JPH0673964U - CCD camera device - Google Patents

Abstract

(57) [Abstract] [Purpose] Reliability that can reduce the number of connecting cables, prevent generation of unnecessary radio waves, and can arbitrarily change the cable length,
To realize a highly versatile CCD camera device. [Structure] The head unit 1 is provided with a horizontal synchronizing signal HD for driving a CCD.
₁ and a CCD drive / synchronization signal generation circuit 14 for generating the vertical synchronization signal VD ₁ are provided, and the control unit 2 is synchronized with the CCD drive / synchronization signal generation circuit 14 via a PLL circuit 25 or the like to perform image processing. An image processing signal generating circuit 26 for generating a color sampling pulse and a clamp pulse, which are signals for use in the image processing, is provided. As a result, the head unit 1 and the control unit 2
The signal supply lines of the connection cable 3a for connecting between the four power supply lines 31 including the ground line, one signal supply line 35 for the video signal IM, the horizontal synchronization signal HD ₁ and the vertical synchronization signal VD. ₇ with 2 signal supply lines 37 of ₁ .

Description

[Detailed description of the device]

[0001]

[Industrial applications]

 The present invention relates to a CCD camera device using a CCD (Charge Coupled Device) image sensor, and in particular, a CCD in which a head unit in which the CCD image sensor is arranged and a control unit including a video signal processing system are separated. The present invention relates to a camera device.

[0002]

[Prior art]

 FIG. 2 is a block diagram showing a configuration example of a conventional CCD camera device in which a head unit and a control unit are separated. In FIG. 2, 1 is a head section, 2 is a control section, and 3 is a connection cable.

In this CCD camera device, a head unit 1 is composed of a CCD image pickup device 11, a CCD drive circuit 12, and a correlated double sampling (CDS) circuit 13, and a control unit 2 is It is composed of a synchronization signal generation circuit 21 and a process encoder circuit 22 as a video signal processing system. The head unit 1 and the control unit 2 are connected by a connection cable 3 between the two circuits. A drive signal, a video signal, and the like are exchanged via the connection cable 3.

As shown in FIG. 2, the connection cable 3 includes four power supply lines 31 including one ground line and a horizontal synchronization signal as lines for supplying a signal from the control unit 2 to the head unit 1. HD and two signal supply lines 32 for the vertical synchronizing signal VD are provided. On the other hand, as a line for supplying a signal from the head unit 1 to the control unit 2, four or five video processing signal supply lines 33 such as color sampling pulses and clamp pulses, and one basic clock signal. A CLK supply line 34 and a single video signal IM supply line 35 are provided.

In such a configuration, when the camera is used, when a power switch (not shown) is turned on, predetermined power is supplied to each circuit of the control unit 2 and also via the power supply line 31 of the connection cable 3. It is supplied to the head unit 1. In this state, the basic clock signal CLK is generated by the CCD driving circuit 12 of the head unit 1 and sent to the synchronizing signal generating circuit 21 of the control unit 2 via the signal supply line 34. In the sync signal generation circuit 21, a horizontal sync signal HD and a vertical sync signal VD for driving the CCD are generated and sent to the CCD drive circuit 12 of the head section 1 via the signal supply line 32, and the sync signal is processed. -It is output to the encoder circuit 22.

In the CCD drive circuit 12, a drive pulse (normally 7 pulses) DR for the CCD image pickup device 11 is generated and output to the CCD image pickup device 11, and a sampling signal is generated and supplied to the CDS circuit 13. It Further, in the CCD drive circuit 12, a color sampling pulse and a clamp pulse which are video processing signals are generated, and these pulses are sent to the process encoder circuit 22 of the control unit 2 via the signal supply line 33. It

In the CCD image pickup device 11 which receives the drive pulse from the CCD drive circuit 12, an optical image received through an image pickup lens (not shown) is photoelectrically converted, and this electric signal ES is output to the CDS circuit 13. In the CDS circuit 13, only the video signal IM is extracted from the input electric signal based on the sampling signal from the CCD drive circuit 12, and the video signal IM is transmitted via the signal supply line 35 to the process encoder circuit 22 of the control unit 2. Sent to.

