JP2004096547A - Television camera system - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a television camera system capable of easily preventing a malfunction of a switch for constant-current switching. <P>SOLUTION: A constant-current value detecting circuit 32 detects a value of a constant current I supplied from a power source part 4A; and when a higher value among two kinds of high and low constant current values is detected, a time-constant circuit composed of a diode 33, a capacitor 34, a resistor 35 and a voltage comparator 36 turns off an electronic switch 30, whereby the power source of a camera 1A is repeatedly turned on and off, and the fact of the repetition can be recognized on a screen of a monitor. <P>COPYRIGHT: (C)2004,JPO

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to a television camera system of a type in which power is supplied from a power supply unit to a camera via a coaxial cable for transmitting a video signal, and more particularly to a television camera system suitable for monitoring.
[0002]
[Prior art]
Conventionally, television cameras have been used for various types of monitoring. At this time, since the construction is simple and can be installed at low cost, the camera power is superimposed on a line such as a coaxial cable for transmitting video signals. The so-called single-cable television camera system has been widely used in recent years.
[0003]
FIG. 7 shows an example of a conventional single-cable television camera system using a camera (television camera) 1, a power supply separation unit 2, a coaxial cable 3, and a power supply unit 4. The DC power of the voltage V1 is supplied to the camera 1 through the coaxial cable 3.
[0004]
In this case, first, the video signal S output from the camera 1 is supplied to the terminal 6 via the capacitor 5 for AC coupling, and then transmitted to the terminal 7 of the power supply unit 3 via the coaxial cable 3.
[0005]
The signal is supplied from the terminal 7 to the video output connector 10 via the AC coupling capacitor 8 and the amplifier 9, and is connected to a video monitor (not shown).
[0006]
On the other hand, the power supply unit 4 has a constant current circuit composed of a current determining resistor 11 and a transistor 12, and thereby, for example, a DC power supply V of a voltage of 35 V. _CC Supplies a constant current I to the power supply separation unit 2 on the camera side via the terminal 7 and the coaxial cable 3. At this time, the capacitor 5 on the camera side and the capacitor 8 on the power supply side block the DC voltage, respectively. DC is not applied to unnecessary portions.
[0007]
As a result, the constant voltage I1 supplied from the power supply unit 4 is converted to a constant voltage V1 of, for example, 20 V by the constant voltage circuit including the transistor 14, the resistor 15, the capacitor 16, and the shunt regulator 17 of the power supply separation unit 2. DC voltage E converted to _CC Is supplied to the camera 1, whereby the imaging operation of the camera 1 is guaranteed.
[0008]
At this time, the value of the constant current I supplied from the constant current circuit of the power supply unit 4 is set to, for example, 205 mA including a margin to the maximum value of the consumption of the camera 1. For the time being, a design has been made in which the consumption current does not exceed 205 mA.
[0009]
In recent years, the power consumption of the camera has been reduced, and the current value required by the camera 1 has been considerably reduced to, for example, 130 mA. Therefore, when a camera having such a specification is used, a power supply unit is required. 75 mA of the current value of 205 mA supplied from 4 is consumed by the shunt regulator 17, resulting in large heat generation.
[0010]
In other words, in this case, no matter how much the power consumption of the camera 1 can be reduced, the power consumption on the camera side does not change, and not only power is wasted but also a large current flows through the shunt regulator 10. Heat generation becomes significant, and even the possibility of failure occurs.
[0011]
Therefore, conventionally, as shown in FIG. 8, a power supply unit 4 is used which can switch a constant current value supplied from a constant current circuit by adding resistors 20 and 21 and a manual switch 22. Thus, for example, both 205 mA specification camera and 160 mA specification camera can be appropriately handled. The reason why the specification is 160 mA is that the above-mentioned 130 mA has a margin.
[0012]
Here, in the power supply unit 4 of FIG. 8, the resistor 20 has a resistance value R corresponding to a constant current of 160 mA. ₁₆₀ When the resistor 21 is connected in parallel with the resistor 20, the combined resistance of the resistors 21 corresponds to the constant current I of 205 mA. ₂₀₅ So that R ₂₀₅ = R ₁₆₀ ・ R _A / (R ₁₆₀ + R _A ) Is satisfied. _A It is.
