JP6210850B2 - Power over Ethernet (registered trademark) compatible power receiving device and power over Ethernet (registered trademark) compatible display - Google Patents

Description

  The present invention relates to a power receiving device and a display compatible with Power over Ethernet (registered trademark) that receive power supply via a network cable.

  Power over Ethernet (registered trademark) supplies power to each network device from a hub or switch via a network cable. Hereinafter, the “registered trademark” note may be omitted from the Ethernet notation. In power over Ethernet, a hub, a switch, or the like is provided as a power supply device called PSE (Power Sourcing Equipment), and power is supplied to a power reception device called PD (Powered device) connected thereto. According to Power over Ethernet, power can be supplied to network devices arranged in places where it is difficult to supply power. For example, it is suitable for wireless LAN (Local Area Network) access points, WEB cameras, IP (Internet Protocol) phones, etc. It is. The power over Ethernet standard is IEEE802.3af standardized in 2003 and IEEE802.3at standardized in 2009.

In IEEE802.3af, the power feeding apparatus can transmit a maximum of 15.4 W of power, and the power receiving apparatus can use a maximum of 12.95 W of power when in class 0. The difference between the transmission power of the power supply apparatus and the power used by the power reception apparatus is a power loss in the transmission path. Hereinafter, IEEE802.3af may be described as “PoE”.
In IEEE802.3at, the power feeding device can transmit a maximum of 30 W of power, and the power receiving device can use a maximum of 25.5 W of power. Hereinafter, IEEE802.3at may be described as “PoE +”.

  The solution of the summary of Patent Literature 1 includes: “When an event occurs in which the operation mode of the first camera is changed from the low power mode to the high power mode, and there is no power supply capacity on the hub side, the server device An instruction is sent to the second camera to set the operation mode to the low power mode and lower the priority of power supply. " As described above, the power supply capability of PoE is a limitation of the network device on the power receiving side.

  In 2011, Cisco Systems announced UPoE (Universal Power over Ethernet), which can use more power than IEEE802.3at. In UPoE, the power supply apparatus can transmit a maximum of 60 W of power, and the power reception apparatus can use a maximum of 51 W of power. As described above, it is expected that the application range of the power over Ethernet is further expanded due to an increase in power that can be used by the power receiving apparatus.

JP 2013-105394 A

  When a liquid crystal display is made to support PoE (IEEE802.3af) and is operated with power supplied via a network cable, the upper limit of PoE power becomes a problem. The power consumption of the liquid crystal display exceeds 12.95 W, which is the power that can be used with PoE (IEEE802.3af) when operated at the maximum load. Therefore, the power protection of the PoE-compatible power supply device works, and the power supply may stop. Some PoE + (IEEE802.3at) compatible power supply devices that support LLDP (Link Layer Discovery Protocol) supply only 15.4 W of power until LLDP negotiation is completed. At this time, there is a problem in that the PoE-compatible power receiving device whose power consumption exceeds 12.95 W cannot start operation and makes the user wait.

  Therefore, the present invention provides a power over Ethernet (registered trademark) compatible power receiving device and display that can be used immediately even when connected to a PoE compatible power supply device or a PoE + compatible power supply device compatible with LLDP. The issue is to provide.

In order to solve the above-described problem, in the first invention, a power receiving unit that receives supply of power from a power supply device via a network cable , an output unit that performs predetermined output by the power received by the power receiving unit, and the power supply a determination unit that determines the power supply capacity of the device, if it is determined that its power consumption than feeding capacity of the feeding device is large, limiting the maximum output by the output unit in accordance with the power supply capacity of the pre-Symbol feed device The power over Ethernet (registered trademark) power receiving apparatus includes a control unit and a display unit that displays information on the maximum output limited by the control unit.

In the second invention, a power receiving unit that receives power supply from the power supply device via a network cable , an output unit that performs a predetermined output by the power received by the power receiving unit, and a determination for determining the power supply capability of the power supply device and parts, if it is determined that its power consumption than feeding capacity of the feeding device is large, and a control unit that limits the maximum output by the output unit in accordance with the power supply capacity of the pre-Symbol power feeding device, wherein the control unit And a display unit for displaying information related to the limited maximum output . A display compatible with Power over Ethernet (registered trademark) is provided.

In this way, a power over Ethernet (registered trademark) compatible power receiving device and display can be used even when connected to a PoE compatible power supply device or a PoE + compatible power supply device compatible with LLDP. is there. Furthermore, information corresponding to the power saving operation can also be displayed.
Other means will be described in the embodiment for carrying out the invention.