The process encoder circuit 22 performs predetermined signal processing on the video signal IM based on the input color sampling pulse, clamp pulse and synchronizing signal, for example, color demodulation processing, clamp processing, white / dark clip processing and the like. Then, the output video signal is obtained.

FIG. 3 is a block diagram showing another configuration example of the conventional CCD camera device. This device is different from the device shown in FIG. 2 in order to further simplify the structure of the head unit 1, only the CCD image pickup device 11 is arranged in the head unit 1, and the CCD drive circuit 12 and the CDS circuit 13 are arranged. It is arranged on the control unit 2 side. In this configuration, it is necessary to arrange the delay circuit 23 in the control unit 2 to correct the round trip delay of the connection cable 3.

The connection cable 3 in this case is composed of four power supply lines 31, one supply line 35 of the video signal IM, and seven CCD drive pulse DR supply lines 36.

[0011]

[Problems to be solved by the device]

 However, in the above-mentioned conventional CCD camera device, the former device requires 12 to 13 connection cables and the latter device requires 12 connection cable lines, so that there is a problem that the cable cost including the connector is high. . Further, since high frequency pulse transmission such as the basic clock signal CLK or the CCD drive pulse DR is required, there are problems such as generation and reflection of unnecessary radio waves from the cable. A method such as shielding may be considered to prevent this, but this will double the number of cable lines.

Further, in the latter device, since the delay circuit 23 for correcting the delay for the round trip of the cable is required, it is difficult to change the cable length after once setting and adjusting the cable length, There are also problems such as poor versatility.

The present invention has been made in view of the above circumstances, and an object thereof is to reduce the number of connection cable lines, to prevent generation of unnecessary radio waves because transmission of high frequency pulses is unnecessary, and to prevent signal delay. It is an object of the present invention to provide a highly reliable and versatile CCD camera device in which the cable length can be arbitrarily changed without the need for correction.

[0014]

[Means for Solving the Problems]

 In order to achieve the above object, in the present invention, a CCD camera in which a head section in which a CCD image pickup device is arranged and a control section having a video signal processing system are separated, and signals are exchanged between them by a connection cable. A device for driving a CCD, which generates a synchronizing signal and a driving signal for driving the CCD image pickup element, supplies the driving signal to the CCD image pickup element, and sends the synchronizing signal to the control section. A sync signal generation circuit is provided, and a video processing signal generation circuit that generates a video processing signal synchronized with the sync signal by the CCD drive / sync signal generation circuit and supplies it to the video signal processing system is provided to the control unit. Provided.

[0015]

[Action]

 According to the present invention, the connection cables for connecting the head unit and the control unit are only the power supply line, the video signal supply line from the head unit to the control unit, and the synchronization signal supply line. A synchronization signal is generated in the CCD drive / synchronization signal generation circuit of the head section, is sent to the control section via the connection cable, and the drive signal is supplied to the CCD image pickup device. In the CCD image pickup device, the optical image received through the image pickup lens is photoelectrically converted based on the drive signal, and the video signal which is this electric signal is sent to the video signal processing system of the control section through the connection cable. Further, in the control section, the video processing signal generating circuit generates a video processing signal in synchronization with the synchronizing signal from the head section and outputs it to the video signal processing system. As a result, the video signal processing system performs predetermined video processing on the video signal from the head section.

[0016]

FIG. 1 is a block diagram showing an embodiment of a CCD camera device according to the present invention. The same components as those of FIG. 2 showing a conventional example are represented by the same reference numerals. That is, 1a is a head part, 2a is a control part, and 3a is a connection cable.

The head unit 1 is composed of a CCD image pickup device 11, a CDS circuit 13, and a CCD drive / synchronization signal generation circuit 14. The CCD drive / synchronization signal generation circuit 14 generates a horizontal synchronization signal HD ₁ and a vertical synchronization signal VD ₁ for driving the CCD and sends them to the control section 2 through the signal supply line 37, and also the CCD image pickup device. A driving pulse (normally 7 pulses) DR 11 is generated and output to the CCD image pickup device 11, and a sampling signal is generated and supplied to the CDS circuit 13.

