JP2021064194A - Power control system, video display device, and power control method - Google Patents

Abstract

To provide a power control system, a video display device, and a power control method capable of reducing power consumption.SOLUTION: A source apparatus 100 supplies voltage. A sink apparatus 110 operates an operation unit 1220 using voltage supplied from the source apparatus 100 after authentication related to voltage with the source apparatus 100. The sink apparatus 110 includes a request unit 1200 and a transformation unit 1210. The request unit 1200 requests the source apparatus 100 power supply at a first voltage value under a normal state. The transformation unit 1210 transforms voltage of the first voltage value supplied from the source apparatus 100 based on the request from the request unit 1200 and outputs it to the operation unit 1220. The request unit 1200 requests power supply at a second voltage value lower than the first voltage value in a power saving state different from the normal state. The transformation unit 1210 outputs, based on the voltage of the second voltage value supplied from the source apparatus 100, voltage having a predetermined voltage value to the operation unit 1220.SELECTED DRAWING: Figure 12

Description

The present invention relates to a power control system, a video display device, and a power control method.

In recent years, the number of devices compatible with a USB (Universal Serial Bus) Type-C connector has been increasing. For example, the number of source devices that can supply up to 100 W of power from the Vbus line of the Type-C connector is increasing. In addition, the number of video display devices (sink devices) capable of displaying images by using the electric power from the USB Type-C cable source device is increasing.

The Vbus voltage (supply voltage) output from the USB Type-C connector of the source device is determined by the power delivery authentication between the source device and the sink device, and is supplied to the video display device. For example, the Vbus voltage is determined to be one of 5V, 9V, 12V, 15V and 20V and supplied to the image display device.

Normally, the DC power supply supplied to the sink device is set to a voltage between a low voltage and a high voltage among the voltages used in the circuit in the sink device. This is because the voltage of each circuit is generated by the step-down circuit and the step-up circuit to maintain good power efficiency of the entire sink device.

Here, for example, the low voltage used in the circuit in the sink device is set as the voltage (5V) of the control unit (CPU: Central Processing Unit) of the sink device, and the high voltage used in the circuit in the sink device. Let's assume a power supply configuration in which the voltage (40V) of the backlight of the display panel is used. In the case of such a power supply configuration, for example, when the Vbus voltage from the source device is in the vicinity of 20V between 5V and 40V, the power supply efficiency becomes good.

Therefore, in the case of such a power supply configuration, when the sink device is connected to the source device by the USB Type-C connector, the source device requests a Vbus voltage of 20 V and receives a Vbus voltage of 20 V from the source device. .. This makes it possible to reduce the power consumption of the entire sink device.

As a related technique, a power supply device is disclosed in which the power supplied from the power supply unit to the external device via the USB connector is lower when the operation mode is the power saving mode than when the operation mode is the normal mode (). For example, see Patent Document 1.).

In addition to this, as related technologies, the operation mode for the main control unit is switched to the normal mode or the power saving mode, and the voltage supplied from the main power supply to a plurality of device groups is stepped down or lowered based on the mode switching state. A power control device that boosts the voltage and adjusts access timings for a plurality of device groups based on a mode switching request to the main control unit is disclosed (see, for example, Patent Document 2).

Japanese Unexamined Patent Publication No. 2016-134059 Japanese Unexamined Patent Publication No. 9-305275

However, with the above power supply configuration, the backlight is turned off in the power saving mode such as when the power of the sink device is off or when the operator of the sink device is absent, so that the display panel is backed up. The 40V voltage required for the light is no longer required, and the voltage required in the sink device is 5V required for the operation of the control unit. Therefore, if a Vbus voltage of 20 V is supplied from the source device, there is a problem that power consumption corresponding to the power for boosting in the source device and the power for stepping down in the sink device is wasted. was there.

In addition, even in the eco mode in which the current of the backlight of the sink device is reduced to reduce the power consumption, the voltage required for the backlight is lowered. Therefore, if a Vbus voltage of 20 V is supplied from the source device, the voltage inside the source device is reduced. There is a problem that the power consumption related to the boosting and the power consumption corresponding to the power related to the step-down and the boosting in the image display device are wasted.

In view of the above problems, it is an object of the present invention to provide a power control system, an image display device, and a power control method capable of reducing power consumption.

In order to solve the above-mentioned problems, the power control system according to one aspect of the present invention is
A power control system including a source device that supplies a voltage and a sink device that operates an operating unit using the voltage supplied from the source device after certification of the voltage with the source device.
The sink device is
In a normal state, a request unit that requests the source device to supply power at the first voltage value, and
A transformer unit that transforms the voltage of the first voltage value supplied from the source device in response to a request from the request unit and outputs the voltage to the operating unit.
With
The requesting unit requests power supply at a second voltage value lower than the first voltage value in a power saving state different from the normal state.
The transformer unit outputs a voltage having a predetermined voltage value to the operating unit based on the voltage of the second voltage value supplied from the source device.
It is a power control system.

The image display device according to one aspect of the present invention is
An image display device that operates an operating unit using the voltage supplied from the voltage supply device after authentication regarding the voltage with the voltage supply device.
In a normal state, a requesting unit that requests the voltage supply device to supply power at the first voltage value, and
A transformer unit that transforms the voltage of the first voltage value supplied from the voltage supply device in response to a request from the request unit and outputs the voltage to the operating unit.
With
The requesting unit requests power supply at a second voltage value lower than the first voltage value in a power saving state different from the normal state.
The transformer unit outputs a voltage having a predetermined voltage value to the operating unit based on the voltage of the second voltage value supplied from the voltage supply device.
It is a video display device.