  According to the present invention, a power over Ethernet (registered trademark) power receiving device or display that can be used immediately even when connected to a PoE compatible power supply device or a PoE + compatible power supply device compatible with LLDP. It becomes possible to provide.

It is a schematic block diagram which shows the liquid crystal display in this embodiment. It is a figure which shows the structure of the power supply board in this embodiment. It is a flowchart which shows the process of the liquid crystal display in this embodiment. It is a flowchart which shows the process of the Ethernet microcomputer in this embodiment. It is a flowchart which shows the LED display process of the scaler in this embodiment. It is a figure which shows the setting screen in this embodiment. It is a figure which shows the display screen in a modification.

Hereinafter, embodiments for carrying out the present invention will be described in detail with reference to the drawings.
FIG. 1 is a schematic configuration diagram showing a liquid crystal display 1 in the present embodiment.
As shown in FIG. 1, a liquid crystal display 1 includes a scaler 2, a power supply board 3, a DVI (Digital Visual Interface) terminal 4, a storage unit 5, a switch board 6, an LED (Light Emitting Diode) 7, A liquid crystal panel 8 and a liquid crystal panel backlight 81 are provided, and are connected to the power supply device 9 by a network cable (LAN cable). The liquid crystal display 1 corresponds to the IEEE802.3af standard, the IEEE802.3at standard, and the UPoE standard. That is, the liquid crystal display 1 is compatible with Power over Ethernet (registered trademark), and is driven by the power received from the power feeding device 9.
The power supply device 9 is a hub device having a power supply function of, for example, IEEE 802.3af standard, IEEE 802.3at standard, and UPoE standard. However, the power supply device 9 is not limited to this, and the power supply device 9 may have, for example, a power supply function according to IEEE802.3af standard and IEEE802.3at standard, or a power supply function that supports only the IEEE802.3af standard. May be.

The scaler 2 processes the input video signal and synchronization signal and outputs them to the liquid crystal panel 8, and controls the volume setting and mute of the input audio and outputs them to a speaker (not shown). The scaler 2 (control unit) has a built-in microcomputer, receives a switch signal from the switch board 6 and controls the liquid crystal display 1 in an integrated manner. The scaler 2 shifts to the power save mode when either or both of the horizontal synchronizing signal and the vertical synchronizing signal of the video signal cannot be detected. If the scaler 2 determines that the power consumption of the liquid crystal display 1 is larger than the power supply capability of the power supply device 9, the operation mode of the liquid crystal display 1 itself is changed to a power saving mode corresponding to the power supply capability of the power supply device 9. Change to That is, the scaler 2 limits the luminance of the liquid crystal panel backlight 81, which is one of the operation items of the liquid crystal display 1, to the luminance according to the power supply capability of the power supply device 9. However, the present invention is not limited to this, and the scaler 2 may limit the volume of the speaker, which is one of the operation items, to a volume according to the power supply capability of the power supply device 9.
The switch element Q1 is, for example, a field effect transistor, receives a POWER_ON signal from the scaler 2, and supplies DC + 5V power to the liquid crystal panel 8.
The power supply board 3 is supplied with power from the power supply device 9 via a network cable, and supplies power to each part of the liquid crystal display 1. Details of the power supply substrate 3 will be described in detail with reference to FIG.

The DVI terminal 4 is a terminal that can be connected to a computer or the like, for example, and flows a TMDS (Transition Minimized Differential Signaling) signal from the outside to the scaler 2. The TMDS signal is converted into an LVDS (Low voltage differential signaling) signal by the scaler 2 and transmitted to the liquid crystal panel 8.
The storage unit 5 is a non-volatile memory represented by, for example, an EEPROM (Electrically Erasable Programmable Read-Only Memory), and stores information set by the user on an OSD (On Screen Display). . The information stored in the storage unit 5 includes, for example, backlight luminance, display timing, R / G / B gain, firmware information, and the like.
The switch board 6 is a button for operating a power button or OSD, and accepts a user operation to set the liquid crystal display 1 itself. The switch board 6 is, for example, a plurality of electrostatic switches, and includes a menu key, a pair of left and right cursor keys, an input key, and a power key.