The control unit 2 includes a process encoder circuit 22, a synchronization signal generation circuit 24, a PLL (Phase Locked Loop) circuit 25, and a video processing signal generation circuit 26. The synchronization signal generation circuit 24 receives the vertical synchronization signal VD ₁ from the CCD drive / synchronization signal generation circuit 14 of the head unit 1 and is reset, and also generates the horizontal synchronization signal HD ₂ and the vertical synchronization signal VD ₂ . The horizontal synchronizing signal HD ₂ is output to the PLL circuit 25, and the vertical synchronizing signal VD ₂ is output to the video processing signal generating circuit 26. The PLL circuit 25 is composed of a VCO, a phase comparator, an LPF, etc., and based on the result of phase comparison between the horizontal synchronizing signal HD ₁ by the head unit ₁ and the horizontal synchronizing signal HD ₂ by the synchronizing signal generating circuit 24, a reference clock signal CLK. _B is generated and output to the video processing signal generation circuit 26. The video processing signal generation circuit 26 outputs the basic clock signal CLK to the synchronization signal generation circuit 24, and receives the vertical synchronization signal VD _{2 from the} synchronization signal generation circuit 24 and the reference clock signal CLK _B from the PLL circuit 25. A color sampling pulse and a clamp pulse, which are video processing signals, are generated, and these pulses are output to the process encoder circuit 22.

The connection cable 3a is provided with four power supply lines 31 including one ground line as lines for supplying a signal from the control unit 2 to the head unit 1. On the other hand, as a line for supplying a signal from the head unit 1 to the control unit 2, one video signal supply line 35, a horizontal synchronization signal HD ₁ generated by the CCD drive / synchronization signal generation circuit 14 and a vertical synchronization signal HD _{1 are} generated. Two signal supply lines 37 for the sync signal VD ₁ are provided. That is, the total number of cable lines of the connection cable 3a is seven.

Next, the operation of the above configuration will be described. When a power switch (not shown) is turned on during use of the camera, predetermined power is supplied to each circuit of the control unit 2 and also to the head unit 1 via the power supply line 31 of the connection cable 3a. In this state, the horizontal sync signal HD ₁ and the vertical sync signal VD ₁ are generated by the CCD drive / sync signal generation circuit 14 of the head unit 1 and sent to the control unit 2 via the signal supply line 37, and the horizontal sync signal HD ₁ is input to the PLL circuit 25, and the vertical synchronizing signal VD ₁ is input to the reset terminal RST of the synchronizing signal generating circuit 24. Further, the basic clock signal CLK is generated by the video processing signal generation circuit 26 of the control unit 2 and input to the synchronization signal generation circuit 24.

In the synchronizing signal generation circuit 24, the horizontal synchronizing signal HD₂And vertical sync signal VD₂Is generated and the horizontal sync signal HD₂Is output to the PLL circuit 25, and the vertical synchronizing signal VD ₂ Is output to the video processing signal generation circuit 26. In the PLL circuit 25, the horizontal sync signal HD generated by the CCD drive / sync signal generation circuit 14 of the head unit 1₁And the horizontal synchronizing signal HD by the synchronizing signal generating circuit 24₂Phase comparison with the reference clock signal CLK based on the result._BIs generated and output to the video processing signal generation circuit 26. As a result, the CCD drive / synchronization signal generation circuit 14 of the head unit 1 and the image processing signal generation circuit 26 of the control unit 2 are synchronized.

In the CCD drive / synchronization signal generation circuit 14 of the head unit 1, a driving pulse DR for the CCD image pickup device 11 is generated and output to the CCD image pickup device 11, and a sampling signal is generated to generate the CDS circuit 13. Is supplied to.