The power control method according to one aspect of the present invention is
A power control method in a power control system including a source device that supplies a voltage and a sink device that operates an operating unit using the voltage supplied from the source device after certification of the voltage with the source device.
The sink device
In the normal state, the request step of requesting the source device to supply power at the first voltage value, and
A transformer step that transforms the voltage of the first voltage value supplied from the source device according to the request in the request step and outputs the voltage to the operating unit.
And
In the request step, power is requested at a second voltage value lower than the first voltage value in a power saving state different from the normal state.
In the transformation step, a voltage having a predetermined voltage value is output to the operating unit based on the voltage of the second voltage value supplied from the source device.
This is a power control method.

According to the present invention, power consumption can be reduced.

It is explanatory drawing which shows an example of the electric power control system 1 which concerns on embodiment. It is explanatory drawing which shows an example of the hardware composition of the power control system 1. It is explanatory drawing which shows an example of the power-source control in a normal state. It is explanatory drawing which shows an example of the power supply control in the power saving mode 1 of a power control system 1. It is explanatory drawing which shows an example of the power supply control in the power saving mode 2 of the power control system 1. It is explanatory drawing which shows an example of the power source control in the power saving mode 3 of a power control system 1. It is a flowchart which shows an example of the power-source control processing in a power-saving mode performed by a power control system 1. It is explanatory drawing which shows an example of the power source control in the eco mode of the electric power control system 1. It is explanatory drawing which shows an example of the relationship between the current and voltage at the time of DC control of a backlight 225b. It is explanatory drawing which shows an example of the relationship between the current and voltage at the time of DC control of a backlight 225b. It is a flowchart which shows an example of the power-source control processing in an eco-mode performed by a power control system 1. It is a block diagram which shows an example of the functional structure of the electric power control system 1 which concerns on embodiment. It is explanatory drawing which shows an example of the power-source control in the conventional power saving mode.

Hereinafter, a power control system, an image display device, and a power control method according to an embodiment of the present invention will be described with reference to the drawings.

(Embodiment)
FIG. 1 is an explanatory diagram showing an example of the power control system 1 according to the embodiment. In FIG. 1, the power control system 1 is, for example, a computer device such as a personal computer. The power control system 1 includes a source device 100 and a sink device 110. The source device 100 is, for example, a personal computer body. The source device 100 includes an AC power supply unit and receives power from an outlet. Further, the source device 100 includes a mouse 101 and a keyboard 102. The mouse 101 and keyboard 102 are connected to the source device 100 by wire or wirelessly. The mouse 101 and keyboard 102 may be connected to the source device 100 with a Type-C cable.

The sink device 110 is, for example, a video display device (display). Specifically, as the sink device 110, for example, a liquid crystal display, a plasma display, an organic EL (Electroluminescence), or the like can be adopted. The sink device 110 and the source device 100 are connected by, for example, one USB Type-C cable 120. The USB Type-C cable 120 outputs a video signal from the source device 100 to the sink device 110 and supplies DC power. The sink device 110 displays a video signal by the electric power supplied from the source device 100 by the USB Type-C cable 120.

(Example of hardware configuration of power control system 1)
FIG. 2 is an explanatory diagram showing an example of the hardware configuration of the power control system 1. In FIG. 2, the source device 100 includes a video output unit 201, a CPU 202, a USB PD (Power Delivery) controller 203, a power supply unit 204, and a booster circuit 205.

The video output unit 201 generates a video signal and outputs the generated video signal to the sink device 110 via the USB Type-C cable 120. The CPU 202 controls the USB PD controller 203. The USB PD controller 203 enables power supply of up to 100 W from the booster circuit 205 to the sink device 110 under the control of the CPU 202 in response to a request for power supply from the USB PD controller 226 of the sink device 110. The power supply unit 204 outputs the power (for example, 5V) supplied from the AC power supply to the booster circuit 205.

The booster circuit 205 boosts the voltage output from the power supply unit 204 according to the control of the USB PD controller 203. For example, the booster circuit 205 boosts the voltage of 5V supplied from the AC power source to either the 5V as it is or 9V, 12V, 15V and 20V, and sinks it via the USB Type-C connector 210. Output to device 110.

The USB Type-C cable 120 includes a plurality of wires. The plurality of wires include, for example, a video signal line 212, a CC signal line 213, and a Vbus line 214. The video signal line 212 is a signal line for outputting the video signal output from the video output unit 201 to the sink device 110.

The CC signal line 213 performs negotiations such as determining the direction of the plug inserted into the connector, setting the direction of power supply, current or voltage between connected devices, and determining the role of each terminal. It is a signal line that sends and receives signals related to equipment for such purposes. The Vbus line 214 is a power supply wiring for supplying power from the booster circuit 205 to the sink device 110. The USB Type-C connector 210 can supply up to 100 W of power from the Vbus line 214.

Further, the USB Type-C cable 120 includes USB Type-C connectors 210 at both ends. The USB Type-C connector 210 includes terminals corresponding to a plurality of wirings included in the USB Type-C cable 120.

