JPH0461491A - Solid-state image pickup device - Google Patents

Abstract

PURPOSE:To simplify the communication line and to reduce the cost of the image pickup system by sending a video signal synchronously with a television synchronizing signal to the communication line. CONSTITUTION:Solid-state image pickup devices 30 to each of which an address is given are interconnected in series with a communication line 20. The plural solid-state image pickup devices connected to the common communication line 20 are operated selectively by giving various communication data to control the operation of the solid-state image pickup devices to the solid-state image pickup devices 30 while being superimposed on a synchronizing signal for its specific period and video signals whose scanning timing is coincident are obtained from the solid-state image pickup devices 30. Thus, number of the solid-state image pickup devices 30 enabling to be designated by the number of communication data are connected to the same communication line 20 without any special circuit provision, the communication line is simplified and a large sized image pickup system is inexpensively configured.

Description

DETAILED DESCRIPTION OF THE INVENTION (a) Field of Industrial Application The present invention relates to a solid-state imaging device that is capable of transmitting and receiving various communication data via a communication line.

(B) Prior Art A surveillance system or the like in which a plurality of television cameras are used is configured to be able to simultaneously reproduce video signals from each television camera. Methods for displaying multiple playback screens in this way include displaying the images captured by each TV camera on multiple TV monitors, displaying each video on a single TV monitor in time division, or Examples include a method of dividing the screen of a television monitor into multiple parts for display.

In general surveillance systems, it is desirable to obtain multiple playback screens, but high resolution is often not particularly required, so there is a tendency to adopt a method of displaying multiple playback screens split on a single TV monitor. It is in.

FIG. 5 is a block diagram showing the configuration of an imaging system that displays a plurality of playback screens on one television monitor. Here, a case is shown in which four playback screens are displayed on a television monitor (5) using four television cameras (1) to (4).

Each television camera (1) to (4) is connected in parallel to the main controller (6), and each television camera (1) to (4) is connected in parallel to the main controller (6).
The video signals ¥1 to Y4 outputted from (4) are manually input to the main controller (6). This main controller (6) includes a synchronization signal generation circuit (6a), a screen control circuit (
6b) and a field memory (6c), and synchronizes the operation of each television camera (1) to (4) with a predetermined timing, and also synchronizes each video signal Y1 to Y.

A video signal Ym for displaying the four videos simultaneously on the same screen is created and supplied to the television monitor (5).

The synchronization signal generation circuit (6a) is used for each television camera (1) to
(4) by supplying the synchronization signal SY to each television camera (1).
The operation timings of (4) to (4) are made to match.

On the other hand, the screen control circuit (6b) connects each television camera (1) to
The video signals Y1 to ¥4 obtained from (4) are reduced to 1/2 in the horizontal scanning period and vertical scanning period, and the video information corresponding to the four images is temporarily stored in the field memory (6c). Video information is read out in a predetermined order from the field memory (6c) to generate a video signal Y. Create. That is, the video signals Y1 to Y4 are thinned out every Jli times during the horizontal scanning period and the vertical scanning period, and are stored in the field memory (6c), and each television camera (1)
The video information corresponding to the video from (4) to (4) is read out every 1/2 period of the horizontal scanning period and every 1/2 period of the vertical scanning period to obtain the video signal Y.

For example, when displaying on the screen in four divided areas A to D as shown in FIG. 6, in the first half of the vertical scanning period, the video signal Y1 is The corresponding video information is read out, and in the second half period, the video information corresponding to the video signal Y2 is read out. Then, in the second half period of vertical scanning, the first half of horizontal scanning is read out.
reads the video information corresponding to the video signal Y3 during the period;
A video signal Y is created by reading and comparing the video information corresponding to the video signal Y4 during the latter 1/2 period of horizontal scanning. Therefore, each TV camera (1) is placed in the divided areas A to D of the playback screen.
The images from (4) to (4) are displayed simultaneously.

(c) Problems to be Solved by the Invention When configuring an imaging system as described above, it is necessary to control the operation of a plurality of television cameras (1) to (4), and also to control the video signals of each television camera (1) to (4). Video signal Y for obtaining a 4-split playback screen from Y1 to ¥4. The main controller (6) that creates the data is essential. Such a main controller (6) has a field memory (6C) that can store video information for at least 64 screens, and stores video information in this field memory (6c) and retrieves video information from the field memory (6C). In addition to requiring a large-scale circuit configuration such as a screen control circuit (6b) that compares and synthesizes readings,
There is a problem in that a plurality of lines are required to connect each of the television cameras (1) to (4), resulting in a significant increase in cost.

Therefore, an object of the present invention is to provide a solid-state imaging device that can simplify the lines for connecting the television cameras (1) to (4) and reduce the cost of the imaging system.