In the CCD image pickup device 11 which receives the drive pulse DR from the CCD drive / synchronization signal generation circuit 14, the optical image received through the image pickup lens (not shown) is photoelectrically converted, and this electric signal ES is sent to the CDS circuit 13. Is output. In the CDS circuit 13, only the video signal IM is extracted from the input electric signal based on the sampling signal by the CCD drive / synchronization signal generation circuit 14, and the video signal IM is passed through the signal supply line 35 to the process encoder of the control unit 2. It is sent to the circuit 22.

On the other hand, in the video processing signal generation circuit 26 of the control unit 2 which is synchronized with the CCD drive / synchronization signal generation circuit 14 of the head unit 1, the color sampling pulse and the clamp pulse which are the video processing signals are supplied. The generated pulses are output to the process encoder circuit 22. The process encoder circuit 22 performs predetermined signal processing on the video signal IM, for example, color demodulation processing, clamp processing, white / dark clip processing, etc., based on the input color sampling pulse, clamp pulse, and synchronizing signal. An output video signal is obtained.

Although the video signal IM is delayed by the connection cable 3a, since the horizontal synchronizing signal HD ₁ and the vertical synchronizing signal VD ₁ are also delayed in the same manner, the pulse generated by the control unit 2 is All of them are in timing with the video signal IM. As a result, a circuit for delay correction is unnecessary.

As described above, according to this embodiment, the head portion 1 is provided with the CCD drive / synchronization signal generation circuit 14 for generating the horizontal synchronization signal HD ₁ and the vertical synchronization signal VD ₁ for driving the CCD. The control unit 2 is synchronized with the CCD drive / synchronization signal generation circuit 14 via a PLL circuit 25, etc., and generates a video processing signal generation signal for generating a color sampling pulse and a clamp pulse which are video processing signals. Since the circuit 26 is provided, the signal supply line of the connection cable 3a for connecting the head unit 1 and the control unit 2 has four power supply lines 31 including a ground line and a video signal IM. Only _one signal supply line 35 and two signal supply lines 37 for the horizontal synchronizing signal HD ₁ and the vertical synchronizing signal VD ₁ are required. Therefore, the number of connectors and the like are also reduced, so that the cost can be reduced, and since the high frequency pulse such as the drive pulse DR and the basic clock signal CLK is not transmitted, the problem or reflection of unwanted radio waves due to the connection cable 3a can be avoided. Problems can be resolved. Further, since the delay time due to the connection cable 3a is automatically canceled, there is an advantage that the degree of freedom of the cable length is increased.

[0027]

[Effect of device]

 As described above, according to the present invention, it is possible to reduce the total number of connecting cable lines, and eventually to reduce the cost. In addition, it does not transmit high-frequency pulses such as drive pulses or basic clock signals, so problems such as unwanted radio waves and reflections from connection cables can be eliminated. Furthermore, since the delay time due to the connecting cable is automatically canceled, there is an advantage that the flexibility of the cable length increases.

[Brief description of drawings]

FIG. 1 is a block diagram showing an embodiment of a CCD camera device according to the present invention.

FIG. 2 is a block diagram showing a configuration example of a conventional CCD camera device.

FIG. 3 is a block diagram showing another configuration example of a conventional CCD camera device.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 ... Head part 11 ... CCD image pick-up element 13 ... CDS circuit 14 ... CCD drive / synchronization signal generation circuit 2 ... Control part 22 ... Process encoder circuit 24 ... Synchronization signal generation circuit 25 ... PLL circuit 26 ... Video processing signal generation circuit

Claims (1)

[Scope of utility model registration request] 1. A CCD camera device in which a head portion in which a CCD image pickup device is arranged and a control portion having a video signal processing system are separated, and a signal is exchanged between them by a connection cable. Drive unit for generating a sync signal and a drive signal for driving the CCD image pickup device, supplying the drive signal to the CCD image pickup device, and sending the sync signal to the control unit
A synchronization signal generation circuit is provided, and the control section is provided with a video processing signal generation circuit that generates a video processing signal synchronized with the synchronization signal by the CCD drive / synchronization signal generation circuit and supplies the video processing signal to the video signal processing system. A CCD camera device characterized in that