. Unnecessary incoming signal is separated and removed, and only the received signal reflected to the object (viewer) is detected. Proximity sensing device using an ultrasonic sensor to the TV can detect the distance between the object (viewer) and the receiver to enable the power on (on) / off (off) of the receiver or to adjust the image quality for vision protection. .

Description

Proximity Sensing Device in Eye Protection TV Using Ultrasonic Sensor

The present invention relates to a TV (TV), in particular, by applying an ultrasonic sensor to the TV, eyesight protection to detect the distance between the object (viewer) and the receiver power on (on) / off (off) or adjust the image quality The present invention relates to an apparatus for improving proximity detection in a television.

In general, an eye protection TV using an ultrasonic sensor outputs a signal toward an object (viewer) at a transmitter of a receiver, detects an input signal reflected by the object, and enters the receiver, and calculates a distance between the receiver and the object (viewer), It is to protect the eyesight of the viewer by adjusting the image quality according to the calculated value.

1 is a block diagram of an apparatus for detecting a proximity distance of an eye protection television using an ultrasonic sensor according to the prior art, which is an oscillator 12 generating an ultrasonic signal transmission signal and switched on / off by a control signal and outputting the same; A switching unit 13, an output unit 14 for amplifying the signal waveform output from the switching unit 13, a transmitting unit 15 for transmitting the signal output from the output unit 14 in the form of an ultrasonic wave and The receiver 16 receives the ultrasonic signal reflected from the object, the amplifier 17 amplifies the low level signal received by the receiver 16 to a sufficient voltage level, and is output from the amplifier 17. A detector 18 for removing an ultrasonic signal transmission signal component from a signal waveform, an A / D converter 19 for digitally converting a signal output from the detector 18 and outputting the signal to the microcomputer 11; , Turns on / off the switching part 13 with a waveform of a certain period and A / D conversion The microcomputer 11 converts the distance from the object detected by the signal input at 19 and adjusts the image quality corresponding to the distance, and the video signal is processed by the digital signal output from the microcomputer 11. And an image processor 20.

Referring to the accompanying drawings, the operation principle of the eye protection TV using the ultrasonic sensor according to the prior art configured as described above is as follows.

In the block diagram of the apparatus for detecting the proximity distance of the TV using the ultrasonic sensor of FIG. 1, the oscillator 12 generates the 40 kHz signal for transmitting the ultrasonic signal as shown in FIG. 2A and applies it to the switching unit 13.

In addition, as shown in FIG. 2B, the microcomputer 11 turns on / off the switching unit 13 with a signal having a t _cy period having a time width of t ₁ (generally 1 ms).

When the switching unit 13 is turned on by the control of the microcomputer 11, the switching unit 13 outputs the oscillation waveform of the oscillation unit 12 to the output unit 14.

Therefore, a 40 kHz oscillation signal as shown in FIG. 2C is applied to the output unit 14 for a time t ₁ .

The output unit 14 amplifies the voltage enough to send the transmission level of the transmission unit 15 to the transmission unit 15, and the transmission unit 15 transmits toward the front surface in the form of an ultrasonic wave.

At this time, if there is an object (viewer) in the front in Figure 1, the transmitted ultrasound is reflected by the object (viewer) is input to the receiver 16.

Since the input level of the ultrasonic signal received by the receiver 16 is small, if the voltage is sufficiently amplified by the amplifier 17, a signal of 40 Hz component as shown in FIG. 2D waveform is detected.

FIG. 2E is a waveform obtained by removing a 40 kHz component by applying a diode detection or integrating circuit in the detector 18. The signal waveform output from the detector 18 is high in the A / D converter 19 as shown in FIG. 2F. The digital signal is signaled according to the ratio of / low, and the output thereof is input to the microcomputer 11.

In the above description, after the ultrasonic wave such as the waveform of FIG. 2C is transmitted from the TV receiver 21 to the object (viewer), the time taken for the transmitted signal to be reflected and received is converted into a distance.

₁ (m) = 1/2 x t (sec) x 340m of FIG.

Here, 340m is a distance that the ultrasonic waves can go per second (sec), and if the time taken for the ultrasonic wave to be reflected by the object (viewer) and enter the receiver 16 is t (sec), the distance to the object (viewer) l ₁ Since the time required for is half, it is calculated as the distance of t / 2 hours.

Then, the distance from the microcomputer 11 to the object (viewer) is converted, and when the viewer approaches the receiver 21 corresponding to the distance, the power of the receiver 21 is turned off or the screen is darkened. Will be adjusted.

In the eye protection TV using the ultrasonic sensor according to the related art, since the general ultrasonic sensor has a strong linearity, the general detection angle of a commercially available sensor is only about 30 ^o, so that the detection angle is not enough for one pair of transceivers. I'm using.

However, when two pairs of sensors are applied as shown in FIG. 3, the receiver has a structure in which the transmitter R and the receiver S are in close proximity to each other. In this case, as shown in FIG. Signal is generated.