The sink device 110 includes a control key 221, a sensor 222, a control unit 223, a video processing circuit 224, a display panel 225, a USB PD controller 226, a step-up circuit 227, a step-down circuit 228, and a switch 229. Be prepared. The display panel 225 includes an image display unit 225a and a backlight 225b. The backlight 225b is, for example, an LED (Light Emitting Diode) backlight. The USB PD controller 226 includes a supply voltage memory 226a.

The control key 221 includes a power switch for switching to the power saving mode, a changeover switch for the eco mode, and the like, and accepts the user's operation. The power saving mode is a mode in which the power supply to the backlight 225b is turned off and the backlight 225b is turned off. The eco mode is a mode in which the power consumption of the backlight 225b is reduced according to the setting by the operator. The control key 221 outputs the input result of the operation input received from the user to the control unit 223.

The sensor 222 is a sensor capable of detecting the absence of an operator, and is, for example, a motion sensor or a luminance sensor. When the sensor 222 detects, for example, the absence of the operator, the sensor 222 outputs the detection result to the control unit 223. The determination as to whether or not the operator is absent is not limited to the sensor 222, but may be performed by the control unit 223. Specifically, the control unit 223 may constantly input the detection result of the sensor 222 and use the detection result to determine whether or not the operator is absent.

The control unit 223 controls the video processing circuit 224, the USB PD controller 226, and the booster circuit 227. The control unit 223 is realized by, for example, a CPU. For example, the control unit 223 outputs the video signal output from the source device 100 to the video processing circuit 224. The image processing circuit 224 causes the image display unit 225a of the display panel 225 to display an image under the control of the control unit 223. Further, the control unit 223 controls the USB PD controller 226 to change the voltage value supplied from the source device 100. Further, the control unit 223 controls the booster circuit 227 to output a voltage having a predetermined voltage value to the backlight 225b.

The USB PD controller 226 refers to the voltage stored in the supply voltage memory 226a, and makes a request for power supply (supply of voltage) to the USB PD controller 203 of the source device 100. Specifically, the supply voltage memory 226a stores a combination of a voltage value and a current value that can be received. Here, the source device 100 and the sink device 110 are determined to be on the power feeding side and the power receiving side by the resistance connected to the CC signal after the USB Type-C connector 210 is connected.

Then, the power supply side and the power receiving side perform power delivery authentication via the CC signal. In the power delivery certification, the supply side transmits the combination of the voltage and the current that can be supplied to the power receiving side, and the power receiving side transmits the combination of the voltage and the current that can be supplied stored in the supply voltage memory 226a to the power receiving side. As a result, the supply voltage and current supplied from the power supply side to the power reception side are determined.

The booster circuit 227 boosts the voltage supplied from the booster circuit 205 of the source device 100 according to the control of the control unit 223, and outputs the voltage to the backlight 225b. The step-down circuit 228 lowers the voltage supplied from the step-up circuit 205 of the source device 100 and outputs it to the control unit 230.

The switch 229 can output the voltage supplied from the source device 100 to the control unit 223 without passing through the step-down circuit 228. Specifically, the switch 229 is switched ON / OFF according to the control of the control unit 223, and when the switch 229 is ON, the voltage supplied from the booster circuit 205 of the source device 100 is output to the control unit 230. ..

(Example of power supply control under normal conditions)
FIG. 3 is an explanatory diagram showing an example of power supply control in a normal state. The normal state is not a state for power saving such as a power saving mode, but a steady state in which the image display device is on. In a normal state, the USB PD controller 226 of the sink device 110 requests the USB PD controller 203 of the source device 100 to supply 20 V according to the control of the control unit 223.

The USB PD controller 203 of the source device 100 causes the booster circuit 205 to start supplying 20 V when there is a request for supplying 20 V from the sink device 110. Here, a voltage of 5 V is input to the booster circuit 205 from the power supply unit 204. The booster circuit 205 boosts the voltage of 5V from the power supply unit 204 to 20V under the control of the USB PD controller 203 and supplies it to the sink device 110.

The booster circuit 227 of the sink device 110 boosts the voltage of 20V supplied from the booster circuit 205 of the source device 100 to 40V and outputs it to the backlight 225b. Further, the step-down circuit 228 of the sink device 110 steps down the voltage of 20 V supplied from the step-up circuit 205 of the source device 100 to 5 V and outputs it to the control unit 223.

As described above, when the voltage required for the control unit 223 of the sink device 110 is 5V and the voltage required for the backlight 225b of the display panel 225 is 40V, the power supply efficiency is high when the supply voltage from the source device 100 is around 20V. It will be good. Therefore, in the power delivery authentication performed when the USB Type-C cable 120 is connected, the power receiving side (USB PD controller 226 of the sink device 110) requests the power supply side (USB PD controller 203 of the source device 100) to supply 20 V. To do. Then, the power supply side supplies a voltage of 20 V from the booster circuit 205 to the sink device 110 via the Vbus line 214.

(Example of power supply control in the conventional power saving mode)
Here, an example of power supply control in the conventional power saving mode will be described in detail with reference to FIG. FIG. 13 is an explanatory diagram showing an example of power supply control in the conventional power saving mode. The conventional power control system 1300 shown in FIG. 13 is different from the power control system 1 according to the present embodiment in that the sink device 110 is not provided with the switch 229 in terms of configuration.

In the power saving mode, the USB PD controller 226 of the sink device 110 requests the USB PD controller 203 of the source device 100 to supply 20 V according to the control of the control unit 223.

