KR100263840B1 - Color video-audio communication system - Google Patents

Abstract

1. TECHNICAL FIELD OF THE INVENTION

Color Video Voice Communication System

2. The technical problem to be solved by the invention

Color video audio communication system, color video audio communication device, color video audio communication device, magnetic and color video audio communication device that can colorize video display with simple circuit configuration without reducing bandwidth of audio signal or video signal. Provided for mosquitoes.

3. Summary of Solution to Invention

It is provided on the transmission line, the magnetic side and the mosquito side, and transmits the baseband magnetic side voice signal from the magnetic side to the mosquito side using the transmission line by the hybrid transformer and the baseband from the mosquito side to the magnetic side using the same transmission line. A voice signal transmitting means for transmitting an audio signal of the mother mosquito, a frequency modulation circuit for frequency modulation of a video signal composed of a luminance signal and a carrier color signal of a baseband, and a frequency modulation circuit provided on the magnetic side. An adder for adding the frequency-modulated video signal to the baseband magnetic-side audio signal and transmitting it to the transmission line, a frequency modulation demodulation means for demodulating the frequency-modulated video signal transmitted from the transmission line and installed on the mosquito side; A knife provided on the side for displaying the video signal from the frequency modulation / demodulation means in color. Also provided with a display means.

4. Important uses of the invention

Used in video and audio communication devices such as monitor intercom devices known as television door phones.

Description

Color Video Voice Communication System

The present invention relates to a color video audio communication system for communicating video and audio signals.

Background Art [0002] Video-audio communication devices, such as interphone devices with monitors, which are conventionally known as television door phones, have a voice communication function capable of talking between a mosquito and a baby via a common transmission line. In addition, it has a monitor display function that monitors images by transferring images from the self to the mosquitoes. Therefore, in the interphone device with a monitor, in order to realize monitor display, an image pickup device is provided on the magnetic side and a television monitor, which is an image display means, on the mosquito side, and the electric signal obtained from the image pickup device on the magnetic side is converted into a video signal. Thus, the video signal is transmitted to the mosquito side through a two-wire transmission line connecting the porcelain and the mosquito, and displayed on the television monitor of the mosquito.

In addition, the audio signal is also capable of bidirectional transmission by transceivers provided on the magnetic side and the mosquito side. The audio signal can be transmitted and received while watching an image. In such a configuration, the video signal and the audio signal are transmitted by a standard image transmission means or an original transmission method. Generally, as described in, for example, Japanese Patent Laid-Open No. 2-50663, a baseband signal and an audio signal of a video signal are put on a carrier wave, modulated, and then mosquitoed, for example, in the NTSC system. And a mosquito is configured to demodulate the modulated signal.

Also, in a monitoring apparatus for monitoring external video and sound, the baseband signal and audio signal of the video signal are carried on a carrier wave, modulated, and then demodulated by a mosquito which is transmitted after being modulated.

However, in the apparatus using such a carrier wave, a modulation / demodulation circuit of an audio signal or a modulation / demodulation circuit of a video signal is required, and the circuit becomes complicated and expensive.

In response to this, it has been developed to allow the transmission of a baseband audio signal by a hybrid transformer, and to transmit and output a black and white video signal by FM modulation on a carrier wave having a center frequency of about 4 MHz. In such a device, since the modulation / demodulation circuit is good for a black and white video signal and is not required for an audio signal, it has a simple circuit configuration, which makes it possible to reduce the price. In addition, since the video signal can be set to a frequency higher than that of the baseband, there is also a feature that the effect of giving an audio signal is minimal.

However, in recent years, the use of color liquid crystal display panels has become mainstream in small monitor devices such as portable television receivers, and even in an interphone device with a monitor, it is difficult to give a good impression to a user unless they are colorized.

In the above-described interphone device with a monitor, in order to enable low cost without reducing the bandwidth of the audio signal or the video signal, the hybrid transformer enables the transmission of the baseband audio signal and at the same time, It has been developed to transmit a black and white video signal by FM modulation on a carrier wave having a center frequency of about 4 MHz. However, in recent years, a small monitor device such as a portable television receiver has used a color liquid crystal display panel. Even in the interphone device, it is difficult to give a good impression to the user unless it is colorized.

A television door phone device is disclosed in Japanese Patent Laid-Open No. 61-43889 (Example 1). This television door phone device has adopted a light emitting diode (LED) that emits infrared rays as illumination for a subject when the image is black and white, and particularly when the natural light is low, such as at night or in the evening light. This is because the CCD, which is an image pickup device, also has sensitivity in the near infrared region, and thus uses a point capable of capturing a subject illuminated with near infrared rays. In addition, since the visitor, which is a subject illuminated with near infrared rays, does not notice the illumination, the visitor can take an image without causing discomfort to the visitor, and the LED also has the advantages of low cost and long life. In this type of TV door phone device, since the illuminance of the infrared light from the LED is always constant, when the illuminance of the subject changes according to the circumstances of the surrounding environment, by adjusting with the shutter control function of the video camera, Images of appropriate exposure were obtained.