[0013]
Therefore, if the switch 22 is turned off, it can correspond to a camera having a constant current value of 160 mA, and if it is turned on, it can correspond to a camera having a constant current value of 205 mA. Thus, power consumption can always be optimized using the same power supply unit 4.
[0014]
[Problems to be solved by the invention]
The prior art described above does not give consideration to confirming that the switch is properly operated, and has a problem in preventing erroneous operation.
[0015]
In the related art, for example, even if a camera of 160 mA specification is operated with a switch setting of 205 mA, an abnormality does not immediately occur. Therefore, if the switch operation is not confirmed, there is a possibility that a camera of 160 mA specification may be used with the setting of 205 mA.
[0016]
Then, in this case, an overcurrent continues to flow through the shunt regulator 10 to generate a large amount of heat. If the shunt regulator 10 is left for a long time, there is a possibility that a failure will occur. This is not the case, so erroneous operations cannot be prevented.
[0017]
SUMMARY OF THE INVENTION It is an object of the present invention to provide a television camera system capable of easily preventing an erroneous operation of a constant current switch.
[0018]
Another object of the present invention is to provide a television camera system in which a switching operation of a constant current switch is not required.
[0019]
[Means for Solving the Problems]
The above object is to provide a television camera system of a system including a camera unit, a power supply separation unit and a power supply unit, and supplying DC power to the camera unit from a constant current source of the power supply unit via a line for transmitting a video signal. A current detection / comparison circuit that detects a constant current value supplied to the camera unit, a time constant circuit that operates by an output of the current detection / comparison circuit, and an operation signal that is output by the time constant circuit. A switch circuit, wherein the current detection and comparison circuit generates a detection signal when a constant current value supplied to the camera unit exceeds a preset reference current value, and the time constant circuit includes the detection signal The switch circuit generates the output signal until a predetermined time elapses from when the input is input, and the switch circuit cuts off the power supply to the camera unit when the output signal is input. To to be achieved.
[0020]
According to the above-described means, for example, if a camera of 160 mA specification is driven by a constant current of 205 mA, the power supply of the camera automatically repeats on and off, so that an erroneous operation can be immediately recognized and necessary measures are taken. be able to.
[0021]
Similarly, the other object is that the power supply unit further includes a voltage detection circuit that detects the voltage of the line, and a constant current value switching circuit that switches the constant current value between large and small, and the voltage detection circuit includes A switching signal is generated when the voltage of the line changes in a predetermined cycle, and the constant current value switching circuit switches the constant current value to the smaller one of the two types when the switching signal is generated. But it is achieved.
[0022]
According to the above means, when the power of the camera is repeatedly turned on and off, the constant voltage value of the power supply section is automatically changed, so that the imaging operation can be continued as it is.
[0023]
BEST MODE FOR CARRYING OUT THE INVENTION
Hereinafter, a television camera system according to the present invention will be described in detail with reference to the illustrated embodiments.
[0024]
First, FIG. 1 shows a first embodiment of the present invention. In FIG. 1, reference numeral 1A denotes a camera having a consumption current of 160 mA, and 2A denotes a power supply separation unit combined with a camera having a consumption current of 160 mA. The power supply unit 4 is the same as the television camera system according to the related art described with reference to FIG.
[0025]
In the power supply separating unit 2A, reference numeral 30 denotes a voltage control switch, 31 denotes a resistor for detecting a constant current value, 32 denotes a constant current detection circuit, 33 denotes a diode for a time constant circuit, and 34 denotes a diode for a time constant circuit. , A resistor 35 for a time constant circuit, and a voltage comparator 36. Others are the same as those of the television camera system according to the prior art described with reference to FIG.
[0026]
The switch 30 is a circuit element called an analog switch or the like. The switch 30 is turned on (conducted) when the control voltage V3 is at level 0, and is turned off (cut off) only when the control voltage V3 reaches a predetermined level. Works as a closed (normally closed) electronic switch.
[0027]
The resistor 31 is a so-called shunt resistor, and converts a constant current I supplied from the power supply unit 4 to the camera 1 to a voltage (voltage drop) V _x To the detected voltage V _x Is input to the constant current value detection circuit 32.
[0028]
The constant current value detection circuit 32 detects the voltage V _x Is input, and when the level exceeds a predetermined value, the peak value P _V Generates a pulse P having a predetermined width, and serves to supply the pulse P to a parallel circuit of a capacitor 34 and a resistor 35 via a diode 33.