That is, when a transmission signal is applied in the waveform of FIG. 4A for t ₁ hour, an 8tray component is generated, which is repeatedly reflected between the wall and the wall in the case of the transmitter, and the level is not high because the receiver is close. Even if unnecessary signal waveforms are detected in the receiver circuit as shown in Fig. 4B.

When the detected signal waveform is detected by the A / D converter again, a waveform as shown in FIG. 4C is output, which means that an object (viewer) in the vicinity of the receiver cannot be detected by a distance corresponding to a time of t _p .

The present invention has been made to solve such a problem, and when the ultrasonic signal transmitted when the object is detected in the vicinity of the ultrasonic sensor is directly received without reflection, it is an object of the present invention to remove such a signal. .

1 is a block diagram of an apparatus for detecting a proximity distance of a vision protecting TV using an ultrasonic sensor according to the related art.

FIG. 2 is a signal waveform diagram of each block of the apparatus for detecting a proximity distance of a vision protecting TV using the ultrasonic sensor of FIG. 1.

a) shows the waveform of the ultrasonic wave signal generated by the oscillator

b) is the signal waveform output from the microcomputer

c) is the signal waveform transmitted to the output through the switching unit

d) is the signal waveform output through the amplifier

e) is the signal waveform output through the detector

f) shows the signal waveform outputted through the A / D converter and input to the microcomputer

3 is a block diagram of an eye protection TV using the ultrasonic sensor according to the prior art

FIG. 4A is a signal waveform diagram transmitted from the transmitter R of FIG. 3.

4b is a signal waveform diagram directly flowing from the transmitter R of FIG. 3 to the receiver S;

4C is a signal waveform diagram detected by the A / D converter of FIG. 4B.

5 is a block diagram of an apparatus for detecting a proximity distance of a vision protecting TV using an ultrasonic sensor according to the present invention.

FIG. 6 is a signal waveform diagram of each block of the apparatus for detecting a proximity distance of a vision protecting TV using the ultrasonic sensor of FIG. 5.

a) is the signal waveform output from the microcomputer

b) is the signal waveform drawn from the microcomputer and output through the inverting unit

c) is the signal waveform output through the spike generator

d) is a signal waveform diagram in which the signal output from the spike generator is output to the level adjuster via the sawtooth wave generator;

e) is the signal waveform output through the adder

f) is the signal waveform output from the amplifier and input to the gain controller

g) is the signal waveform output from the gain control unit and input to the detector.

Explanation of symbols for main parts of the drawings

21: INVERTER 22: spike generating unit

23: sawtooth wave generator 24: level adjustment unit

25: adder 26: gain control unit

30: interference signal cancellation unit

A feature of the apparatus for improving the proximity detection of a vision-protected TV using the ultrasonic sensor according to the present invention includes an interference signal removing unit for separating and removing unnecessary signals directly flowing from the adjacent ultrasonic transmitter and detecting only the received signal reflected. Characterized in that configured.

Since the process of transmitting ultrasound in the eye protection TV using the ultrasonic sensor according to the present invention is the same as in the prior art, the description is omitted, and in the present invention, only the configuration and operation of the receiving process including the interference signal removing unit will be described with reference to the accompanying drawings. do.

FIG. 5 is a block diagram of an apparatus for detecting a proximity of a vision protection television using an ultrasonic sensor according to an embodiment of the present invention. In the receiving process including an interference signal removing unit of the apparatus for detecting a proximity using an ultrasonic sensor, an inversion on / off control signal may be reversed. All 21, the spike generator 22 for outputting the bipolar spike signal from the inverted control signal, the sawtooth wave generator 23 for outputting the sawtooth wave from the spike signal, and the level adjuster for level adjustment of the output sawtooth wave (24), a summation section (25) which combines the output of the inverting section (21) and the output of the level adjusting section (24), and a receiving section (16) into which a signal reflected from an object (viewer) and a signal not subjected to reflection are introduced. ) And the gain output from the receiver 16 without gaining the signal from the receiver 16 during the time when the gain is 0 by gain control of the signal output from the receiver 16 and the signal output from the adder 25. During the time that A gain control unit 26 for outputting a signal flowing from the receiver 16, a detector 18 for removing the ultrasonic wave oscillation signal component for transmission from the signal output from the gain control unit 26, and a detector 18 And an A / D converter 19 for converting the analog signal output of the digital signal into a digital signal and outputting the digital signal to the microcomputer 11.

Referring to the accompanying drawings, the operation of the reception process including the interference signal removing unit in the apparatus for detecting the proximity of the vision-protected TV using the ultrasonic wave configured as described above is as follows.

As shown in FIG. 6A, a signal having a time width of t ₁ is input to the inverting unit 21.

In the inverting section 21, a signal having a time width of t ₁ is inverted as shown in the waveform of FIG. 6B, and the inverted signal is a spike generating section including a capacitor C ₁ , a resistor R ₁ , and a diode D ₁ . If input to 22, a bipolar spike signal is generated in the bipolar transition portion as shown in FIG. 6C waveform.

When the generated bipolar spike signal is input to the (monostable) sawtooth wave generator 23, a sawtooth wave inverted through the spike 22 is generated, and the sawtooth wave output from the sawtooth wave generator 23 is a level adjuster ( 24), the level is adjusted for the time t _ga to output a waveform as shown in FIG. 6D.