The USB PD controller 203 of the source device 100 causes the booster circuit 205 to start supplying 20 V when there is a request for supplying 20 V from the sink device 110. Here, a voltage of 5 V is input to the booster circuit 205 from the power supply unit 204. The booster circuit 205 boosts the voltage of 5V from the power supply unit 204 to 20V under the control of the USB PD controller 203 and supplies it to the sink device 110.

The step-down circuit 228 of the sink device 110 steps down the voltage of 20 V supplied from the step-up circuit 205 of the source device 100 to 5 V and outputs it to the control unit 223. Further, in the power saving mode, the booster circuit 227 of the sink device 110 stops supplying the voltage to the backlight 225b under the control of the control unit 223. This makes it possible to reduce the power consumption of the power used for the backlight 225b.

However, in the conventional power control system 1300, although the maximum voltage required for the sink device 110 is 5 V, a voltage of 20 V is supplied from the source device 100. Therefore, the power component related to the step-up in the step-up circuit 205 of the source device 100 and the power component related to the step-down in the step-down circuit 228 of the sink device 110 are wasted.

Therefore, the sink device 110 according to the present embodiment requires the source device 100 to supply a voltage (low voltage) at a voltage value lower than the voltage value in the normal state in a power saving state such as a power saving mode. , The voltage based on the low voltage supplied from the source device 100 is output to the control unit 223 and the like. As a result, the efficiency of power consumption can be improved. Hereinafter, the power supply control in the power saving modes 1 to 3 of the power control system 1 of the present embodiment will be described.

(Example of power supply control in power saving mode 1 of power control system 1)
FIG. 4 is an explanatory diagram showing an example of power supply control in the power saving mode 1 of the power control system 1. The power saving mode 1 is, for example, a mode in which the output of the voltage to the backlight 225b is turned off when it is detected that the mouse 101 or the keyboard 102 is not operated for a certain period of time.

As shown in FIG. 4, when the mouse 101 or the keyboard 102 is not operated for a certain period of time, the video output unit 201 considers that the operator is absent and stops the output of the video signal. When the video signal from the video output unit 201 is turned off, the control unit 223 controls the booster circuit 227 to stop the output of the voltage to the backlight 225b.

Further, the control unit 223 controls the USB PD controller 226 to switch the PD (Power Delivery) supply voltage to 5V. For example, the control unit 223 rewrites the feed voltage value stored in the supply voltage memory 226a from 20V to 5V. The USB PD controller 226 performs USB Type-C power delivery authentication again, and requests the USB PD controller 203 of the source device 100 to supply 5 V.

The USB PD controller 203 of the source device 100 causes the booster circuit 205 to start supplying 5V when there is a request for supplying 5V from the sink device 110. Here, a voltage of 5 V is input to the booster circuit 205 from the power supply unit 204. The booster circuit 205 supplies the 5V voltage from the power supply unit 204 to the sink device 110 as it is without boosting the voltage.

In the power saving mode 1, the control unit 223 short-circuits (on) the switch 229 of the sink device 110 and outputs the 5 V voltage supplied from the source device 100 to the control unit 223. As a result, it is possible to reduce the waste of power consumption of the power consumption of the step-up circuit 205 of the source device 100 and the power consumption of the step-down circuit 228 of the sink device 110.

(Example of power supply control in power saving mode 2 of power control system 1)
FIG. 5 is an explanatory diagram showing an example of power supply control in the power saving mode 2 of the power control system 1. The power saving mode 2 is, for example, a mode in which the output of the voltage to the backlight 225b is turned off when the absence of the operator is detected by the sensor 222 for a certain period of time.

As shown in FIG. 5, when the sensor 222 detects the absence of the operator for a certain period of time, the sensor 222 outputs the detection result to the control unit 223. When the control unit 223 inputs the detection result indicating the absence of the operator from the sensor 222, the control unit 223 stops the output of the voltage to the backlight 225b to the booster circuit 227.

Further, the control unit 223 controls the USB PD controller 226 to switch the PD supply voltage to 5V. For example, the control unit 223 rewrites the feed voltage value stored in the supply voltage memory 226a from 20V to 5V. The USB PD controller 226 performs USB Type-C power delivery authentication again, and requests the USB PD controller 203 of the source device 100 to supply 5 V.

The USB PD controller 203 of the source device 100 causes the booster circuit 205 to start supplying 5V when there is a request for supplying 5V from the sink device 110. Here, a voltage of 5 V is input to the booster circuit 205 from the power supply unit 204. The booster circuit 205 supplies the 5V voltage from the power supply unit 204 to the sink device 110 as it is without boosting the voltage.

In the power saving mode 2, the control unit 223 short-circuits (on) the switch 229 of the sink device 110 and outputs the 5 V voltage supplied from the source device 100 to the control unit 223. As a result, it is possible to reduce the waste of power consumption of the power consumption of the step-up circuit 205 of the source device 100 and the power consumption of the step-down circuit 228 of the sink device 110.

(Example of power supply control in power saving mode 3 of power control system 1)
FIG. 6 is an explanatory diagram showing an example of power supply control in the power saving mode 3 of the power control system 1. The power saving mode 3 is, for example, a mode in which the output of the voltage to the backlight 225b is turned off when the power switch of the control key 221 is turned off.