[0029]
Therefore, as the constant current value detection circuit 32, for example, a voltage comparator and a monostable multivibrator (monostable multivibrator) are used, and the voltage V _x Is greater than or equal to a predetermined value, an output is generated by the voltage comparator, and the output triggers the monostable multivibrator to generate the pulse P.
[0030]
Here, in this example, the voltage V _x Becomes higher than a predetermined value when the value of the constant current I supplied from the power supply unit 4 to the camera 1 becomes 205 mA or more. 32 judgment values are set.
[0031]
The capacitor 34 and the resistor 35 constitute a time constant circuit. When a pulse P is input from the constant current value detection circuit 32 via the diode 33, the peak value P of this pulse _V After the capacitor 34 is charged to the voltage, the capacitor 34 is discharged by the resistor 35, and functions to generate a voltage V2 that decreases with a predetermined time constant.
[0032]
The voltage comparator 36 compares the level of the voltage V2 with the reference voltage VA, and generates the control voltage V3 when the voltage V2 is equal to or lower than the reference voltage VA, that is, when V2 ≦ VA. . Then, the control voltage V3 is supplied to the electronic switch 30 and functions to turn off.
[0033]
Next, the operation of the embodiment of FIG. 1 will be described. Here, in this figure, as described above, the camera 1A with the consumption current of 160 mA and the power supply separation unit 2A with the same consumption of 160 mA are combined with the power supply unit 4.
[0034]
Here, it is assumed that the switch 22 of the power supply unit 4 has been turned off as illustrated. Then, at this time, the value of the constant current I supplied to the camera becomes 160 mA, so that the loss of the shunt regulator 17 remains within the specification range.
[0035]
Further, as a result, the current value flowing through the shunt resistor 30 of the power supply separation unit 2A also becomes 160 mA, so that no pulse is generated from the constant current value detection circuit 32, and as a result, the switch 30 is kept on. .
[0036]
Therefore, at this time, the imaging operation of the camera 1A is continued as it is, and the heat generation of the shunt regulator 17 also falls within the specification range, and the operation is normally continued as it is.
[0037]
On the other hand, at this time, if the switch 22 of the power supply unit 4 is turned on from the beginning or due to an erroneous operation, the value of the constant current I supplied to the camera side becomes 205 mA this time. .
[0038]
As a result, the loss of the shunt regulator 17 exceeds the specification range, and if the operation is continued as it is, there is a risk of heating. In this case, the current flowing through the shunt resistor 30 of the power supply separation unit 2A is reduced. Since the current becomes 205 mA, a pulse is generated from the constant current value detection circuit 32.
[0039]
The operation at this time will be described with reference to FIG. 2. Assuming that the power supply unit 4 rises at time t1, the switch 21 is turned on at this time, and a constant current I of 205 mA is supplied to the camera side. The pulse P is generated from the constant current value detection circuit 32 as shown in FIG. 2B, and as a result, a voltage V2 is generated as shown in FIG.
[0040]
Then, as described above, the voltage V2 decreases to a sawtooth wave according to a time constant determined by the capacitance of the capacitor 34 and the resistance value of the resistor 35, and as a result, as shown in FIG. , Period T ₀ Is generated from the voltage comparator 36, whereby the switch 30 is on / off controlled.
[0041]
As a result, when a constant current I of 205 mA is supplied to the camera 1A, the power of the camera 1A is repeatedly turned on and off. As a result, a predetermined screen is displayed on the monitor screen connected to the camera 1A. Period T ₀ Will cause the video to be projected or disappeared, and even to be noticed.
[0042]
The cycle T at which the power is turned on / off at this time ₀ Is usually set to about 1 second in order to make it easy for the operator (operator) to see, and the time constant determined by the capacitance of the capacitor 34 and the resistance of the resistor 35 is set to the above-mentioned predetermined value. ing.
[0043]
Therefore, according to this embodiment, even if the power supply unit 4 is set to a constant current of 205 mA, that is, the switch 22 is turned on, and the camera is connected to a camera of 160 mA specification, this is not a problem. The operator can immediately recognize from the screen, and as a result, an appropriate response by the operator becomes possible, and occurrence of an abnormality due to unnecessary power consumption and overheating can be prevented.
[0044]
As a result, according to this embodiment, even when the power supply unit of the 205 mA specification is erroneously connected to the camera 1A, that is, the camera of the 160 mA specification, the power unit can be immediately recognized. The occurrence of an abnormality due to the above can be prevented beforehand.
