JPH01255382A - Camera system - Google Patents

Abstract

PURPOSE:To execute the coincidence of the phase of a video signal to be transmitted and a former synchronizing signal by re-transmitting the transmitted synchronizing signal to a master device and controlling a phase control circuit so as to cause it to coincide with the phase of the former synchronizing signal. CONSTITUTION:A horizontal synchronizing signal HD is generated from a synchronizing signal generating circuit 18 of a camera head unit 2, the signal is supplied to a delaying circuit 22, and the delayed horizontal synchronizing signal HD is generated. The delayed signal and a pulse signal HD' from a correcting circuit 19 are supplied to a phase comparing circuit 20, the compared output is supplied to a variable oscillator 21, and the phase of the generating circuit 18 is controlled so that the phases (rising phases) of two signals can coincide. Thus, for the video signal generated based on synchronizing signals VD and HD from the generating circuit 18, the phase of the signal transmitted in a transmission line 3 is made to coincide with the phase of the synchronizing signal from a generating circuit 12, and the satisfactory processing of the video signal can be easily executed.

Description

DETAILED DESCRIPTION OF THE INVENTION [Field of Industrial Application] The present invention relates to a camera system in which, for example, an imaging section and a control section are separated.

[Summary of the invention]

The present invention relates to a camera system that transmits a synchronization signal from a synchronization signal generation circuit of a master device to a slave device via a phase control circuit, and based on the synchronization signal from the synchronization signal generation circuit that is synchronized with the transmitted synchronization signal. to form a video signal and transmit it to the master device, and also retransmit the transmitted synchronization signal to the master device, and a phase control circuit so that the retransmitted synchronization signal and the original synchronization signal match in phase. By controlling the synchronization signal, the phase of the transmitted video signal matches the original synchronization signal.

[Conventional technology]

For example, there is a camera system in which an imaging unit (camera head unit: CHU) that forms a video signal and a control unit (camera control unit: CCU) that processes the video signal are separated.

In such a camera system, the imaging unit and the control unit are each provided with a synchronization signal generation circuit, and the synchronization signal from the synchronization signal generation circuit controls internal circuits such as forming and processing the respective video signals. It looks like this.

Therefore, when using such a camera system, it is necessary to synchronize the synchronization signal generating circuits. That is, in order for the control section to process the video signal formed by the imaging section, the phase of the video signal transmitted from the imaging section to the control section must match the synchronization signal of the control section.

Therefore, since the control section is generally connected to other external devices, the control section is set as a master device, the imaging section is set as a slave device, and the synchronization signal generation circuit of the imaging section is synchronized with the synchronization signal generation circuit of the control section. was.

[Problem to be solved by the invention]

However, in the camera system described above, signal transmission between the imaging unit and the control unit is usually performed via a transmission line such as a multi-core cable, and such a transmission line generally has a signal delay effect. There is. Therefore, when the synchronization signal generation circuit of the control section synchronizes the synchronization signal generation circuit of the imaging section by transmitting the synchronization signal from the synchronization signal generation circuit of the control section to the imaging section as described above, the synchronization signal generation circuit of this imaging section is connected to the transmission line. The video signal is delayed and synchronized by the delay effect, and the video signal formed based on the synchronization signal from the synchronization signal generation circuit is transmitted to the control unit via the transmission line, so that the video signal has two This will cause twice as much delay.

In this case, it is extremely difficult to process such delayed and out-of-phase video signals, and a large-scale circuit is required for processing.

In contrast, in the past, a phase adjustment means was provided in the synchronization signal generation circuit of the imaging unit to generate a synchronization signal whose phase was advanced by a time corresponding to the delay of the transmission line with respect to the synchronization signal transmitted from the control unit. By forming a video signal based on this synchronization signal, the phase of this video signal when transmitted via the transmission line matches the synchronization signal of the control section.

However, in this method, when the length of the transmission line is changed or the amount of delay of the transmission line is changed due to temperature characteristics or the like, it is necessary to readjust the above-mentioned phase adjustment means.