A television door phone device in which a video is colored is disclosed in Japanese Unexamined Patent Publication No. 1-243794 (Prior Example 2). In this color television door phone device, when a subject is to be irradiated with infrared light to capture an image in an environment such as a night where it is difficult to obtain a subject light, the color camera outputs an unnatural color video signal and a color at night. In order to solve the problem that the S / N ratio decreases when the subject illuminance is lower than that of the white image signal, and the color reproducibility is deteriorated, the image signal automatically cuts the unsightly color of the subject in the environment where the subject illuminance is lowered. It is to switch to black and white video.

In addition, a color television door phone device capable of always obtaining a color image even at night without switching the color to a black and white image in an environment in which the subject illuminance is degraded as in the above-described conventional example 2 is disclosed in Japanese Patent Laid-Open No. 4-269090. It is disclosed in the publication (prior example 3). This color television door phone device is constituted by a mosquito installed indoors, electrically connected to the mosquito via a signal line, and provided with a porcelain disposed on a porch, and a lighting apparatus provided near the porcelain.

As described above, a pair of parallel wires (pair wires) such as those disclosed in Japanese Patent Application Laid-Open No. 62-257287 (Prior Example 4) are used as the signal line connecting the mosquito and the porcelain. The pair of parallel lines is configured to transmit a color video signal and an audio signal composed of a color signal and a luminance signal.

In addition, Japanese Unexamined Patent Publication No. 61-167292 (Prior Example 5) does not clearly distinguish between color and black and white images, but it is configured to turn on the lighting of the illumination part installed in the self when the subject illumination is low at night. A television door phone device is disclosed.

However, as in the conventional example 2, when the television door phone device is to colorize the image using, for example, a color CCD, when the subject illuminance is low, such as at night, the subject is photographed by near-infrared light emitted from the light emitting diode. When illuminated, the image becomes an unnatural color that only appears blue, for example. In addition, when the subject is illuminated by mixing external light such as natural light in addition to near-infrared light, there is a problem that the image taken by the color monitor described above becomes more unnatural and unsightly.

In addition, in the color television door phone device in which the lighting device is arranged near the self so that color images can be obtained at night, the lighting device is separate from the self, and both of them are installed at the entrance or the like. The constructability is a problem such as the need to do it and the power wiring of the lighting apparatus to be redone.

Therefore, the present invention provides a color video audio communication system, a color video audio communication device, a color video audio communication device, and a magnetic and color device capable of colorizing a video display with a simple circuit configuration without reducing the bandwidth of an audio signal or a video signal. An object of the present invention is to provide a mosquito for color video audio communication device.

In addition, in the present invention, using a small light source that emits visible light that can be installed in the main body to illuminate the subject, while suppressing the enlargement of the magnetism, the color television door phone magnetic and color television door can obtain a clear color image at night An object of the present invention is to provide a phone device.

BRIEF DESCRIPTION OF THE DRAWINGS Fig. 1 is a block diagram showing an embodiment of the invention in a color video audio communication system according to the present invention.

2 is a perspective view of a color television door phone device according to one embodiment of the present invention;

3 is a block diagram of a color television door phone device according to one embodiment of the present invention;

4 is a graph showing the spectral characteristics of the CdS sensor.

5 is a characteristic diagram showing the relationship between the resistance value and illuminance of the CdS sensor.

Fig. 6 is a front view showing the surveillance camera device to which the color video audio communication system of Fig. 1 is applied.

7 is a spectral distribution diagram of a white LED.

Fig. 8 is a spectral distribution diagram of an incandescent lamp (white lamp manufactured by Toshiba Leitek Corporation).

Fig. 9 is a spectral distribution diagram of a fluorescent lamp [Mellow 5N manufactured by Toshiba Leitec Co., Ltd., Japan].

