JP5922294B1 - Power supply system, optical transmission system - Google Patents

Abstract

Provided is a power supply system capable of using an electronic device without attaching an external battery to the electronic device even when AC power cannot be supplied to the power supply device. A power supply system that supplies power to a camera adapter (electronic device) from a base station (power supply device), wherein the base station selectively outputs high-voltage DC power and low-voltage DC power. The unit 29 is provided. The camera adapter includes a power receiving unit 31 to which high voltage DC power and low voltage DC power are input, a DC-DC conversion circuit 33 that converts the high voltage DC power into low voltage DC power, and a main circuit 34 that operates with the low voltage DC power. The power receiving unit is configured to be able to select whether input power is supplied to the main circuit through the DC-DC conversion circuit or whether input power is directly supplied to the main circuit. [Selection] Figure 1

Description

  The present invention relates to a power supply system and an optical transmission system.

  The video signal of the video captured by the video camera is sent to a switcher, etc. via a transmission cable. However, when these devices are installed far away, it is difficult to transmit the electrical signal without attenuation. By converting an electrical signal into an optical signal with a camera adapter installed in the video camera, transmitting the optical signal through an optical transmission cable, and converting the optical signal into an electrical signal at a base station installed at a distance Long-distance transmission is performed (Patent Document 1).

  Generally, AC power is input to the base station, and the AC power is supplied to the camera adapter as it is or after being boosted (AC power supply), or the AC power is converted into high-voltage DC power (eg, 139 V) at the base station. Power is supplied to the camera adapter. In the camera adapter, AC power or high-voltage DC power is converted into low-voltage DC power (for example, 15 V), and a main circuit for realizing various functions of the camera adapter operates with the low-voltage DC power.

Japanese Patent Laid-Open No. 2014-23042

  However, in the above method, when AC power cannot be supplied to the base station, the camera power cannot be supplied from the base station to the camera adapter, and the camera adapter can only be driven by an external battery. However, since the external battery is heavy, the burden on the photographer increases.

  The present invention has been made in view of such circumstances, and provides a power supply system that can use an electronic device without attaching an external battery to the electronic device even when AC power cannot be supplied to the power supply device. To do.

  According to the present invention, there is provided a power supply system that supplies power to an electronic device from a power supply device, wherein the power supply device selects whether to output at least one of AC power, high-voltage DC power, and low-voltage DC power. A power receiving unit configured to be capable of receiving, and the electronic device is configured to receive at least one of the AC power and the high voltage DC power and the low voltage DC power, and the AC power or the high voltage DC. A power conversion circuit that converts electric power into the low-voltage DC power; and a main circuit that operates with the low-voltage DC power; and the power receiving unit receives power input to the power receiving unit through the power conversion circuit to the main circuit. There is provided a power supply system configured to be able to select whether power supplied to the power receiving unit is directly supplied to the main body circuit.

  ADVANTAGE OF THE INVENTION According to this invention, it can supply with AC power or high voltage | pressure DC power with respect to an electronic device from an electric power supply apparatus, and can also be supplied with low voltage | pressure DC power. For this reason, in an environment where AC power can be supplied to the power supply device, the power supply device supplies power to the electronic device with AC power or high voltage DC power, and in an environment where AC power cannot be supplied to the power supply device, An external battery can be connected to supply power from the power supply device to the electronic device with low-voltage DC power.

  For example, there is a case where a power supply device is installed in a relay car and the power supply device and the electronic device are connected to perform relay. In such a case, conventionally, the power supply device supplies power to the electronic device. Because it was not possible, there was no choice but to attach an external battery to the electronic device. On the other hand, according to the present invention, since it is possible to supply power from the power supply device to the electronic device with low-voltage DC power, an external battery is connected to the power supply device to supply power to the electronic device from the power supply device The electronic device can be used without attaching an external battery to the electronic device.