As shown in FIG. 6, when the control key 221 receives an operation input for turning off the power switch from the user, the control key 221 outputs the reception result to the control unit 223. When the control unit 223 inputs the reception result for turning off the power switch from the control key 221, the control unit 223 stops the output of the voltage to the backlight 225b to the booster circuit 227.

Further, the control unit 223 controls the USB PD controller 226 to switch the PD supply voltage to 5V. For example, the control unit 223 rewrites the feed voltage value stored in the supply voltage memory 226a from 20V to 5V. The USB PD controller 226 performs USB Type-C power delivery authentication again, and requests the USB PD controller 203 of the source device 100 to supply 5 V.

The USB PD controller 203 of the source device 100 causes the booster circuit 205 to start supplying 5V when there is a request for supplying 5V from the sink device 110. Here, a voltage of 5 V is input to the booster circuit 205 from the power supply unit 204. The booster circuit 205 supplies the 5V voltage supplied from the power supply unit 204 to the sink device 110 as it is without boosting the voltage.

In the power saving mode 3, the control unit 223 short-circuits (on) the switch 229 of the sink device 110 and outputs the 5 V voltage supplied from the source device 100 to the control unit 223. As a result, it is possible to reduce the waste of power consumption of the power consumption of the step-up circuit 205 of the source device 100 and the power consumption of the step-down circuit 228 of the sink device 110.

(An example of power control processing in the power saving mode performed by the power control system 1)
FIG. 7 is a flowchart showing an example of power supply control processing in the power saving mode performed by the power control system 1. In FIG. 7, the sink device 110 determines whether or not the non-use state of the power control system 1 has been detected for a certain period of time (step S701). Specifically, the detection of the unused state includes the fact that the video signal is stopped due to the mouse 101 and the keyboard 102 not being operated, the absence of the operator is detected by the sensor 222, and the power switch of the control key 221. Is operated off.

When the sink device 110 does not detect the unused state (step S702: NO), the booster circuit 205 of the source device 100 continuously outputs the PD supply voltage of 20 V (step S702), and ends a series of processes. When the PD supply voltage of 20V is continuously output from the source device 100, the booster circuit 227 of the sink device 110 boosts the PD supply voltage of 20V to 40V and outputs it to the backlight 225b. Further, the step-down circuit 228 of the sink device 110 steps down the PD supply voltage of 20 V to 5 V and outputs it to the control unit 223.

On the other hand, when the sink device 110 detects an unused state (step S702: YES), the control unit 223 of the sink device 110 stops the booster circuit 227 and turns off the backlight 225b (step S703). Then, the control unit 223 of the sink device 110 rewrites the feed voltage value stored in the supply voltage memory 226a from 20V to 5V (step S704). Next, the USB PD controller 226 of the sink device 110 again performs USB Type-C power delivery authentication (step S705).

Then, the USB PD controller 226 requests the USB PD controller 203 of the source device 100 to supply 5 V (step S706). In response to this request, the source device 100 outputs a PD supply voltage of 5 V (step S707). Then, the control unit 223 of the sink device 110 short-circuits the switch 229 of the sink device 110, supplies the 5V voltage supplied from the source device 100 to the control unit 223 (step S708), and ends a series of processes.

(Example of power supply control in eco mode of power control system 1)
FIG. 8 is an explanatory diagram showing an example of power supply control in the eco mode of the power control system 1. As shown in FIG. 8, when the control key 221 receives an operation input for setting the eco mode from the user, the control key 221 outputs the reception result to the control unit 223. When the reception result for setting the eco mode is input from the control key 221, the control unit 223 controls the USB PD controller 226 to switch the PD supply voltage to 15V.

For example, the control unit 223 rewrites the feed voltage value stored in the supply voltage memory 226a from 20V to 15V. The USB PD controller 226 performs USB Type-C power delivery authentication again, and requests the USB PD controller 203 of the source device 100 to supply 15 V.

The USB PD controller 203 of the source device 100 causes the booster circuit 205 to start supplying 15 V when there is a request from the sink device 110 to supply 15 V. Here, a voltage of 5 V is input to the booster circuit 205 from the power supply unit 204. The booster circuit 205 boosts the 5V voltage supplied from the power supply unit 204 to 15V and supplies it to the sink device 110.

Further, the control unit 223 of the sink device 110 controls the booster circuit 227 to reduce the current value of the backlight 225b. Although the details will be described later, by lowering the current value of the backlight 225b, the forward voltage Vf of the backlight 225b is lowered.

The booster circuit 227 of the sink device 110 boosts the voltage of 15V supplied from the booster circuit 205 of the source device 100 to 25V under the control of the control unit 223, and outputs the voltage to the backlight 225b. Here, the booster circuit 227 outputs a voltage of 40 V to the backlight 225b in a normal state, but outputs a voltage of 25 V to the backlight 225 b in the eco mode.

Further, the step-down circuit 228 of the sink device 110 steps down the voltage of 15V supplied from the step-up circuit 205 of the source device 100 to 5V and outputs it to the control unit 223. Thereby, in the eco mode, the voltage supplied from the source device 100 can be reduced from 20V to 15V, and the voltage of the backlight 225b can be reduced from 40V to 25V.

Further, since the booster circuit 205 of the source device 100 only needs to be boosted to 15V, the power related to boosting can be reduced as compared with the case of boosting to 20V. Further, since the booster circuit 227 of the sink device 110 only needs to boost the voltage from 15V to 25V, the power related to the boosting can be reduced as compared with the case of boosting from 20V to 40V. Further, since the step-down circuit 228 of the sink device 110 only needs to step down from 15V to 5V, the power related to the step-down can be reduced as compared with the case of stepping down from 20V to 5V.