<Explanation of symbols for the main parts of the drawings>

1: Color video audio communication system 2, 3: Transmission line

10: magnetic 10a: magnetic body

10b: Color CCD 10c: Call Button Switch

10d: microphone 10e: speaker

10f: LED 10g: light diffusion means

11: first communication means 12: transceiver

13: voice circuit 14, 34: low pass filter (LPF)

15: color image means 16: color image element

17 process circuit 18 frequency (FM) modulation circuit

19, 39: High Pass Filter (HPF) 20, 21: Terminal

22: adder 30: mosquito

30a: color monitor 30b: handset

31: second communication means 32: transceiver

33: audio circuit 35: connection point

38: FM demodulation circuit 40, 41: terminal

42: color image display means 50: transmission line transformer

70: surveillance camera body 71: shooting lens

72: transparent plate 73: the microphone

80: monitor device 81: camera image display means

82: sound output means

The invention of the first embodiment of the present invention is provided on the transmission line, the magnetic side and the mosquito side, and transmits the baseband magnetic side voice signal from the magnetic side to the mosquito side using the transmission line by a hybrid transformer. Voice signal transmitting means for transmitting the baseband mosquito side audio signal from the mosquito side to the magnetic side using a transmission line, and a frequency modulation circuit provided on the magnetic side to frequency modulate a video signal composed of the baseband luminance signal and the carrier color signal. And an adder which is provided on the magnetic side and adds a video signal frequency-modulated by the frequency modulation circuit to the magnetic side audio signal of the baseband and always transmits it to the transmission line, and is installed on the mosquito side. Frequency modulation demodulation means for demodulating the frequency-modulated video signal to be transmitted; And color image display means for displaying the video signal from the frequency modulation and demodulation means in color.

The invention of the second embodiment of the present invention is provided on the magnetic side and the mosquito side, and transmits the baseband magnetic side voice signal from the magnetic side to the mosquito side using a transmission line by a hybrid transformer, and at the same time uses a transmission line. A voice signal transmitting means for transmitting a baseband mosquito side voice signal from one side to a magnetic side, a frequency modulation circuit provided on the magnetic side for frequency modulating a video signal comprising a baseband luminance signal and a carrier color signal, and the magnetic side And an adder for adding the video signal frequency-modulated by the frequency modulation circuit to the magnetic side audio signal of the baseband and transmitting it to the transmission line, and the frequency-modulated signal provided on the mosquito side and transmitted on the transmission line. Frequency modulation demodulation means for demodulating a video signal, and on the mosquito side, the frequency modulation demodulation means; In that it includes a color image display means for displaying the video signal from the means to the collar and is characterized.

According to a third aspect of the present invention, there is provided a frequency signal for frequency-modulating a video signal consisting of a voice signal transmitting means for transmitting a baseband magnetic side voice signal to a mosquito using a transmission line, and a luminance signal and a carrier color signal of the baseband. And a modulator and an adder which adds a video signal frequency-modulated by the frequency modulator to the magnetic side voice signal of the baseband and transmits it to the transmission line.

In accordance with a fourth aspect of the present invention, an audio signal transmitting means for transmitting a baseband mosquito side audio signal to a magnetic side using a transmission line, and a frequency modulation demodulation means for demodulating a frequency-modulated video signal transmitted from the transmission line. And color image display means for displaying the video signal from the frequency modulation demodulation means in color.

According to a fifth aspect of the present invention, in the first embodiment, a transmission line transformer is interposed as a similar transmission path between at least one internal circuit of the magnetic or mosquito and the transmission line. .

According to a sixth aspect of the present invention, there is provided a magnetic body, a solid state image pickup device disposed in the magnetic body and outputting a color image signal by photoelectric conversion, and a color image signal output from the solid state image pickup device to perform video processing. A voice signal processing means for outputting as a signal, a voice signal processing means for disposing in the main body and outputting voice as a voice signal, and a small light source disposed in the main body for illuminating the subject with white light. do.

The invention according to the seventh embodiment of the present invention has a solid-state image pickup device which is provided in a magnetic body and a magnetic body, and outputs a color image signal by photoelectric conversion, and an automatic gain control circuit, and at the same time improves the manual exposure operation to the sensitivity improving side. Manual exposure control means configured to set the automatic gain adjustment circuit to increase gain in the case of operation and to set the automatic gain adjustment circuit to decrease in gain when the manual exposure operation is operated to lower the sensitivity, and output from the solid state image pickup device. Video signal processing means for outputting a video signal for performing signal processing on the color video signal that has been processed, audio signal processing means for disposing in the main body and outputting audio as a voice signal, and for discharging the subject with white light. It is characterized by having a small light source for illuminating.

The invention according to the eighth embodiment of the present invention is characterized in that a light expanding means is provided in front of the irradiation direction of the small light source.

According to a ninth aspect of the present invention, the small light source is a white LED.

The invention of the tenth embodiment of the present invention outputs the magnetic signal for the color video-audio device according to the sixth embodiment, the color monitor for displaying the video signal output from the video signal processing means, and the audio signal output from the audio signal processing means. And a cable for electrically connecting the magnetic image and the mosquito for the color image audio communication device having a speaker.