The adder 25 synthesizes the output g of the inverter 21 of FIG. 6B and the sawtooth wave level adjusted by the level adjuster 24 of FIG. 6D to obtain a waveform as shown in FIG. 6E.

Here, there are two signals input to the receiver 16.

One is a signal that is reflected in an object (viewer) after being sent out in space, and the other is a signal that does not undergo the reflection directly introduced from the transmitter 15.

When the two signals are transmitted from the transmitter 15 at the same time point, the dotted line reflected by the gothic portion 40 and the object (viewer) directly introduced from the transmitter 15 to the receiver 16 as shown in FIG. 6F. The portion 50 is a synthesized signal.

As such, the output signal flowing into the receiver 16 and passing through the amplifier 17 is input to the gain control circuit without being directly applied to the detector 18.

The ultrasonic transmission time t ₁ to the gain control signal in the Fig. 6f is reflected on the object (viewer) Figure 6e for detecting only the incoming signal to the normal 1ms, and converted them into the distance.

L =

Since the distance (L) is 17 cm, considering the front distance of the receiver 16 from the receiver 21 to the object (viewer) to be reflected, the distance L is at least 17 cm, so that the transmitter 15 during the ultrasonic transmission time t ₁ (typically 1 ms). Ignoring the signal sent from, there is no problem with the function implementation.

Therefore, in the signal input to the gain control unit 26 during (t ₁ + t _ga ), the signal portion inverted for t ₁ time is treated as a gain zero, and the spike portion of the spike generator 22 output is inverted. In this case, the gain is processed during gain t _ga time, i.e., the slope of the gain characteristic is inversely proportional to the signal level determined by the constant values of the sawtooth generator 23 and the level adjuster 24 based on the characteristics of the sensor. Process.

The gain control signal removes a signal introduced into the receiver 16 during t ₁ in FIG. 6F, and performs gain control to detect only a signal introduced during t _ga .

6G is a signal output obtained by gain control of the FIG. 6F waveform by FIG. 6E, and detects a signal portion carrying pure sensing distance information from which unnecessary signals introduced directly from the transmitter 15 to the receiver 16 are removed.

The detected signal waveform of FIG. 6G is input to the microcomputer 11 through the detector 18 and the A / D converter 19, and the operation thereof is the same as the prior art, and thus description thereof is omitted.

According to the apparatus for detecting a proximity distance in an eye protection TV using the ultrasonic sensor according to the present invention, the signal that is directly transmitted to the receiver without removing the object (viewer) from the signal transmitted from the transmitter is removed, and the object (viewer) is removed. By adding an interference signal canceller to detect only the reflected signal, it is possible to remove unnecessary signals flowing directly from the adjacent ultrasonic transmitter to the receiver.

As a result, the ultrasonic receiver and the transmitter can be arranged in close proximity, and when the vision protection function is applied to the television, it is possible to design the proximity arrangement of the transceiver without structural constraints. The effect is that it can be applied in the structure that must be close.

Claims (3)

In the proximity detection device of the vision protection TV (TV) using the ultrasonic sensor, A control unit which outputs a signal having a predetermined period of time and calculates a distance between the object (viewer) and the TV according to the input digital signal and adjusts the image quality; An ultrasonic transmitter for transmitting an ultrasonic signal to a space at a predetermined cycle having a predetermined time width under the control of the controller; An ultrasonic receiver for receiving and amplifying the ultrasonic signals transmitted from the transmitter; An interference signal removal unit which receives or receives an ultrasonic signal from the ultrasonic receiver and separates or removes a signal directly flowing thereto without detecting the ultrasonic signal; Apparatus for detecting the proximity distance of the eye protection TV using an ultrasonic sensor, characterized in that the detection unit for removing the ultrasonic signal oscillation signal component from the signal output from the interference signal removing unit and converts it into a digital signal to output to the control unit. The method of claim 1, The interference signal removing unit and an inverting unit for inverting the signal when the controller outputs a predetermined period of time having a predetermined time width; A spike generator for generating a spike signal at the bipolar transition portion of the inverted transmission signal; A sawtooth wave generator for generating sawtooth waves in synchronization with the spike signal; A level adjusting unit for level adjusting the output waveform of the sawtooth wave to a predetermined size for a predetermined time; A summing unit for adding the signal inverted in the inverting unit and the output signal of the sawtooth wave generating unit with the level adjusted signal; According to the output signal output from the adder to gain control of the signal received directly without the reflection of the signal of the ultrasonic receiver, the gain control unit for removing the signal, characterized in that the eye protection TV using an ultrasonic sensor Proximity distance sensor. The method of claim 2, wherein the spike generator receives the on / off control signal inverted through the inverting unit (C ₁ , R ₁ ) to differentiate to a predetermined level, and outputs only the bipolar level of the spike signal generated through the differentiator Proximity distance detection device of the eye protection TV using an ultrasonic sensor, characterized in that consisting of a rectifier (D ₁ ).