(Relationship between current and voltage during DC control of backlight 225b)
FIG. 9 is an explanatory diagram showing an example of the relationship between the current and the voltage during DC control of the backlight 225b. As shown in FIG. 9, in the case of DC control, when the forward current of the backlight 225b decreases, the forward voltage Vf of the backlight 225b also decreases. The forward voltage Vf is a voltage required to make the LED emit light. FIG. 9 shows a case where the forward voltage Vf is reduced from 40 V to 25 V by reducing the forward current from 100 mA to 5 mA in the eco mode.

Here, for example, the supply voltage (Va) of the optimum power supply efficiency in the video display device is expressed by the formula “Va = (Vf + Vb) / 2”. Vf is the forward voltage of the backlight 225b. Vb is the voltage of the control unit 223. When Vf is 25V and Vb is 5V, the supply voltage Va of the optimum power efficiency is 15V. For this reason, in the eco mode in the present embodiment, the supply voltage from the source device 100 is set to 15 V, which is the optimum power efficiency.

Further, with reference to FIG. 10, the reason why the supply voltage from the source device 100 to the sink device 110 is set to a value lower than 20V (for example, 15V) will be described. FIG. 10 is an explanatory diagram showing an example of the relationship between the current and the voltage during DC control of the backlight 225b.

Depending on the control method of the backlight 225b, as shown in FIG. 10, when the forward current is reduced to 5 mA, the forward voltage Vf may be 20 V or less (for example, 18 V in the figure). That is, depending on the control method of the backlight 225b, the voltage of the backlight 225b decreases (for example, decreases to 20V or less) in the eco mode, and the voltage of the backlight 225b is lower than the input voltage (for example, 20V) of the booster circuit 227. The voltage may drop.

In this case, the booster circuit 227 may become unstable and may not operate correctly. In order to avoid this state, in the present embodiment, the voltage supplied from the source device 100 to the sink device 110 (voltage input to the booster circuit 227) in the eco mode is set from the voltage value 25V output from the booster circuit 227. The low voltage value is 15V. This makes it possible to stably operate the booster circuit 227 of the sink device 110.

(Example of power control processing in eco mode performed by power control system 1)
FIG. 11 is a flowchart showing an example of power supply control processing in the eco mode performed by the power control system 1. In FIG. 11, the sink device 110 determines whether or not the eco-mode is turned on by setting the eco-mode changeover switch (step S1101).

When the eco mode is off (step S1102: NO), the booster circuit 205 of the source device 100 continuously outputs the PD supply voltage of 20 V (step S1102), and ends a series of processes. When the PD supply voltage of 20V is continuously output from the source device 100, the booster circuit 227 of the sink device 110 boosts the PD supply voltage of 20V to 40V and outputs it to the backlight 225b. Further, the step-down circuit 228 of the sink device 110 steps down the PD supply voltage of 20 V to 5 V and outputs it to the control unit 223.

On the other hand, when the eco mode is turned on (step S1102: YES), the control unit 223 of the sink device 110 reduces the current of the backlight 225b from 100 mA to 5 mA (step S1103). As a result, the forward voltage Vf of the backlight 225b drops from 40V to 30V (step S1104).

Then, the control unit 223 of the sink device 110 rewrites the feed voltage value stored in the supply voltage memory 226a from 20V to 15V (step S1105). Next, the USB PD controller 226 of the sink device 110 again performs USB Type-C power delivery authentication (step S1106).

Then, the USB PD controller 226 requests the USB PD controller 203 of the source device 100 to supply 15 V (step S1107). In response to this request, the source device 100 outputs a PD supply voltage of 15 V (step S1108), and ends a series of processes.

(Functional configuration of power control system 1)
Next, the functional configuration of the power control system 1 will be described with reference to FIG. FIG. 12 is a block diagram showing an example of the functional configuration of the power control system 1 according to the embodiment. In FIG. 12, the power control system 1 includes a source device 100 and a sink device 110. The source device 100 is a voltage supply device that supplies a voltage. The source device 100 is, for example, a video display device. The sink device 110 displays an image on the display unit (display panel 225) using the voltage supplied from the source device 100 after the authentication regarding the voltage with the source device 100. The certification referred to here is power delivery certification.

The sink device 110 includes a request unit 1200, a transformer unit 1210, and an operation unit 1220. The request unit 1200 is realized by the control unit 223 and the USB PD controller 226. The transformer unit 1210 includes a step-up circuit 227, a step-down circuit 228, and a switch 229. Further, the operation unit 1220 includes a control unit 223 and a backlight 225b.

The request unit 1200 requests the source device 100 to supply power at the first voltage value under a normal state. The first voltage value is, for example, 20V. The transformer unit 1210 transforms the voltage of the first voltage value supplied from the source device 100 at the request of the request unit 1200 and outputs it to the operation unit. Specifically, the booster circuit 227 of the transformer unit 1210 boosts the first voltage value to 40 V and outputs it to the backlight 225b under a normal state. Further, the step-down circuit 228 of the transformer unit 1210 steps down the first voltage value to 5 V and outputs it to the control unit 223 under a normal state.