(Example)

Hereinafter, embodiments of the present invention will be described with reference to the drawings.

1 is a block diagram showing an embodiment of a color video audio communication system according to the present invention.

In FIG. 1, the color video audio communication system 1 has a configuration in which a magnetic wire 10 and a mosquito 30 are connected by two-wire transmission lines 2 and 3. As shown in FIG. The color video audio communication system 1 has a voice call function for making a voice call in both directions between the mosquito 30 and the magnet 10 via two-wire transmission lines 2 and 3, and a mosquito in the magnet 10. It has a monitor display function of transmitting a video signal of a frequency-modulated color to (30) to display a monitor as a color image. The porcelain 10 and the mosquito 30 constitute a video audio communication device.

First, the magnet 10 will be described. The first call means 11 on the side of the person 10 to whom the call function is applied is composed of a transceiver 12 and a voice circuit 13.

The transceiver 12 of the first call means 11 on its own side is provided with a microphone and a speaker, and supplies the audio signal a1 from the microphone to the audio circuit 13.

The audio circuit 13 has a hybrid transformer, and passes the audio signal a1 from the midpoint of the primary winding of the hybrid transformer to one end side to a low pass filter ("LPF") 14. Induce. The LPF 14 allows only the frequency band included in the frequency band in the vicinity of the voice frequency (for example, 20 Hz to 20 KHz, which is an audible region) to pass, and passes the voice signal a1 from the voice circuit 13. It introduces into the adder (22). The audio circuit 13 supplies the transceiver 12 audio signal b1, which will be described later, generated in the secondary winding of the hybrid transformer to the transceiver 12 and outputs it from the speaker.

Next, the imaging function of the magnet 10 will be described. The color imaging means 15 is composed of a color imaging element 16 and a process circuit 17. The color image element 16 is composed of a lens, a charge coupled device (CCD), a color image sensor, and the like. The color image element 16 captures a subject in color and outputs a three-color signal of red-green-blue (RGB). The process circuit 17 is a frequency modulation circuit (hereinafter referred to as an "FM modulation circuit") 18 that consists of a video signal c1 consisting of a baseband luminance signal and a carrier color signal from three-color signals from the color image elements 16. To supply. The FM modulation circuit 18 frequency modulates the video signal c1, and introduces the FM video signal d1 centered at 10 MHz into the high pass filter (referred to as "HPF") 19.

The HPF 19 blocks the frequency band in the vicinity of the audio frequency, and passes the FM video signal d1 in the FM modulator 18 to the adder 22.

The output terminal of the adder 22 is connected to one terminal 20 of the pair of input / output terminals of the magnetic unit 10. The other terminal 21 of the pair of input / output terminals of the magnet 10 is connected to each circuit of the magnet 10 and is connected to the reference potential point. Terminals 20 and 21 are connected to one end of transmission lines 2 and 3, respectively.

Next, the mosquito 30 is demonstrated.

The second call means 31 on the side of the mosquito 30 that completes the call function is composed of a transceiver 32 and an audio circuit 33.

The transceiver 32 of the second call means 31 on the side of the mosquito 30 is provided with a microphone speaker, and supplies the voice signal e1 from the microphone to the voice circuit 32.

The audio circuit 33 has a hybrid transformer, and passes the audio signal e1 at one end side from the midpoint of the primary winding of the hybrid transformer to guide the low pass filter (referred to as an LPF) 34. . The LPF 34 allows only the frequency band included in the frequency band in the vicinity of the voice frequency to pass therethrough. The LPF 34 passes the voice signal a1 in the voice circuit 33 and introduces it into the connection point 35. In addition, the audio circuit 13 supplies the transceiver 32, the magnetic side voice signal f1 described later generated in the secondary winding of the hybrid transformer, to be output from the speaker.

The connection point 35 is connected to one terminal 40 of the pair of input / output terminals of the mosquito 30 via the primary winding 11 of the transmission line transformer 50. The other terminal 41 of the input / output terminal pair of the mosquito 30 is connected to each circuit of the mosquito 30 via the secondary winding 12 of the transmission line transformer 50, and is connected to the reference potential point. do. The terminals 40 and 41 are connected to the other ends of the transmission lines 2 and 3, respectively. By such a connection, the connection point 35 is guided to the FM video signal of the magnet 10 and the audio signal of the baseband.

The transmission line transformer 50 is composed of toroidal coils, for example, and is formed as a pseudo transmission line.

The connection point 35 is connected to the HPF 39. The HPF 39 is configured to block a frequency band near the audio frequency. The HPF 39 blocks an audio signal of the baseband from the magnet 10 and passes the FM video signal from the magnet 10 to the FM video signal g1. ) To the FM demodulation circuit 38. The FM demodulation circuit 38 demodulates the FM video signal g1, converts it into a video signal h1 consisting of a baseband luminance signal and a carrier color signal, and supplies it to the color image display means 42.