In that case, extremely high precision is required for this readjustment,
It is necessary to prepare a special measuring device for this adjustment. Therefore, it is not easy to make such adjustments, and the transmission line is usually used in a fixed manner after being adjusted. Furthermore, it is extremely difficult to follow and adjust the temperature characteristics, and in the past, only short transmission lines that were not affected by the temperature characteristics could be used.

Furthermore, providing a phase adjustment means has been an extremely serious problem in reducing the size and weight of the imaging section.

This application was filed in view of these points.

[Means to solve the problem]

The present invention includes a first synchronizing signal generating circuit (12) and a first synchronizing signal generating circuit (12).
A phase control circuit (monomulti (14)'') that controls the phase of the synchronization signal from the synchronization signal generation circuit of the slave device (C
a master device (CCU (1)) having transmission means (13) (16) for transmitting to the HU (2)); and a master device (CCU (1)) that receives a synchronization signal transmitted by the transmission line and synchronizes with the transmitted synchronization signal. a second synchronization signal generation circuit (18);
A video circuit (CCD (24R) (2) that forms a video signal based on the synchronization signal from the second synchronization signal generation circuit
4G) (24B> ), a transmission means for transmitting the output of the video circuit to the master device via the transmission line, and a synchronous signal transmitted by the transmission line to the master device via the transmission line. and a retransmission means (32) for retransmitting, the slave device compares the phase of the synchronization signal retransmitted by the transmission line and the synchronization signal from the first synchronization signal generation circuit, and detects the phase. A phase comparator circuit (
34), a video processing circuit (process circuit (27)) that processes the video signal transmitted by the transmission line, and mixes the output of the video processing circuit with the synchronization signal from the first synchronization signal generation circuit. This camera system is characterized in that the master device is provided with a mixing circuit (29) that performs the following.

[Effect]

According to this, by matching the phase of the retransmitted synchronization signal and the synchronization signal from the first synchronization signal generation circuit, the phase of the transmitted video signal can be synchronized from the first synchronization signal generation circuit. It is possible to match the signal and perform good video signal processing.

〔Example〕

In Figure 1, the diagram shows the entire camera system, and the right side of the drawing shows the camera control unit (CCU) (L) (L) (L) as the master device, and the camera head unit (CHU) (2) as the haslep device on the left side. These are connected via a transmission line (3).

This CCU (1) is provided with a first synchronization signal generation circuit (12) driven by a reference oscillator (11),
The vertical synchronizing signal VD from the generating circuit (12) is transmitted to the transmission line (3) through the output circuit (13) as a transmission means. Further, the horizontal synchronizing signal HD from the generation circuit (12) is supplied to a variable monomulti (14) which serves as a phase control circuit, and the signal from this monomulti (14) is used to form a predetermined pulse signal HD'. Mono multi (15)
The signal from this monomulti (15) is sent to the transmission line (3) through the output circuit (16) as a transmission means.
transmitted to.

On the other hand, in C) I tJ (2), the transmission line v6 (3
), the vertical synchronization signal VD transmitted through the waveform shaping etc. correction circuit (17) is sent to the second synchronization signal generation circuit (17).
8). Further, the pulse signal HD' transmitted through the transmission line (3) is supplied to the phase comparison circuit (20) through the correction circuit (19), and the comparison output is supplied to the variable oscillator (21), and this oscillation signal is sent to the generation circuit. (18
). Furthermore, the horizontal synchronization signal HD from the generation circuit (18) is supplied to the phase comparison circuit (20) through a predetermined delay circuit (22).

As a result, the generation circuit (18) is synchronized with the transmitted vertical synchronization signal VD and pulse signal HD'.

The vertical synchronization signal VD and horizontal synchronization signal HD from this generation circuit (18) are supplied to the timing generation circuit (23), and a vertical shift clock φ and a horizontal shift clock φH synchronized with the synchronization signals VD, )iD are generated. be done. This clock φV is the CCD (24R) as a video circuit.
(24G) (24B) and the clock φ□ is supplied to the CCD output register (25R) (25G)
(25B) and the generated video signal is extracted.