(d) Means for Solving the Problems The present invention has been made to solve the above-mentioned problems, and its feature is that the received image is photoelectrically converted to charge information according to the image pattern. a solid-state image sensor that stores information, a drive circuit that scans the solid-state image sensor horizontally and vertically and transfers and outputs the information charge at predetermined intervals to obtain a continuous video signal for each screen, and a television synchronization signal. and a detection circuit that respectively detects a synchronization signal and communication data from a communication line through which various communication data are transmitted; a timing control circuit that sets each scan timing of the drive circuit according to the synchronization signal; and a detection circuit that determines the content of the communication data. and a data processing circuit that changes the scanning timing of the timing control circuit according to the data content, and transmits the video signal to the communication line in synchronization with the synchronization signal.

(E) Effect According to the present invention, multiple solid-state imaging devices connected to a common communication line can be connected to a common communication line by superimposing various types of communication data for controlling the operation in a specific period of a synchronization signal and giving it to the solid-state imaging device. The imaging devices can be selectively operated, and video signals with matching scanning timing can be obtained from each solid-state imaging device. Therefore, a number of solid-state imaging devices that can be specified by communication data can be connected to the same communication line without adding any special circuit, and the line can be simplified.

Furthermore, by providing a communication data transmission circuit in the solid-state imaging device, the solid-state imaging device can also be used as a communication terminal.

(f) Example Embodiments of the present invention will be described with reference to the drawings.

FIG. 1 is a block diagram showing the configuration of the solid-state imaging device of the present invention, and FIG. 2 is a waveform diagram of each signal.

The solid-state image sensor (10) has a plurality of light-receiving elements arranged in a matrix, and stores information charges corresponding to the image pattern received. This information charge is sequentially transferred according to the transfer lock from the clock generation circuit (11), converted into a voltage value at the output section of the solid-state image sensor (10), and outputted as a video signal Y.

The video signal Y output from the solid-state image sensor (10) is sent to the communication line (20) after being subjected to signal processing such as sample hold and gain adjustment in the video signal processing circuit (13).

On the other hand, the timing control circuit (12) has a solid-state image sensor (
This is to synchronize the operation of 10) with the synchronization signal SY transmitted through the communication line (20), and the synchronization signal detection circuit (1
4) Horizontal synchronization signal from 1-5Y and vertical synchronization signal V
-5Y, the operation timing of the clock generation circuit (11) is set. Synchronous signal detection circuit (
14) detects the synchronization signal SY from the communication line (20) and separates this synchronization signal SY into a horizontal synchronization signal H-SY and a vertical synchronization signal v-5Y. That is, the synchronization signal SY transmitted through the communication line (20) is a so-called composite signal in which an equivalent pulse is mixed in addition to a horizontal synchronization pulse and a vertical synchronization pulse. The horizontal synchronizing signal (1-5Y) is obtained by removing the equivalent pulse of /2 period, and the vertical synchronizing signal vs.
I am getting y.

Further, communication data AD is transmitted to the communication line (20) together with the synchronization signal SY. This communication data AD is superimposed on a specific period of the synchronization signal SY, is detected by the communication data detection circuit (15), and is detected by the communication data processing circuit (16).
). The communication data processing circuit (16) is configured to determine the communication data AD and control the operation of the timing control circuit (12). (20)
When the address specified by the communication data AD is confirmed to match the address specified by the communication data AD, the operation of the timing control circuit (12) is permitted. This communication data AD is superimposed during a specific period outside the effective video period of the video signal Y, that is, within the blanking period of the video signal Y, and when the video data of the video signal Y and the communication data AD are They will be separated sequentially.

FIG. 3 is a block diagram showing the configuration of an imaging system using the solid-state imaging device of the present invention, and FIG. 4 is an operation timing chart thereof.

A solid-state imaging device (30) having the same configuration as in FIG.
Each is assigned an address and connected in series through a communication line (2o). In this solid-state imaging device (3o), the number of pixels of the COD (10) is set to 1/2 of the playback screen in both the horizontal and vertical directions, and the video information is set to 1/2 of the horizontal scanning period and vertical scanning period. /2 period.

A main controller (31) that controls the operation of each solid-state imaging device (30) is connected to the communication line (20), and a synchronization signal SY and communication data AD are sent onto the communication line (20). configured. Therefore, each solid-state imaging device (
30) receives the synchronization signal SY and communication data AD from the main controller (31), synchronizes with the synchronization signal SY, and operates according to the communication data AD.

That is, the communication data AD specifies the address of the solid-state imaging device (30) and also sets the output timing of video information.Up to four out of the plurality of solid-state imaging devices (30) are designated, and each The solid-state imaging devices (30) are configured to output video information at different timings.

The operation timing of the solid-state imaging device (30) is shown in FIG.
) As shown in (B), two horizontal scanning timing signals H-5T and H-3 follow the horizontal synchronizing signal H-5Y.
T2 and one of two vertical scanning timing signals V-5T and V-5T2 according to the vertical synchronization signal v-sy. These horizontal scanning timing signals H-5T1 and HST2 and vertical scanning timing signal V-
5T and V-3T2, one of which is selected according to the communication data AD, and the horizontal scanning timing signal H-5T2 is 1/2 of the horizontal scanning period with respect to the horizontal scanning timing signal H-ST. (H/2) period delay, the vertical scanning timing signal V-ST2 is set to be delayed by 1/2 (V/2) period of the vertical scanning period with respect to the vertical scanning timing signal VST. This selection of the scanning timing signal is performed in the timing control circuit (12) based on the output of the communication data processing circuit (16), and for example, by decoding the output of a counter that is reset by a synchronization signal. The decoded value of the decoder that obtains each scanning timing is set according to the content of the communication data AD determined by the communication data processing circuit (16).