The color image display means 42 is comprised by the color liquid crystal display panel, for example, and displays the video signal h1 as an image of a color.

According to such a configuration, the communication means 11 and 31 are provided on the magnetic 10 side and the mosquito 30 side, and the magnetic means are transferred using the transmission lines 2 and 3 by the hybrid transformer. 10) side transmits the baseband magnetic side voice signal to the mosquito 30 side and simultaneously transmits the baseband mosquito side voice signal from the mosquito 30 side to the magnetic 10 side using the same transmission line. It is by means.

The operation of this embodiment of the invention is described below.

The signals of the three colors of the image picked up by the color image pickup device 16 are converted by the process circuit 17 into a video signal c1 composed of the baseband luminance signal and the carrier color signal, and fed to the FM modulation circuit 18. Is modulated to the FM video signal d1, and the FM demodulation circuit 38 is transmitted through the HPF 19, the adder 22, the transmission lines 2 and 3, the transmission line transformer 50 and the HPF 39. ) Is demodulated into a video signal h1 comprising the luminance signal of the baseband and the carrier color signal, and displayed as a color image by the color image display means 42.

The magnetic side voice signal a1 inputted by the microphone of the transceiver 12 on the magnetic field 10 side is one end from the midpoint of the primary winding of the hybrid transformer of the voice circuit 13, the LPF 14 and the adder ( 22) is supplied to the primary winding of the hybrid transformer of the voice circuit 33 via the transmission lines 2 and 3, the transmission line transformer 50 and the LPF 34. Thereby, from the secondary winding of the hybrid transformer of the audio circuit 33, the magnetic side voice signal f1 having the same contents as the magnetic side voice signal a1 is supplied to the transceiver 32, and the magnetic side from the speaker. The audio signal f1 is output as an audible voice.

The mosquito side voice signal e1 input by the microphone of the transceiver 32 on the side of the mosquito 30 is one end from the midpoint of the primary winding of the hybrid transformer of the voice circuit 33, the LPF 34, and the connection point ( 35) is supplied to the primary winding of the hybrid transformer of the audio circuit 13 via the transmission line transformer 50, the transmission lines 2, 3, and the LPF 14. Accordingly, the mosquito side audio signal b1 having the same content as the mosquito side audio signal e1 is supplied from the secondary winding of the hybrid transformer of the audio circuit 13 to the transceiver 12, and the mosquito side from the speaker. The audio signal b1 is output as an audible voice.

In this operation, the LPF prevents the influence of the baseband audio signal from being applied to the FM demodulation circuit 18 and the FM demodulation circuit 38 by the movement of the HPFs 19 and 39. The movements of (19) and (39) prevent the influence of the FM video signal from being applied to the audio circuits (13) and (33).

As the transmission line transformer 50 embeds the pseudo transmission line, the short distances that the transmission lines 2 and 3 handle in the centralized constant circuit (ie, the length of the transmission lines 2 and 3 are 7.5). Even if m is used, the transmission lines 2 and 3 are operated as a distribution constant circuit, whereby stable frequency characteristics can be maintained, and image degradation caused by confusion of frequency characteristics can be prevented.

Specifically, the wavelength of the FM video signal transmitted from the transmission lines 2 and 3 is 30 m, and when the transmission line transformer 50 cannot be installed, the length of the transmission lines 2 and 3 Becomes 7.5 m, which is 1/4 of the wavelength of the FM video signal, resonance occurs and the frequency characteristic is disturbed. However, by providing the transmission line transformer 50, the transmission line becomes substantially long, thereby preventing resonance and confusion of frequency characteristics.

As described above, according to the embodiment of the present invention, only the video signal consisting of the luminance signal of the baseband and the carrier color signal is transmitted by frequency modulation, and the magnetic side voice signal and the mosquito side voice signal are transmitted to the baseband. By colorizing the video display with a simple circuit configuration without reducing the bandwidth of the video signal, it is possible to give a good impression to the user without excessively increasing the manufacturing cost.

Here, the advantage point of the system which can conventionally colorize video display is demonstrated. When transmitting / receiving audio signals through a system such as CATV, audio is transmitted by FM. Therefore, when transmitting and receiving bidirectionally by a mosquito and a self, two FM demodulation circuits and two FM modulation circuits are required. Since the demodulation circuit and the FM modulation circuit increase, the manufacturing cost becomes higher than that of the embodiment of the invention of FIG.