Hereinafter, various embodiments of the present invention will be exemplified. The following embodiments can be combined with each other.
Preferably, the electronic device includes a main body unit having the power receiving unit and the main body circuit, and an external circuit unit having the power conversion circuit and configured to be detachable from the main body unit.
Preferably, the main body circuit is configured to be operable with electric power supplied from an external battery attached to the electronic device.
Preferably, the electronic device includes a power receiving side control unit that determines a type of electric power input to the power receiving unit, and the power receiving unit is configured to perform the selection under the control of the power receiving side control unit. The
Preferably, the power supply device includes a power transmission side control unit that communicates with the power reception side control unit to determine a type of power output by the power transmission unit, and the power transmission unit is controlled by the power transmission side control unit. And making the selection.
Preferably, the electronic device includes a power transmission unit that outputs electric power input to the power reception unit.
Preferably, the power supply device is configured to be able to input both AC power and low-voltage DC power.
Preferably, the power transmission unit outputs the high-voltage DC power obtained by converting the AC power input to the power supply device by a power conversion circuit, and the low-voltage DC power input to the power supply device. Configured to be possible.
Preferably, the power transmission unit is configured to be capable of outputting the AC power and the low-voltage DC power input to the power supply device.
Preferably, the high voltage DC power is 40 to 400V DC power, and the low voltage DC power is DC voltage of 25V or less.

According to another aspect of the present invention, an optical transmission system including the above-described power supply system,
An optical transmission system is provided in which the electronic device is a camera adapter, the power supply device is a base station, and optical transmission is performed between the camera adapter and the base station.

It is a block diagram which shows the structure of the optical transmission system of 1st Embodiment of this invention. It is a block diagram which shows the structure of the optical transmission system of 2nd Embodiment of this invention. It is a block diagram which shows the structure of the optical transmission system of 3rd Embodiment of this invention. It is a block diagram which shows the structure of the optical transmission system of 4th Embodiment of this invention. It is a block diagram which shows the structure of the optical transmission system of 4th Embodiment of this invention.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings. Various characteristic items shown in the following embodiments can be combined with each other. In addition, the invention is independently established for each feature.

  In the following embodiments, a power supply system in an optical transmission system will be described as an example. However, the power supply system of the present invention is applicable to any combination of electronic devices and power supply devices. In the following embodiments, the camera adapter is an electronic device, and the base station is a power supply device.

1. First embodiment 1-1. Configuration of Optical Transmission System Hereinafter, the optical transmission system according to the first embodiment of the present invention will be described with reference to FIG. As shown in FIG. 1, the optical transmission system according to the first embodiment of the present invention is an optical signal between a camera adapter 1 installed in a video camera and a base station 5 arranged at a position away from the video camera. In the optical transmission system for optical transmission, the camera adapter 1 converts the first electric signal including the video signal from the video camera into the first optical signal and transmits the first optical signal to the base station 5, and the base station 5 A signal is received, converted into a first electrical signal, and output to an external device. The base station 5 converts the second electric signal including the video signal from the external device into the second optical signal and transmits the second optical signal to the camera adapter 1. The camera adapter 1 receives the second optical signal and receives the second electric signal. Converted to external output.
Hereinafter, each component will be described.

1-2. Camera adapter 1
The camera adapter 1 is provided with a first electric signal input terminal, a second electric signal output terminal, and a connection terminal for the composite cable 7.

  The first electrical signal only needs to include at least a video signal, and may further include an income audio signal and various control signals. Accordingly, the first electric signal input terminal is constituted by, for example, a video signal input terminal, an intercom audio signal input terminal, and a control signal input terminal. The video signal of the first electric signal is preferably a digital signal, such as an SDI signal (eg, HD-SDI signal, SD-SDI, 3G-SDI signal), HDMI signal, 3D, or the like. A cable connected to the video signal output terminal of the video camera is connected to the video signal input terminal of the first electrical signal, and a cable connected to the headset is connected to the audio signal input terminal of the first electrical signal. The cable connected to the control signal output terminal of the video camera is connected to the control signal input terminal of the first electric signal.

  The second electrical signal only needs to include at least a video signal, and may further include an income audio signal and various control signals. Accordingly, the second electric signal output terminal is constituted by, for example, a video signal output terminal, an intercom audio signal output terminal, and a control signal output terminal. The video signal of the second electrical signal is preferably a digital signal, such as an SDI signal (eg, HD-SDI signal, SD-SDI, 3G-SDI signal), HDMI signal, 3D, or the like. A cable connected to a video signal input terminal of a video display device such as a viewfinder for a video camera is connected to the video signal output terminal of the second electrical signal, and a head is connected to the audio signal output terminal of the second electrical signal. A cable connected to the set is connected, and a cable connected to the control signal input terminal of the video camera is connected to the control signal output terminal of the second electric signal. The audio signal input terminal of the first electric signal and the audio signal output terminal of the second electric signal can be assigned to different pins of the same connector.