This video signal is connected to a sample hold circuit (26R).
) (26G) (260), and the sampling pulse from the generation circuit (23) is supplied to this circuit.

This sampled video signal is transmitted to the transmission line (3).

Furthermore, in the CCU (1), the video signal transmitted through the transmission line (3) is supplied to a process circuit (27) that performs processing such as T correction and white clipping, and this processed signal is supplied to an encoder (28). A predetermined composite signal is formed. This composite signal is supplied to the mixing circuit (29),
Further, the vertical synchronization signal VD and horizontal synchronization signal HD from the generation circuit (12) are combined in the blanking generation circuit (30) and supplied to the mixing circuit (29), and the mixed composite video signal is sent to the output terminal (31). It is taken out.

In this device, the correction circuit (1) of the CHU (2)
The pulse signal HD' from 9) is retransmitted to the transmission line (3) through the output circuit (32). Also, C CU (1
), the pulse signal HD' retransmitted through the transmission line 1/8 (3) is supplied to the phase comparator circuit (34) through the correction circuit (33). More outbreaks! The horizontal synchronizing signal HD from (12) is supplied to the comparator circuit (34) through a predetermined delay circuit (35) that is approximately equal to the delay amount of the delay circuit (22). And this comparison output is mono-multi (14)
is supplied to control the delay amount (phase) of the monomulti.

Therefore, in this device, the synchronization signal generation circuit (12) of the CCU (1) generates a horizontal synchronization signal HD as shown in FIG.
(15), a pulse signal HD' as shown in FIG. B is formed through the output image m (16) and transmitted to the transmission line (3). As a result, from the correction circuit (19)
As shown in FIG.
' is extracted, this signal is further transmitted to the transmission line (3), and a pulse signal HD' as shown in the figure is extracted from the correction circuit (33).

Further, the horizontal synchronization signal HD from the generation circuit (12) is supplied to the delay circuit (35) to form a delayed horizontal synchronization signal HI as shown in FIG. This delayed signal and the above-mentioned retransmitted signal are supplied to a phase comparison circuit (34), and this comparison output is supplied to a monomulti (14) so that the phases (rising phases) of these two signals match. The delay amount of the monomulti (14) is controlled.

On the other hand, the synchronization signal generation circuit (18) of the CHU (2) generates a horizontal synchronization signal HD as shown in FIG. A delayed horizontal synchronization signal HD is formed. This delayed signal and the pulse signal HD' from the above-mentioned correction circuit (19) are supplied to a phase comparison circuit (20), and this comparison output is supplied to a variable oscillator (21). ) is controlled so that the phase of the generating circuit (18) is matched.

As a result, from the generation circuit (18), the correction circuit (19)
) from the pulse signal HD' from the delay circuit (22) are generated, and the horizontal synchronization signal HD from the force generating circuit (12) is generated from the pulse signal HD' from the delay circuit (3).
Since the signal delayed in step 5) and the pulse signal HD' from the correction circuit (19) are transmitted through the transmission line (3) and the delayed signals are in phase, the generation circuit (18)
The video signal generated based on the synchronization signals VD and HD from the generator circuit (3) was transmitted through the transmission line (3), and the phase of the signal matched the phase of the synchronization signal from the generation circuit (12), as shown in H in the same figure. This makes it possible to easily process good video signals.

In this way, according to the above-mentioned device, by matching the phases of the retransmitted synchronization signal and the synchronization signal from the first synchronization signal generation circuit, the phase of the transmitted video signal is changed to the first synchronization signal.
It is possible to match the synchronizing signal from the synchronizing signal generating circuit of the present invention, and it is possible to perform good video signal processing.

In addition, in the above-mentioned device, the delay circuit (22) (35)
Since control by the monomulti (14) is performed only in the delay direction, the reference signal is delayed to enable control in the phase advance direction, and the amount of delay is determined by the amount of delay transmitted back and forth through the transmission line (3). Maximum delay when it (approximately 3μ5ec at 300m
) is assumed to be a larger value. Furthermore, this delay circuit (22)
In principle, the delay amounts in (35) are assumed to be equal, but
If there is a signal delay specific to another circuit system, the delay circuit (22) (35) can absorb the difference.