2 is a perspective view of a television door phone apparatus to which the video and voice communication system of FIG. 1 is applied. The television door phone device is composed of a porcelain 1 provided on an outdoor side and a mosquito 2 provided on an indoor side, and both are electrically connected by a cable 3.

The magnet 1 includes a color CCD 10b as a solid state image pickup device, a call button switch 10c, a microphone 10d for recording the visitor's sound, and a speaker 10e for outputting the sound of the correspondent in the magnetic body 10a. And LED 10f, which is a small light source that emits visible light (white) that illuminates the visitor when the surrounding environment is dark. Light diffusion means 10g are disposed in front of the irradiation direction of the LED 10f. In addition, a CdS sensor for detecting visible light illuminance is also disposed.

In addition, the mosquito 30 outputs a handset 30b to which a color monitor 30a for illuminating the visitor's image, a speaker for outputting the visitor's sound, and a microphone for recording the visitor's sound are integrally attached, and a ring tone. I have a speaker.

In the period when the natural light of the night light is low light, the LED 1f lights up to illuminate the visitor. The color CCD 10b captures the visitor illuminated by the visible light irradiated by the LED 10f. Moreover, the call with the visitor can be made without a problem by the speaker 10e, the microphone 10d of the magnet 1, and the handset 30b of the mosquito 30. In addition, when the visitor presses the button switch 10c, a ring tone is generated from the speaker of the mosquito 30.

Here, the outline | summary of the white LED by the Japanese Ichiagagaku Kogyo Co., Ltd. used in this embodiment is demonstrated below. This white LED is similar to a normal InGaN-based blue LED in terms of its basic structure, but a thin phosphor is coated on the chip surface of the light emitting source. Then, the blue light emitted from the chip is incident on the phosphor and then emitted and scattered in the phosphor, and then emitted outside. At this time, the blue light absorbed by the phosphor acts as an excitation source and emits yellow fluorescence. The yellow light and blue light are mixed with each other to appear white. Moreover, the characteristic of this white LED is luminous intensity 3cd and efficiency 5.01 m / W at 20 mA electric current and 25 degreeC of ambient temperature, and has a color temperature of 8000K.

7 is a spectral distribution diagram of a white LED. According to this, light is emitted in the visible wavelength range of about 380 nm to 800 nm, and particularly, has a spectral characteristic with a gentle emission peak around 450 nm indicating blue light and 550 nm showing yellow light.

FIG. 8 is a spectral distribution diagram of an incandescent lamp (white lamp manufactured by Toshiba Leitek Co., Ltd., Japan). According to this, light is emitted in the visible wavelength region and the infrared wavelength region of about 400 nm to 2000 nm, and most of the energy is emitted in the infrared wavelength region.

9 is a spectral distribution diagram of a fluorescent lamp (Mellow 5N manufactured by Toshiba Leitec Co., Ltd., Japan). According to this, it emits light in the visible wavelength range of about 400 nm to 720 nm, and in particular, has a spectral characteristic in which the emission peak is present in red light, green light and blue light.

As described above, most of the infra-red wavelengths and incandescent lamps with low energy in the visible wavelength range are difficult to sufficiently illuminate the subjects, and the color tone is not sufficient. In a fluorescent lamp having a spectral characteristic having a plurality of emission peaks, the chromaticity of the color image is easily influenced by one emission peak. In this case, it is necessary to adjust by a fluorescent lamp or a video signal processing circuit. In addition, a fluorescent lamp requires a lighting circuit in particular, which may be large and expensive.

Therefore, in order to obtain a clear color image, a continuous spectrum such as natural light is most preferable, and light is emitted in the visible wavelength range of about 380 nm to 800 nm, and a white LED having spectral characteristics with a gentle emission peak is easy in such a case. It is easy to be adopted.

According to the present embodiment, in the case of low light such as at night, the visible light visitors in the LED 10f are illuminated and imaged, so that the screen is very easy to see and the visitor can be easily checked. In addition, since a light source having a long life can be used at a low price, such as the LED 10f, the maintenance of the device can be facilitated and the operating cost can be kept low.

3 is a block diagram of a television door phone device according to one embodiment of the present invention. In the figure, reference numeral B denotes an image pickup unit which captures visitor A as a subject and obtains a color image signal B1. The lens B2 condenses the reflected light of the visitor A and the color image signal by photoelectric conversion of the light collected by the lens B2. It has CCD 10b set to B1.