  A composite cable 7 that connects the camera adapter 1 and the base station 5 is connected to a connection terminal of the composite cable 7. The composite cable 7 includes an optical fiber 7a for optical transmission, a power cable 7b for power transmission, and a communication cable 7c for communication.

1-3. Base station 5
The base station 5 is provided with a first electric signal output terminal, a second electric signal input terminal, and a connection terminal for the composite cable 7.

  The first electric signal output terminal includes, for example, a video signal output terminal, an income audio signal output terminal, and a control signal output terminal. A cable connected to the video signal input terminal of an external device such as a switcher or a relay device is connected to the video signal output terminal of the first electrical signal, and the headset is connected to the audio signal output terminal of the first electrical signal. The cable connected to the control signal input terminal of the external device is connected to the control signal output terminal of the first electric signal.

  The second electric signal input terminal includes, for example, a video signal input terminal, an intercom audio signal input terminal, and a control signal input terminal. A cable connected to the video signal output terminal of the external device is connected to the video signal input terminal of the second electrical signal, and a cable connected to the headset is connected to the audio signal input terminal of the second electrical signal. The cable connected to the control signal output terminal of the external device is connected to the control signal input terminal of the second electrical signal. The audio signal output terminal of the first electric signal and the audio signal input terminal of the second electric signal can be assigned to different pins of the same connector.

  A composite cable 7 that connects the camera adapter 1 and the base station 5 is connected to a connection terminal of the composite cable 7.

1-4. Operation of Optical Transmission System Hereinafter, the operation of the optical transmission system will be described in more detail.
First, a first electric signal including a video signal from a video camera is input to the camera adapter 1. The first electrical signal is converted into a first optical signal by the EO conversion unit 11 in the camera adapter 1, and the first optical signal is transmitted to the base station 5 via the composite cable 7.

  In the base station 5, the OE converter 17 receives the first optical signal, converts it into a first electric signal, and outputs it to an external device such as a switcher or a relay device.

  The base station 5 receives a second electric signal including a video signal from an external device such as a switcher or a relay device. The second electrical signal is converted into a second optical signal by the EO converter 19 and transmitted to the camera adapter 1. The second optical signal may be transmitted using an optical fiber different from the first optical signal, or may be transmitted using the same optical fiber as the first optical signal by multiplexing.

  In the camera adapter 1, the OE conversion unit 25 receives the second optical signal, converts it into a second electrical signal, and externally outputs it to a video display device or the like installed in the video camera.

1-5. Power Supply System The camera adapter 1 includes a main circuit 34 that operates with low-voltage DC power. The main circuit 34 realizes various functions (OE conversion, EO conversion, LED lighting, etc.) of the camera adapter 1. The low-voltage DC power is a power supply voltage of the main circuit 34, and is preferably DC power having a voltage of 25V or less. This voltage is preferably 8 to 25V, and more preferably 10 to 20V. The camera adapter 1 can be attached with an external battery 35. The external battery 35 is configured to be able to supply low-voltage DC power, and this power can be used to operate the main circuit 34 as it is.

  The camera adapter 1 can also be powered from the base station 5. AC power from the AC power source 26 can be input to the base station 5, and the input AC power is converted into high voltage DC power by the AC-DC conversion circuit 27 and input to the power transmission unit 29. The high-voltage DC power is power that can be converted into low-voltage DC power by DC-DC conversion, and preferably has a voltage of 40 to 400 V, more preferably 60 to 300 V, more preferably 80 to 200 V, and still more preferably 100 to The DC power is 200V.

  An external battery 28 can be attached to the base station 5, and the low-voltage DC power from the external battery 28 is input to the power transmission unit 29 as it is. The power transmission unit 29 includes a connection switching device such as a relay. The connection switching device of the power transmission unit 29 is configured to be able to select which of the high-voltage DC power and the low-voltage DC power is output from the power transmission unit 29 by a connection switching signal from the power transmission side control unit 30.

  The power transmission side control unit 30 of the base station 5 can communicate with the power reception side control unit 32 of the camera adapter 1 through the communication cable 7c. The type of power that can be transmitted to the camera adapter 1 is determined. In the present embodiment, since the DC-DC conversion circuit 33 is built in the camera adapter 1, it is determined that both high voltage DC power and low voltage DC power can be transmitted.