[0045]
According to the above-described embodiment, a smooth transition to a power-saving camera can be easily achieved in the present embodiment even with a mixture of old-type cameras.
[0046]
Next, another embodiment of the present invention will be described with reference to FIG. Here, in the embodiment of FIG. 3, a power supply unit 4A is provided instead of the power supply unit 4 in the embodiment of the present invention described with reference to FIG. 1, and the camera 1A and the power supply separation unit 2A are not shown. This is the same as the first embodiment.
[0047]
The power supply unit 4A also differs from the power supply unit 4 in FIG. 1 in that an electronic switch 40 is provided instead of the manual switch 22, and a voltage comparator 41 and a time measurement circuit 42 are provided. Then, the on / off of the electronic switch 40 is controlled by the clock output V6 of the time measurement circuit 42.
[0048]
First, the electronic switch 40 is a normally closed type electronic switch like the switch 30 in the power supply separation unit 2A, and is turned off only when the time output V6 of the time measurement circuit 42 appears, thereby turning off the power supply unit 4A. It functions to switch the value of the output constant current I from 205 mA when turned on to 160 mA when turned off.
[0049]
Next, the voltage comparator 41 compares the line voltage V4 appearing on the coaxial cable 3 with the reference voltage VB. When the line voltage V4 is equal to or lower than the reference voltage VB, that is, when V4 ≦ VB, the comparison signal V5 is generated. It works to happen.
[0050]
Then, when the comparison signal V5 is generated, the time measurement circuit 42 compares the cycle with the reference cycle, and when the comparison signal V5 falls within a predetermined tolerance, generates a timekeeping signal V6. It serves to keep the signal V6 generated.
[0051]
Next, the operation of the embodiment of FIG. 3 will be described with reference to FIG. 4. Since the electronic switch 40 of the power supply section 4A is a normally closed type, a constant current I of 205 mA is supplied to the camera side when the power is turned on. As a result, as described above, in the power supply separation unit 2A on the camera side, as a result of detecting the constant current I of 205 mA, the electronic switch 30 has a period T of about 1 second. ₀ To start on / off.
[0052]
This situation is as shown in FIGS. 4A to 4D. As a result, the line voltage V4, that is, the constant voltage supplied to the coaxial cable 3 from the constant current circuit of the power supply unit 4A is obtained. The voltage appearing due to the current I periodically changes between around 20 V and around 35 V, as also shown in FIG.
[0053]
At this time, the voltage V4 changes because, as shown in FIG. 4D, the electronic switch 30 of the power supply separation unit 2A is turned on and off. DC voltage E supplied to camera 1A _CC However, the reason is that the voltage is adjusted to 20 V by the shunt regulator 17, and the voltage becomes close to 35 V when the power supply is turned off. _CC Is set to 35V.
[0054]
Therefore, by setting the reference voltage VB of the voltage comparator 41 between 20 V and 35 V as shown in FIG. 4E, that is, for example, near 25 V so that 20 V>VB> 35 V, As shown in FIG. 4 (f), the voltage comparator 41 generates a periodically changing comparison signal V 5, which is input to the time measurement circuit 42.
[0055]
Then, the time measurement circuit 42 determines that the cycle of the comparison signal V5 is the reference cycle T ₀ 4 (g), a time signal V6 is generated as shown in FIG. 4 (g). As a result, the electronic switch 40 is turned off after time t1 to switch the constant current I to 160 mA. .
[0056]
Therefore, according to the embodiment of FIG. 3, when the camera has the 205 mA specification, the state is the same, but in the case of the camera 1A having the 160 mA specification, the constant current I output from the power supply unit 4A is output by the electronic switch 40 by the electronic switch 40. Is automatically switched from the initial 205 mA to 160 mA, so that the operation can be continued without any consideration.
[0057]
Here, in the case of the embodiment described with reference to FIG. 1, if the operation is started while the manual switch 22 is turned on, the image display on the monitor screen becomes abnormal. Can solve the problem.
[0058]
However, when the monitor is not connected or when the power of the monitor is not turned on, this determination cannot be made. For example, the camera may be left in this abnormal state for a long time when a camera is set up.
[0059]
In this case, since the power supply of the camera is repeatedly turned on and off, the circuit is stressed, and the possibility of failure may occur. In addition, the switch 22 must be set in accordance with the camera at the time of installation. Is troublesome.