Furthermore, in the above-mentioned device, control is performed following changes in the amount of delay due to transmission, so that control can be performed not only in accordance with the length of the transmission line (3) but also in accordance with temperature characteristics. Furthermore, the device can be made with high accuracy without any adjustment, and C
Since almost no extra circuit devices are provided in the HU (2), there is no obstacle to downsizing the slave device.

Furthermore, FIGS. 3 and 4 show the configuration of other examples.

Note that the video signal system in these figures is omitted because it is the same as described above.

First, in Fig. 3, a synchronization signal generation circuit (41) is used as a slave instead of the monomulti (14) (15), and the vertical synchronization signal VD from the synchronization signal generation circuit (12) is sent to the reset signal generation circuit ( 42) to the generating circuit (41). Also, the horizontal synchronization signal HD from the generation circuit (12)
The phase comparison circuit (43) compares the phase of the retransmitted horizontal synchronization signal from the correction circuit (33), and this comparison output is supplied to the variable oscillator (44), and this oscillation signal is sent to the generation circuit (41). Supplied. Furthermore, the vertical synchronization signal VD and horizontal synchronization signal IID from the generation circuit (41) are transmitted to the transmission line (3) through the output circuits (13) and (16). The configurations of other CHU (2) etc. are similar to the above example.

This also allows the same control as described above to be performed.

In this case, the synchronizing signal generating circuit (41) can also control the phase advance direction, so the delay circuit (22) (3
5) becomes unnecessary.

Furthermore, FIG. 4 shows that the composite synchronization signal 5ync from the synchronization signal generation circuit (41) is passed through the transmission line (51) through the output circuit (51).
3), the number of transmission lines (3) is reduced by one. In this case, CHU (
In 2), the vertical synchronization signal VD and the horizontal synchronization signal HD are generated from the transmitted composite synchronization signal 5sync in the correction separation circuit (52).
By correcting and separating, the same effect as described above can be obtained.

〔Effect of the invention〕

According to this invention, by matching the phases of the retransmitted synchronization signal and the synchronization signal from the first synchronization signal generation circuit, the phase of the transmitted video signal can be adjusted to match the phase of the retransmitted synchronization signal and the synchronization signal from the first synchronization signal generation circuit. It is now possible to match the synchronization signal and perform good video signal processing.

[Brief explanation of the drawing]

FIG. 1 is a configuration diagram of one example of the present invention, FIG. 2 is a diagram for explaining the same, and FIGS. 3 and 4 are configuration diagrams of other examples. (1) is the camera control unit, (2) is the camera head unit, (3) is the transmission line, (12)
(18) is a synchronization signal generation circuit, (14) (15) is a monomulti, (20) (34) is a phase comparison circuit, (21)
) is a variable oscillator, (22) (35) is a delay circuit, (2
4) is a CCD, (27) is a process circuit, and (29) is a mixed circuit.

Claims (1)

[Scope of Claims] A first synchronization signal generation circuit, a phase control circuit that controls the phase of the synchronization signal from the first synchronization signal generation circuit, and an output of the phase control circuit as a slave via a transmission line. a master device having a transmission means for transmitting data to the device; a second synchronization signal generation circuit that receives the synchronization signal transmitted by the transmission line and synchronizes with the transmitted synchronization signal; and the second synchronization signal generation circuit. a video circuit that forms a video signal based on a synchronization signal from the circuit; a transmission means that transmits the output of the video circuit to the master device via the transmission line; and a retransmission means for retransmitting the synchronization signal to the master device via the transmission line, and transmitting the synchronization signal retransmitted by the transmission line and the synchronization signal from the first synchronization signal generation circuit. a phase comparison circuit that compares phases and controls the phase control circuit with the phase comparison output; a video processing circuit that processes the video signal transmitted by the transmission line; and an output of the video processing circuit and the first synchronization. A camera system characterized in that the master device is provided with a mixing circuit that mixes the synchronization signal from the signal generation circuit.