  As described above, when both the high voltage DC power and the low voltage DC power are input to the power transmission unit 29 and the camera adapter 1 can receive both the high voltage DC power and the low voltage DC power, the power transmission side control unit 30 In consideration of transmission efficiency, it is determined that the high-voltage DC power is output from the power transmission unit 29, and a connection switching signal for controlling the power transmission unit 29 is output so that the high-voltage DC power is output. Based on this signal, high-voltage DC power is output from the power transmission unit 29, and this power is supplied to the camera adapter 1 through the power cable 7b. Further, when the power transmission side control unit 30 notifies the power reception side control unit 32 that the high voltage DC power is supplied, the power reception side control unit 32 determines that the power input to the power reception unit 31 is the high voltage DC power. can do.

  The power receiving unit 31 includes a connection switching device such as a relay. In the connection switching device of the power reception unit 31, the power input to the power reception unit 31 is supplied to the main circuit 34 via the DC-DC conversion circuit 33 according to the connection switching signal from the power reception side control unit 32, or the power reception unit It is configured to be able to select whether the power input to 31 is directly supplied to the main circuit 34.

  When the power receiving side control unit 32 determines that the power input to the power receiving unit 31 is high voltage DC power, the power receiving side control unit 32 outputs a connection switching signal to the power receiving unit 31, and the high voltage DC power input to the power receiving unit 31 is The power receiving unit 31 is controlled so as to be supplied to the main circuit 34 after being converted into low-voltage DC power by the DC-DC conversion circuit 33. In this state, when high voltage DC power is input to the power receiving unit 31, this power is converted into low voltage DC power by the DC-DC conversion circuit 33, and this low voltage DC power is supplied to the main circuit 34.

  On the other hand, when AC power is not supplied to the base station 5, only low-voltage DC power is supplied to the power transmission unit 29. In this case, the power transmission unit 29 supplies low-voltage DC power to the camera adapter 1 through the power cable 7b. In addition, when the power transmission side control unit 30 notifies the power reception side control unit 32 that low voltage DC power is supplied, the power reception side control unit 32 determines that the power input to the power reception unit 31 is low voltage DC power. can do.

  Based on the determination of the power receiving side control unit 32, the power receiving unit 31 switches so that the low voltage DC power input to the power receiving unit 31 is directly supplied to the main circuit 34, and the low voltage DC power is supplied to the main circuit 34. .

  As described above, in the present embodiment, low voltage DC power can be supplied from the base station 5 to the camera adapter 1, so that an external battery is attached to the camera adapter 1 even when AC power cannot be supplied to the base station 5. The camera adapter 1 can be powered.

The present invention can also be implemented in the following modes.
In the above embodiment, the connection switching devices of the power transmission unit 29 and the power reception unit 31 are controlled by the control units 30 and 32. However, a switch is provided in the connection switching device, and the switch is manually switched using this switch. May be. For example, in consideration of safety or the like, when it is desired to supply power with low-voltage DC power, the switches of the power transmission unit 29 and the power reception unit 31 are operated to output the low-voltage DC power from the power transmission unit 29. The low voltage DC power input to 31 can be set to be input directly to the main circuit 34.
In the above embodiment, the AC-DC conversion circuit 27 is configured to convert AC power to high voltage DC power, but the AC power can be converted into either high voltage DC power or low voltage DC power. May be. In this case, for example, the output voltage can be changed by an operation unit (switch, volume, etc.) provided in the AC-DC conversion circuit 27.
-Communication between the control parts 30 and 32 may be performed via the power cable 7b.

2. Second Embodiment A second embodiment of the present invention will be described with reference to FIG. This embodiment is similar to the first embodiment, and the camera adapter 1 has a main body 1a having a power receiving unit 31 and a main body circuit 34, a DC-DC conversion circuit 33, and is attached to and detached from the main body 1a. The main difference is that the external circuit unit 1b is configured to be possible.

  In the present embodiment, the external circuit portion 1b can be removed from the main body portion 1a, and only the main body portion 1a can be attached to the video camera for use. By removing the external circuit portion 1b, the camera adapter 1 can be reduced in weight, and the burden on the cameraman can be reduced.

  When the distance between the base station 5 and the camera adapter 1 is long, power transmission with high-voltage DC power is advantageous in order to reduce power transmission loss. Therefore, in such a case, the external circuit unit 1b is mounted, the camera adapter 1 is supplied with high voltage DC power from the base station 5, and the high voltage DC power is converted into low voltage DC power by the DC-DC conversion circuit 33. The main circuit 34 is supplied.