[0060]
However, according to the embodiment shown in FIG. 3, when the camera has the 205 mA specification, the electronic switch 40 is automatically turned off automatically even if the camera 1A has the 160 mA specification. Since the switching can be performed, the operation can always be performed without any consideration.
[0061]
Therefore, according to the embodiment shown in FIG. 3, there is no risk of occurrence of a failure due to stress in the circuit, and troublesome switch setting is not required. Therefore, it is possible to easily and easily set up the camera in a short time. it can.
[0062]
By the way, as the time measurement circuit 42 in the above-described embodiment, for example, the cycle of the comparison signal V5 is set to T by a program operation of the microcomputer using the built-in timer. ₀ The clock signal V6 may be generated when the value falls within a predetermined tolerance near (≒ 1 s). In this case, an inexpensive one-chip microcomputer can easily cope with this.
[0063]
As another method, as shown in FIG. 5 as an example, a timer can be configured by a monostable multivibrator or the like and a logic circuit can be used to configure the time measurement circuit 42.
[0064]
The time comparator 42 shown in FIG. 5 includes two MMVs (monostable multivibrators) 43 and 44, an AND gate 45, and an FF (flip-flop) 46 as shown in FIG. Period T of the comparison signal V5 supplied from the ₀ Is turned on / off at a cycle between about 0.5 seconds to about 1.5 seconds, the clock output V6 is set to the high level, the electronic switch 22 is turned off, and the constant current value supplied to the camera 1A is set to 205 mA. From 160 mA to 160 mA.
[0065]
Here, the MMVs 43 and 44 are both retriggerable (re-triggerable). First, the time constant of the first-stage MMV 43 is set to 0.5 second by the capacitor 43C and the resistor 43R. Each time it is triggered by a rising edge, it serves to generate a signal A of pulse width t1 (0.5 seconds).
[0066]
Next, the MMV 44 in the second stage is set to a time constant of 1.0 second by the capacitor 44C and the resistor 44R, so that the pulse width t2 (1 second) is generated every time the falling edge of the signal A is triggered. Of the signal B.
[0067]
The AND gate 45 performs a logical AND operation of the signal B and the comparison signal V5, generates an AND output C, and supplies the AND output C to the FF 46. The FF 46 is reset by a resistor 46R and a capacitor 46C when the power is turned on. Thereafter, when the AND output C is input, the timer output V6 is generated and functions to hold it.
[0068]
Therefore, next, the operation of the circuit of FIG. 5 will be described.
[0069]
Now, as described with reference to FIG. 3, if the camera 1A with a consumption current of 160 mA is connected to the power supply unit 4A, a comparison signal V5 is generated from the voltage comparator 41, and the comparison signal V5 is generated for about 0.5 to 1.5 seconds. Period T ₀ To start the level change.
[0070]
Then, in response to the on / off state of the comparison signal V5, the rising edge of the MMV 43 is triggered, so that a signal A having a pulse width t1 (0.5 seconds) is generated.
[0071]
Next, since the MMV 44 in the next stage is triggered by the falling edge of the signal A, a signal B having a pulse width t2 (1 second) is generated. As a result, the signal B is output to the AND gate 45. It is supplied together with the comparison signal V5.
[0072]
Then, the operation at this time will be described with reference to FIG. Here, FIG. 6A first shows the period T of the comparison signal V5. ₀ Is less than 0.5 seconds, FIG. 2B is a case where the time is 0.5 seconds or more and less than 1.5 seconds, and FIG. 2C is a case where the time is 1.5 seconds or more.
[0073]
First, in the case of FIG. 6A at the top, the cycle t1 of the comparison signal V5 is less than 0.5 seconds and the cycle T set to 1 second. ₀ Therefore, after being triggered by the first comparison signal V5, the MMV 43 is retriggered (retriggered) by the comparison signal V5 successively input one after another.
[0074]
As a result, the signal A of the MMV 43 once becomes a high level, is maintained as it is, and does not fall. Therefore, the MMV 44 of the next stage is not triggered, and the output signal B of the MMV 43 keeps a low level. In this case, the signal B and the AND signal C are also at the low level, and the FF 46 is not triggered, so that the clock output V6 is maintained at the low level.