In particular, the requesting unit requests power supply at a second voltage value lower than the first voltage value in a power saving state different from the normal state. The power saving state includes, for example, a light-off mode and a reduction mode. The extinguishing mode is, for example, a power saving mode. The reduction mode is, for example, an eco mode. The second voltage value differs between the power saving mode and the eco mode. The second voltage value in the power saving mode may be any voltage value required for the operation of the control unit 223, and is, for example, 5 V in the present embodiment.

The second voltage value in the eco mode may be a voltage value lower than the voltage value (25V) output from the booster circuit 227 from the viewpoint of stable operation of the booster circuit 227. In the present embodiment, the second voltage value in the eco mode is, for example, 15V.

The transformer unit 1210 outputs a voltage having a predetermined voltage value to the operating unit 1220 based on the voltage of the second voltage value supplied from the source device 100. The predetermined voltage value is a voltage value based on the second voltage value. For example, the predetermined voltage value includes a voltage value obtained by transforming the voltage of the second voltage value and a voltage value of the second voltage value itself (voltage value not transformed). Further, the transformer unit 1210 can output a voltage to the operating unit 1220 based on the voltage of the second voltage value. Specifically, the transformer unit 1210 may or may not output a voltage to the operating unit 1220 based on the voltage of the second voltage value.

Below, the transformer by the transformer unit 1210 will be supplemented separately for the case of the power saving mode and the case of the eco mode.

(In power saving mode)
In the power saving mode, the transformer unit 1210 outputs the voltage of the second voltage value (5V) to the control unit 223 without stepping down. For example, the transformer unit 1210 outputs the voltage of the second voltage value to the control unit 223 without stepping down by turning on the switch 229 in the power saving mode. The on / off switching of the switch 229 is performed, for example, by the control of the control unit 223. Further, in the power saving mode, the transformer unit 1210 does not output the voltage of the second voltage value to the backlight 225b. Specifically, in the power saving mode, the booster circuit 227 of the transformer unit 1210 does not boost the second voltage value and does not output the voltage to the backlight 225b.

Further, in the present embodiment, the start conditions of the power saving mode are, for example, that the video signal output from the source device 100 is turned off, that the backlight 225b is turned off, and that the sink device 110 is turned off. One of the detections that the operator is absent. The start condition of the power saving mode is not limited to these, and may be, for example, a preset time zone or date and time. Further, the power saving mode is started when the above-mentioned start condition is satisfied in the normal state or the eco mode.

(In case of eco mode)
Further, in the present embodiment, the step-down circuit 228 of the transformer unit 1210 reduces the voltage of the second voltage value (for example, 15 V) to a voltage value equivalent to the voltage value (for example, 5 V) for step-down in the normal state in the eco mode. The voltage is stepped down and output to the control unit 223. The voltage value output to the control unit 223 is the same in the eco mode, the normal state, and the control unit 223 because, for example, the voltage value required for the operation of the control unit 223 does not change between the eco mode and the normal state. is there.

On the other hand, in the eco mode, the booster circuit 227 of the transformer unit 1210 boosts the voltage of the second voltage value to a voltage value (for example, 25V) lower than the voltage value (for example, 40V) for boosting in the normal state and backs up. Output to light 225b. As a result, in the eco mode, the backlight 225b can be turned on at a lower voltage value than in the normal state.

As described above, the power control system 1 according to the present embodiment requires the source device 100 to receive power at a second voltage value lower than the voltage value in the normal state in a power saving state such as a power saving mode. Then, a voltage having a predetermined voltage value is output to the operating unit 1220 based on the voltage of the second voltage value supplied from the source device 100. As a result, it is possible to reduce the power consumption related to the power supply of the source device 100 and the power consumption related to the transformation of the sink device 110. Therefore, according to the present embodiment, it is possible to reduce the power consumption of the power control system 1 using the Type-C connector.

Further, in the present embodiment, in the power saving mode, the transformer unit 1210 outputs the voltage of the second voltage value (5V) to the control unit 223 without stepping down, and outputs the voltage of the second voltage value to the backlight 225b. I tried not to. Thereby, the electric power related to the step-down of the step-down circuit 228 can be reduced.

Further, in the present embodiment, the transformer unit 1210 includes a step-down circuit 228 and a switch 229, and in the power saving mode, by turning on the switch 229, the voltage of the second voltage value is not stepped down to the control unit 223. Made to output. As a result, power consumption can be reduced with a simple configuration in which the switch 229 is provided.

Further, in the present embodiment, the start conditions of the power saving mode are that the video signal from the source device 100 is turned off, the operation of turning off the sink device 110 is performed, and the operator of the sink device 110 is used. It was decided that it was one of the cases where the absence was detected. As a result, when the operator is absent or when the operator performs an operation to set the power saving mode, the power saving mode can be set to reduce the power consumption.

Further, in the present embodiment, in the eco mode, the transformer unit 1210 lowers the voltage of the second voltage value (for example, 15V) to the same voltage value as the voltage value (for example, 5V) for lowering the voltage in the normal state, and controls the control unit. It was output to 223, and the voltage of the second voltage value was boosted to a voltage value (for example, 25V) lower than the voltage value (for example, 40V) boosted in a normal state and output to the backlight 225b. As a result, the power consumption related to the step-up of the step-up circuit 205 of the source device 100 is reduced, the power consumption related to the step-up of the step-up circuit 227 of the sink device 110 is reduced, and the power consumption related to the step-down of the step-down circuit 228 is reduced. Can be planned.