  On the other hand, when the distance between the base station 5 and the camera adapter 1 is relatively short, the influence of power transmission loss is small, so that the external circuit unit 1b can be removed with priority given to the weight reduction of the camera adapter 1. In this case, the camera adapter 1 can be supplied with low-voltage DC power from the base station 5, and this low-voltage DC power can be supplied to the main circuit 34. The low-voltage DC power output from the base station 5 may be supplied from the external battery 28 to the base station 5, and is obtained by converting AC power into low-voltage DC power in the AC-DC conversion circuit 27. It may be a thing. Therefore, in the present embodiment, the AC-DC conversion circuit 27 is preferably configured to convert AC power into either high voltage DC power or low voltage DC power.

3. Third Embodiment A third embodiment of the present invention will be described with reference to FIG. This embodiment is similar to the second embodiment, and is mainly different in that power can be supplied from the base station 5 to the camera adapter with AC power.

  In the present embodiment, the AC power input to the base station 5 can be output from the power transmission unit 29 as it is, so that an AC-DC conversion circuit is unnecessary, and the base station 5 can be downsized. The camera adapter 1 is provided with an AC-DC conversion circuit 41 instead of the DC-DC conversion circuit 33, and the AC power input to the power receiving unit 31 is converted into low-voltage DC power by the AC-DC conversion circuit 41. It is converted and supplied to the main circuit 34.

The present invention can also be implemented in the following modes.
-The base station 5 may be provided with a booster circuit to boost the AC power and then transmit power. In this case, power transmission loss can be reduced.
-You may combine 2nd and 3rd embodiment. In this case, power can be transmitted using any of AC power, high voltage DC power, and low voltage DC power.

4). Fourth Embodiment A fourth embodiment of the present invention will be described with reference to FIGS. This embodiment is similar to the first embodiment, and is mainly different in that the camera adapter 2 is provided between the base station 5 and the camera adapter 1. Hereinafter, the difference will be mainly described.

  The camera adapter 1 and the camera adapter 2 are connected by a composite cable 8. The composite cable 8 includes an optical fiber 8a for optical transmission, a power cable 8b for power transmission, and a communication cable 8c for communication. The camera adapter 2 and the base station 5 are connected by a composite cable 7.

  The camera adapter 2 includes OE converters 13 and 21 and EO converters 15 and 23. The first optical signal from the camera adapter 1 is converted into a first electric signal by the OE converter 13. The third electrical signal is input to the camera adapter 2, and the first and third electrical signals are converted into first and third optical signals by the EO converter 15. The third electrical signal only needs to include at least a video signal, and may further include an income audio signal and various control signals.

  The first and third optical signals are converted into first and third electrical signals by the EO converter 17 in the base station 5 and output to an external device. The OE converter 21 of the camera adapter 2 converts the second optical signal from the base station 5 into a second electric signal. The second electrical signal is output to the display device, converted to a second optical signal by the EO converter 23, and output to the camera adapter 1.

  The camera adapter 2 includes a power reception unit 31, a power reception side control unit 32, a DC-DC conversion circuit 33, and a main body circuit 34 similar to the camera adapter 1, and a power transmission unit 29 and a power transmission side control unit 30 of the base station 5. The power transmission part 29a and the power transmission side control part 30a which have the same function are provided. The power supplied from the base station 5 to the camera adapter 2 is input to the power receiving unit 31 and also to the power transmitting unit 29a. The power transmission unit 29 a of the camera adapter 2 supplies low voltage DC power or high voltage DC power toward the camera adapter 1 by the same operation as the power transmission unit 29 of the base station 1.

  According to the configuration of the present embodiment, signal and power can be transmitted between the camera adapter 1 and the base station 5 without directly connecting the camera adapter 1 and the base station 5, and the cable length can be shortened. is there.

The present invention can also be implemented in the following modes.
The configuration disclosed in the second to third embodiments can be applied to this embodiment.