[0075]
Next, in the case of FIG. 6C at the bottom, the cycle t1 of the comparison signal V5 is 1.5 seconds or more and the cycle T set to 1 second. ₀ As described above, the MMVs 43 and 44 sequentially generate the signal A and the signal B according to the comparison signal V5.
[0076]
However, in this case, after the MMVs 43 and 44 are sequentially triggered by the first comparison signal V5, the MMVs 43 and 44 end the monostable operation, and after the output signal B of the MMV 44 returns to the low level, the next comparison is performed. Since the signal V5 appears and the AND condition is not satisfied in the AND gate 45, the signal C does not go high, and the clock output V6 is also kept low in this case.
[0077]
On the other hand, in the case of FIG. 6B in the middle, when the period t1 of the comparison signal V5 is 0.5 seconds or more and less than 1.5 seconds, 0.5 second or more after one comparison signal V5 appears. Until the elapse of .5 seconds, the output signal B of the MMV 44 is at the high level.
[0078]
Therefore, at this time, the next comparison signal V5 is input while the output signal B of the MMV 44 is at the high level. Thereafter, the clock output V6 is set to the high level.
[0079]
Therefore, the time measurement circuit 42 in the above embodiment can be configured by the circuit shown in FIG. 5, and the present invention can be implemented.
[0080]
【The invention's effect】
According to the present invention, since the difference in the drive current value of the camera can be recognized, it is possible to connect and use the low power consumption camera and the conventional camera having the current value without being conscious. , Trouble during construction can be reduced.
[0081]
As a result, a smooth transition to a power-saving camera that will become mainstream in the future can be realized.
[Brief description of the drawings]
FIG. 1 is a block diagram showing an embodiment of a television camera system according to the present invention.
FIG. 2 is a waveform chart for explaining the operation of the embodiment of the present invention.
FIG. 3 is a block diagram showing another embodiment of the television camera system according to the present invention.
FIG. 4 is a waveform chart for explaining the operation of another embodiment of the present invention.
FIG. 5 is a block diagram showing an example of a time measurement circuit according to another embodiment of the present invention.
FIG. 6 is a waveform chart for explaining the operation of the time measurement circuit.
FIG. 7 is a block diagram showing an example of a television camera system according to the related art.
FIG. 8 is a block diagram showing another example of the television camera system according to the related art.
[Explanation of symbols]
1A camera (television camera)
2A power supply separation unit
3 Coaxial cable
4A power supply
5, 8 capacitors (for blocking DC)
6, 7 terminal
9 Amplifier
10 Video output connector
12 Transistor (for constant current circuit)
14 Transistor (for constant voltage circuit)
15 Resistance (for constant voltage circuit)
16 Capacitor (for constant voltage circuit)
17 Shunt regulator
20, 21 resistance (for constant current circuit)
22 switch (manual switch)
30 Electronic switch (for power on / off)
31 resistor (shunt resistor: for constant current detection)
32 Constant current value detection circuit
33 Diode (for time constant circuit)
34 Capacitor (for time constant circuit)
35 resistor (for time constant circuit)
36 Voltage comparator (for power on / off)
40 Electronic switch (for constant current switching)
41 Voltage comparator (for switching constant current)
42 time measurement circuit
43, 44 MMV (monostable multivibrator)
45 And Gate
46 FF (flip-flop)

Claims (2)

A television camera system comprising a camera unit, a power supply separation unit, and a power supply unit, and supplying DC power to the camera unit from a constant current source of the power supply unit via a line for transmitting a video signal,
A current detection / comparison circuit that detects a constant current value supplied to the camera unit, a time constant circuit that operates by an output of the current detection / comparison circuit, and an operation signal that is output by the time constant circuit. Provide a switch circuit,
The current detection / comparison circuit generates a detection signal when a constant current value supplied to the camera unit exceeds a preset reference current value, and the time constant circuit generates a detection signal when the detection signal is input. A television camera system, wherein the output circuit generates the output signal until a predetermined time elapses, and the switch circuit cuts off power supply to the camera unit when the output signal is input. The television camera system according to claim 1,
The power supply unit includes a voltage detection circuit that detects a voltage of the line, and a constant current value switching circuit that switches the constant current value between large and small.
The voltage detection circuit generates a switching signal when the voltage of the line changes at a predetermined cycle, and the constant current value switching circuit converts the constant current value into the large and small two when the switching signal is generated. A television camera system characterized by switching to the smaller of the two.

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