Then, a video signal Y on which video signals from up to four solid-state imaging devices (30) specified by the main controller (31) are superimposed is input to the main controller (31) and connected to the main controller (31). Images from a predetermined solid-state imaging device (30) are simultaneously displayed on a television monitor (32).

Therefore, the image from the solid-state imaging device (30) specified by the communication data AD is displayed on the screen of the television monitor (32) at the position specified by the communication data AD. Then, the solid-state imaging device (30) is selected by changing the address of the communication data AD, and four or more solid-state imaging devices (30) can be connected.

FIG. 5 is a block diagram showing the configuration of a communication system using the solid-state imaging device of the present invention.

Each solid-state imaging device (40) is equipped with a transmitting/receiving circuit (17) that exchanges data with the communication line (20). (20). In addition to determining the communication data AD from the communication data detection circuit (15), the communication data processing circuit (16) also performs predetermined processing on the communication data AD and then superimposes it on the video signal Y. It is output to the communication line (20) via the transmitter/receiver circuit (17).

That is, the solid-state imaging device (40) has a transmission function in addition to a reception function of communication data AD, and works as a communication terminal.
In this way, if the solid-state imaging device (40) that operates in synchronization with the common synchronization signal SY is used as a communication terminal, data can be received and received by adjusting the timing between the transmitting side and the receiving side at the same time. There will be no need to do so.

As this communication data AD, for example, a pi-phase code in which data is inverted for each bit is used, and a synchronization signal SY is used.
Data transmission is performed according to the basic clock for creating. In this case, 910 bins) (NTS
In the case of C method) data can be transmitted.

In addition, in this embodiment, the case where the playback screen is divided into four and the video is displayed is exemplified, but CO
Alternatively, the playback screen can be divided into 9 or The video can be divided into 16 parts and displayed.

(G) Effects of the Invention According to the present invention, it is possible to connect a large number of solid-state imaging devices according to the address indicated by communication data without increasing the circuit configuration, and it is possible to configure a large-scale imaging system at extremely low cost. .

Further, the solid-state imaging device can also be used as a communication terminal, and video information and communication data can be transmitted using the same communication line, thereby simplifying the communication line. Moreover, since the operations of each solid-state imaging device are synchronized with a common synchronization signal, there is no need to match the timing between the transmitting side and the receiving side when transmitting communication data.
Data can be easily transferred between each solid-state imaging device.

[Brief explanation of the drawing]

FIG. 1 is a block diagram of the solid-state imaging device of the present invention, FIG. 2 is a waveform diagram of a synchronizing signal, FIG. 3 is a block diagram of an imaging system using the solid-state imaging device of the present invention, and FIG. 4 is the operation of FIG. 3. FIG. 5 is a block diagram of a communication system using the solid-state imaging device of the present invention, FIG. 6 is a block diagram of a conventional imaging system, and FIG. 7 is a waveform diagram of a synchronization signal. (1) to (4) - TV camera, (5) TV monitor, (6) - Main controller, (1o) CO
D solid-state image sensor, (11) clock generation circuit, (
12) - timing control circuit, (13) - video signal processing circuit, (14) ... synchronization signal detection circuit, (15)
Communication data detection circuit, (16) - Communication data processing circuit, (17) - Transmission/reception circuit, (20) - Communication line, (30) (40) - Solid-state imaging device, (31) - Main controller, (32) )...-TV monitor.

Claims (3)

[Claims] (1) A solid-state image sensor that photoelectrically converts the received image and stores information charges according to the image pattern, and scans this solid-state image sensor in the horizontal and vertical directions to transfer and output the information charges at predetermined intervals. , a drive circuit that obtains a continuous video signal for each screen; a detection circuit that detects the synchronization signal and communication data from a communication line through which the television synchronization signal and various communication data are transmitted; a timing control circuit that sets each scan timing; and a data processing circuit that determines the content of the communication data and changes the scan timing of the timing control circuit according to the data content, and the video image synchronized with the synchronization signal. A solid-state imaging device characterized in that it sends a signal to the communication line. (2) The solid-state imaging device according to claim 1, further comprising a transmitting circuit that superimposes various communication data on a specific period of the video signal and sends the superimposed data to the communication line. (3) The light-receiving surface of the solid-state image sensor has a pixel count equal to 1/n (n>1) of the reproduction screen in the horizontal and vertical directions, and the timing at which the information charge accumulated in the solid-state image sensor follows the communication data 2. The solid-state imaging device according to claim 1, wherein the image is transferred and output during a period of 1/n of a horizontal scanning period and a vertical scanning period.