Claims (11)

A power supply system for supplying power to an electronic device from a power supply device,
The power supply device includes a power transmission unit configured to be capable of selecting which of at least one of AC power and high-voltage DC power and low-voltage DC power is output,
The electronic device includes a power receiving unit configured to be capable of inputting at least one of the AC power and the high-voltage DC power and the low-voltage DC power, and power conversion for converting the AC power or the high-voltage DC power into the low-voltage DC power. A circuit and a main circuit that operates with the low-voltage DC power,
The power receiving unit selects whether the power input to the power receiving unit is supplied to the main body circuit via the power conversion circuit or the power input to the power receiving unit is directly supplied to the main body circuit to be able to be configured,
The AC power and at least one said low DC power of the high-voltage DC power, through a common power supply cable, Ru is configured from the power supply device so as to supply power to the electronic device, the power supply system. A power supply system for supplying power to an electronic device from a power supply device,
The power supply device includes a power transmission unit configured to be capable of selecting which of at least one of AC power and high-voltage DC power and low-voltage DC power is output,
The electronic device includes a power receiving unit configured to be capable of inputting at least one of the AC power and the high-voltage DC power and the low-voltage DC power, and power conversion for converting the AC power or the high-voltage DC power into the low-voltage DC power. A circuit and a main circuit that operates with the low-voltage DC power,
The power receiving unit selects whether the power input to the power receiving unit is supplied to the main body circuit via the power conversion circuit or the power input to the power receiving unit is directly supplied to the main body circuit Configured and possible
The electronic device includes a main body portion and, and having the power conversion circuit comprises an external circuit that is configured to detachably attached to the main body portion, power supply system having the power receiving unit and the main body circuit. The power supply system according to claim 1, wherein the main body circuit is configured to be operable with electric power supplied from an external battery attached to the electronic device. The electronic device includes a power receiving side control unit that determines a type of electric power input to the power receiving unit, and the power receiving unit is configured to be controlled by the power receiving side control unit to perform the selection. The power supply system according to any one of claims 1 to 3. A power supply system for supplying power to an electronic device from a power supply device,
The power supply device includes a power transmission unit configured to be capable of selecting which of at least one of AC power and high-voltage DC power and low-voltage DC power is output,
The electronic device includes a power receiving unit configured to be capable of inputting at least one of the AC power and the high-voltage DC power and the low-voltage DC power, and power conversion for converting the AC power or the high-voltage DC power into the low-voltage DC power. A circuit and a main circuit that operates with the low-voltage DC power,
The power receiving unit selects whether the power input to the power receiving unit is supplied to the main body circuit via the power conversion circuit or the power input to the power receiving unit is directly supplied to the main body circuit Configured and possible
The electronic device includes a power receiving side control unit that determines a type of power input to the power receiving unit, and the power receiving unit is configured to be controlled by the power receiving side control unit to perform the selection.
The power supply device includes a power transmission side control unit that communicates with the power reception side control unit and determines a type of power output from the power transmission unit, and the power transmission unit is controlled by the power transmission side control unit and selected. configured to perform, power supply system. A power supply system for supplying power to an electronic device from a power supply device,
The power supply device includes a power transmission unit configured to be capable of selecting which of at least one of AC power and high-voltage DC power and low-voltage DC power is output,
The electronic device includes a power receiving unit configured to be capable of inputting at least one of the AC power and the high-voltage DC power and the low-voltage DC power, and power conversion for converting the AC power or the high-voltage DC power into the low-voltage DC power. A circuit and a main circuit that operates with the low-voltage DC power,
The power receiving unit selects whether the power input to the power receiving unit is supplied to the main body circuit via the power conversion circuit or the power input to the power receiving unit is directly supplied to the main body circuit Configured and possible
The electronic device includes a power transmission unit which outputs the power input to the power receiving unit, power supply system. The power supply system according to any one of claims 1 to 6, wherein the power supply device is configured to be capable of inputting both AC power and low-voltage DC power. The power transmission unit is configured to output the high-voltage DC power obtained by converting the AC power input to the power supply device by a power conversion circuit and the low-voltage DC power input to the power supply device. The power supply system according to claim 7. The power supply system according to claim 7, wherein the power transmission unit is configured to be capable of outputting the AC power and the low-voltage DC power input to the power supply device. The power supply system according to any one of claims 1 to 9, wherein the high-voltage DC power is DC power of 40 to 400V, and the low-voltage DC power is DC power of 25V or less. An optical transmission system comprising the power supply system according to any one of claims 1 to 10,
The optical transmission system, wherein the electronic device is a camera adapter, the power supply device is a base station, and optical transmission is performed between the camera adapter and the base station.