The code C is a video signal processing means for driving the CCD 10b and performing a variety of processing on the color video signal B1 obtained by the CCD 10b to produce and output a video signal C1 composed of a luminance signal and a color signal. . Code D is a CdS sensor that detects illuminance of visible light. A code E is a determination unit that determines whether or not the illuminance level of the surrounding environment detected by the CdS sensor D is below the set value. Reference numeral 10f denotes an LED which emits visible light for illuminating the visitor A, and the LED lighting control means F controls the lighting of the LED 10f by the lighting signal from the determination unit D. The audio signal processing means G outputs the audio signal G1 recorded in the microphone 10d disposed in the main body 10a.

4 is a graph showing the spectral characteristics of the CdS sensor. According to this graph, the CdS sensor wavelengths are sensitive to visible light in the range of 400 nm to 700 nm, but are insensitive to infrared rays having a wavelength of 700 nm or more.

5 is a characteristic diagram showing the relationship between the resistance value and illuminance of the CdS sensor. CdS sensor D has a characteristic that the resistance value decreases when the illuminance increases. The code | symbol in a figure has shown the kind of CdS sensor D. FIG.

In addition, in this embodiment, the exposure control means is improved to solve the following problems. That is, when the ambient environment ensures the gradation reproducibility of the color monitor required from low light to high light in the first half, conventionally, only the automatic exposure and manual exposure control is performed. If there is a highlight inside, the automatic gain control circuit lowers the gain, resulting in a dark screen setting as a whole.

On the contrary, when the whole screen is dark even if the sensitivity is reduced, the automatic gain control circuit improves the sensitivity and there is a problem that the highlight portion is damaged by white.

Thus, as shown in FIG. 2, in the manual exposure control means H, when the manual exposure operation is operated on the sensitivity enhancement side, the automatic gain adjustment circuit is set to the gain increase and the manual exposure operation is operated on the sensitivity lower side. The automatic gain adjustment circuit is set to gain reduction.

In other words, the automatic exposure control circuit, the manual exposure control circuit, and the electronic shutter speed can be variably controlled by these control circuits to set the exposure and start the automatic exposure when the CCD is operated, and then the manual exposure operation. It is switched to the exposure setting by manual exposure and equipped with the automatic gain adjustment circuit of the image signals obtained by these exposure controls, so that it is possible to control the operation which does not match the automatic gain control circuit, and the operator can generate the image signal of the desired brightness. have.

In addition, in order to obtain gradation reproducibility under low illumination, since the gamma value is set low in the past, under high illumination, white gradation tends to be clogged, and there is a problem that highlight portions are scattered.

Therefore, when a CCD camera equipped with an automatic exposure function and a gamma value variable function is provided and a sufficient video signal level cannot be obtained under low light, the gamma value is set to the lowest value so that the gray level reproducibility can be secured as in the prior art. It was. On the other hand, when the light amount can be obtained more than the maximum exposure state, by setting the gamma value to a relatively larger value than under low illumination, the linearity of the high level portion of the video signal is improved, thereby preventing the occurrence of white damage and causing low A good video signal without black or white damage can be obtained from Doha to high illuminance.

6 is a front view showing a surveillance camera device to which the color video audio communication system of FIG. 1 is applied.

6, the image pickup lens 71 of the color image means 15 of FIG. 1 is provided in the surveillance camera main body 70 serving as the magnet 10 and monitors the FM image signal. On the 80 side, various circuits for transmitting via the wirings 2 and 3 are provided.

In more detail, the monitoring camera main body 70 is connected to the monitor apparatus 80 side via the wirings 2 and 3. The photographing lens 71 is provided at the position in front of the inside of the surveillance camera main body 70. A dustproof transparent plate 72 is provided around the front side and the front side of the photographing lens 71. The microphone 73 is provided in the front lower side of the surveillance camera main body 70. As shown in FIG.

The monitor device 80 separates the audio signal of the baseband from the camera video display means 81 for displaying the FM video signal from the surveillance camera 70, and the FM video signal from the surveillance camera body 70. Audio output means 82 for performing audio output is provided.

According to such a structure, the video-audio communication system of FIG. 1 can be applied to a surveillance camera device.

Moreover, in the embodiment of the invention shown in FIG. 1, although a transmission line transformer intervenes as a similar transmission line between the transmission line and the mosquito internal circuit, the transmission line transformer is a magnetic or What is necessary is just to provide between the internal circuit of the mosquito and the said transmission line.

As described above, according to the inventions of the first to fifth embodiments, the video display can be colored with a simple circuit configuration without reducing the bandwidth of the audio signal or the video signal. It can make a high impression on a user without increasing.

According to the structure of 5th Embodiment, image deterioration resulting from the confusion of a frequency characteristic can be prevented, and a high impression can be given to a user.

In the invention of the sixth embodiment, since a small light source that emits visible light that can be installed in the magnetic body is used to illuminate a subject, it is possible to suppress the enlargement of the color television door phone itself and to obtain a clear color image at night. have.