Further, in the present embodiment, the second voltage value (15V) in the eco mode is set to be a voltage value lower than the voltage value (25V) output from the booster circuit 227. As a result, the voltage value output from the booster circuit 227 can be made higher than the voltage value input to the booster circuit 227, so that the booster circuit 227 of the sink device 110 can be operated stably.

All or part of the power control system 1 in the above-described embodiment may be realized by a computer. In that case, the program for realizing this function may be recorded on a computer-readable recording medium, and the program recorded on the recording medium may be read by the computer system and executed. The term "computer system" as used herein includes hardware such as an OS and peripheral devices. Further, the "computer-readable recording medium" refers to a portable medium such as a flexible disk, a magneto-optical disk, a ROM, or a CD-ROM, or a storage device such as a hard disk built in a computer system. Further, a "computer-readable recording medium" is a communication line for transmitting a program via a network such as the Internet or a communication line such as a telephone line, and dynamically holds the program for a short period of time. It may also include a program that holds a program for a certain period of time, such as a volatile memory inside a computer system that serves as a server or a client in that case. Further, the above program may be for realizing a part of the above-mentioned functions, and may be further realized for realizing the above-mentioned functions in combination with a program already recorded in the computer system. It may be realized by using a programmable logic device such as FPGA.

Although the embodiments of the present invention have been described in detail with reference to the drawings, the specific configuration is not limited to this embodiment, and includes designs and the like within a range that does not deviate from the gist of the present invention.

1: Power control system, 100: Source device, 110: Sink device, 120: USB Type-C cable, 201: Video output unit, 202: CPU, 203: USB PD controller, 204: Power supply unit, 205: Booster circuit , 210: USB Type-C connector, 221: control key, 222: sensor, 223: control unit, 224: video processing circuit, 225: display panel, 225b: backlight, 226: USB PD controller, 227: booster circuit, 228: Step-down circuit, 229: Switch, 1200: Request part, 1210: Transformer part, 1220: Operation part

Claims (8)

A power control system including a source device that supplies a voltage and a sink device that operates an operating unit using the voltage supplied from the source device after certification of the voltage with the source device.
The sink device is
In a normal state, a request unit that requests the source device to supply power at the first voltage value, and
A transformer unit that transforms the voltage of the first voltage value supplied from the source device in response to a request from the request unit and outputs the voltage to the operating unit.
With
The requesting unit requests power supply at a second voltage value lower than the first voltage value in a power saving state different from the normal state.
The transformer unit outputs a voltage having a predetermined voltage value to the operating unit based on the voltage of the second voltage value supplied from the source device.
Power control system. The power saving state includes a turn-off mode in which the backlight of the display unit is turned off.
The operating unit includes a control unit that controls the sink device and the backlight.
In the extinguishing mode, the transformer unit outputs the voltage of the second voltage value to the control unit without stepping down, and does not output the voltage of the second voltage value to the backlight.
The power control system according to claim 1. The transformer unit
It includes a step-down circuit that steps down the voltage supplied from the source device and outputs it to the control unit, and a switch that can output the voltage supplied from the source device to the control unit without passing through the step-down circuit.
In the extinguishing mode, by turning on the switch, the voltage of the second voltage value is output to the control unit without stepping down.
The power control system according to claim 2. In the extinguishing mode, it is detected that the video signal output from the source device is turned off, the operation of turning off the backlight is performed, and the operator of the sink device is absent. Started by one of the things,
The power control system according to claim 2 or 3. The power saving state includes a reduction mode that reduces the power consumption of the backlight of the display unit according to the setting by the operator.
The operating unit includes a control unit that controls the sink device and the backlight.
The transformer unit is in the reduction mode.
The voltage of the second voltage value is stepped down to a voltage value equivalent to the voltage value stepped down in the normal state and output to the control unit.
The voltage of the second voltage value is boosted to a voltage value lower than the voltage value boosted in the normal state and output to the backlight.
The power control system according to any one of claims 1 to 4. The transformer unit includes a booster circuit that boosts the voltage supplied from the source device and outputs the voltage to the backlight.
The second voltage value is a voltage value smaller than the voltage value output from the booster circuit.
The power control system according to claim 5. An image display device that operates an operating unit using the voltage supplied from the voltage supply device after authentication regarding the voltage with the voltage supply device.
In a normal state, a requesting unit that requests the voltage supply device to supply power at the first voltage value, and
A transformer unit that transforms the voltage of the first voltage value supplied from the voltage supply device in response to a request from the request unit and outputs the voltage to the operating unit.
With
The requesting unit requests power supply at a second voltage value lower than the first voltage value in a power saving state.
The transformer unit outputs a voltage having a predetermined voltage value to the operating unit based on the voltage of the second voltage value supplied from the voltage supply device.
Video display device. A power control method in a power control system including a source device that supplies a voltage and a sink device that operates an operating unit using the voltage supplied from the source device after certification of the voltage with the source device.
The sink device
In the normal state, the request step of requesting the source device to supply power at the first voltage value, and
A transformer step that transforms the voltage of the first voltage value supplied from the source device according to the request in the request step and outputs the voltage to the operating unit.
And
In the request step, in the power saving state, power supply at a second voltage value lower than the first voltage value is requested.
In the transformation step, a voltage having a predetermined voltage value is output to the operating unit based on the voltage of the second voltage value supplied from the source device.
Power control method.

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