In the invention of the seventh embodiment, in addition to the effects of the invention of the first embodiment, the operation according to the automatic gain control circuit can be regulated by the exposure control by manual exposure, and the operator can adjust the video signal of the desired brightness. May occur.

In the inventions of the eighth and ninth embodiments, in addition to the effects of the invention of the first embodiment, since the light emitted from the light source is diffused, the subject can be uniformly illuminated, and the subject is, for example, glare to the visitor. It can make it hard to feel.

In the invention of the tenth embodiment, the vivid image can be obtained even at night by a color monitor due to the invention effect of the first embodiment.

Claims (10)

Transmission line, It is installed on the magnetic side and the mosquito side, and transmits the baseband magnetic side voice signal from the magnetic side to the mosquito side using the above-mentioned transmission line by the hybrid transformer, and simultaneously uses the same transmission line. Voice signal transmitting means for transmitting the baseband mosquito side voice signal from the side to the self side; A frequency modulating circuit provided on the magnetic side and frequency modulating a video signal comprising a baseband luminance signal and a carrier color signal; An adder provided on the magnetic side, for adding a video signal frequency-modulated by the frequency modulation circuit to the magnetic side audio signal of the baseband and transmitting the video signal to the transmission line; Frequency modulation and demodulation means which is provided at the side of the mosquito and demodulates the frequency-modulated video signal transmitted from the transmission line; And a color display means which is provided on the side of the mosquito and displays the video signal from the frequency modulation and demodulation means in color. It is installed on the magnetic side and the mosquito side, and transmits the baseband magnetic side voice signal from the magnetic side to the mosquito side using the transmission line by the hybrid transformer, and the baseband mosquito side from the mosquito side to the magnetic side using the same transmission line. Voice signal transmitting means for transmitting a side voice signal; A frequency modulating circuit provided on the magnetic side and frequency modulating a video signal comprising a luminance signal of a baseband and a carrier color signal; An adder which is provided on the magnetic side and adds the video signal frequency-modulated by the frequency modulation circuit to the magnetic side audio signal of the baseband and transmits it to the transmission line; Frequency modulation and demodulation means which is provided at the side of the mosquito and demodulates the frequency-modulated video signal transmitted from the transmission line; And a color image display means which is provided at the side of the mosquito and displays the video signal from the frequency modulation and demodulation means in color. Voice signal transmission means for transmitting the magnetic side voice signal of the baseband to the mosquito side using a transmission line; A frequency modulation circuit for frequency modulating a video signal comprising a baseband luminance signal and a carrier color signal; And an adder which adds a video signal frequency-modulated by the frequency modulation circuit to the audio signal of the baseband of the baseband and transmits the video signal to the transmission line. Voice signal transmitting means for transmitting a baseband mosquito-side voice signal to a magnetic side using a transmission line; Frequency modulated demodulation means for demodulating a frequency modulated video signal transmitted from said transmission line; And a color image display means for displaying a video signal from said frequency modulation / demodulation means in color. 2. The color video audio communication system according to claim 1, wherein the magnetic or mosquito sandwiches a transmission line transformer as a similar transmission line between at least one internal circuit and the transmission line. A magnetic body; A solid-state imaging device installed in the magnetic body and outputting a color image signal by photoelectric conversion; Image signal processing means for outputting a video signal subjected to signal processing on the color image signal output from the solid state image pickup device; Sound signal processing means provided in the main body and outputting sound as a sound signal; A magnet for a color image audio communication device, comprising: a small light source provided in a main body and illuminating a subject with white light. A magnetic body; A solid-state imaging device disposed in the magnetic body and outputting a color image signal by photoelectric conversion; If the automatic gain control circuit is operated and the manual exposure operation is operated on the sensitivity side, the automatic gain adjustment circuit is set to increase the gain, and the manual gain operation is operated on the sensitivity side. Manual exposure control means configured to set the gain reduction; Image signal processing means for outputting a video signal subjected to signal processing on the color image signal output from the solid state image pickup device; Sound signal processing means provided in the main body and outputting sound as a sound signal; A magnet for color image audio communication device, which is provided in a magnetic body and comprises a small light source for illuminating the projectile with white light. The magnetism for color video audio communication device according to claim 6, wherein light diffusion means is arranged in the direction of irradiation of the small light source. The magnetic image device of claim 6, wherein the small light source is a white LED. Magnetic image for the color image communication device according to claim 6: A mosquito for a color video audio communication apparatus having a color monitor for displaying a video signal output from the video signal processing means and a speaker for outputting the audio signal output from the audio signal processing means; And a transmission line for electrically connecting the magnetic and mosquitoes for the color image audio communication device.

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