The LED 7 (display unit) is composed of a light emitting diode capable of multicolor display, and displays a color corresponding to the operating state (luminance limit) of the liquid crystal display 1. If the liquid crystal display 1 is in the power-on state and PoE + operation or UPoE operation (normal operation state), the LED 7 is displayed in blue. If the liquid crystal display 1 is in a power-on state and PoE operation or LLDP negotiation operation (low power consumption operation state), the LED 7 is pink. If the liquid crystal display 1 is in a power-on power saving state or no video signal is input, the LED 7 is displayed in orange. The display processing of the LED 7 will be described in detail with reference to FIG.
The liquid crystal panel 8 displays a video signal transmitted by LVDS. The liquid crystal panel backlight 81 is a light source composed of, for example, LEDs, and a backlight lighting voltage output from the power supply substrate 3 is applied. The liquid crystal panel 8 and the liquid crystal panel backlight 81 constitute a display that emits light with the power received by the power supply substrate 3. The ratio of the power consumption of the liquid crystal panel backlight 81 to the power consumption of the entire liquid crystal display 1 is relatively large. Therefore, by limiting the luminance of the liquid crystal panel backlight 81, the power consumption of the entire liquid crystal display 1 can be suitably limited. If the liquid crystal display 1 is in a power-on state and PoE + operation or UPoE operation (normal operation state), the brightness of the liquid crystal panel backlight 81 is not limited. If the liquid crystal display 1 is in a power-on state and PoE operation or LLDP negotiation operation (low power consumption operation state), the luminance of the liquid crystal panel backlight 81 is limited.

The scaler 2 processes the video signal input from the DVI terminal 4 and outputs it to the liquid crystal panel 8. The scaler 2 outputs a luminance setting value signal and a backlight ON / OFF signal to the power supply board 3 to control a backlight lighting voltage for driving the liquid crystal panel backlight 81. Further, the scaler 2 communicates with the power supply board 3 by I ² C (Inter-Integrated Circuit), and further receives 1-bit PoE status information from the power supply board 3.

FIG. 2 is a diagram showing a configuration of the power supply board 3 in the present embodiment.
As shown in FIG. 2, the power supply substrate 3 includes a pulse transformer 311, a diode bridge 312, a transformer 313, a rectifying / smoothing element 314, a DC / DC converter 315, a regulator 316, and a backlight voltage output rectifying circuit 317. And. The power supply board 3 further includes a PD controller 32, an Ethernet (registered trademark) microcomputer 33, and a PWM controller 34. Hereinafter, the Ethernet (registered trademark) microcomputer 33 is referred to as an “Ethernet microcomputer 33”.
The pulse transformer 311 separates the power supplied from the power supply device 9 and the transmitted signal, supplies the power to the diode bridge 312, and transfers the signal to the Ethernet microcomputer 33.

The diode bridge 312 converts the polarity of the input DC voltage and applies it to the transformer 313 and the PD controller 32.
The transformer 313 is a pulse power supply for generating a DC + 12V power supply. The transformer 313 is connected to the rectifying / smoothing element 314 and the PD controller 32.
The rectifying / smoothing element 314 is, for example, a field effect transistor and an electrolytic capacitor, and smoothes and rectifies the voltage applied by the transformer 313. The DC + 12V power source rectified by the rectifying / smoothing element 314 is supplied to the DC / DC converter 315 and the backlight voltage output rectifying circuit 317.
The DC / DC converter 315 converts a DC + 12V power source into a DC + 5V power source. This DC + 5V power supply is supplied to the regulator 316 and also to each part of the liquid crystal display 1.

The regulator 316 generates DC + 3.3V power for operating each part of the liquid crystal display 1 from the DC + 5V power converted by the DC / DC converter 315. This DC + 3.3V power supply is supplied to the Ethernet microcomputer 33.
The PD controller 32 performs control for receiving power supply from the power supply device 9 (PSE) illustrated in FIG. 1 and is a determination unit that determines the power supply capability of the power supply device 9. The PD controller 32 is connected to the diode bridge 312 and the transformer 313, and outputs a PoE status signal to the Ethernet microcomputer 33. The PoE status signal is a 1-bit signal and is H level during PoE + operation or UPoE operation (normal operation state), and L level during PoE operation or LLDP negotiation operation (low power consumption operation state). It is.

The Ethernet microcomputer 33 is connected to the pulse transformer 311 and transmits / receives a signal to / from the power supply device 9 and is a determination unit that determines the power supply capability of the power supply device 9. The Ethernet microcomputer 33 performs an inquiry response to the MAC address from the scaler 2 and an inquiry response of the firmware version by communicating with the scaler 2 through I ² C. The Ethernet microcomputer 33 further receives the PoE status from the PD controller 32 and outputs the PoE status to the scaler 2.
The PWM controller 34 performs feedback control of the backlight voltage output rectifier circuit 317. The PWM controller 34 outputs a PWM signal to the backlight voltage output rectifier circuit 317. When a backlight ON signal is input from the scaler 2 (see FIG. 1), the PWM controller 34 outputs a PWM lighting signal having a predetermined duty so that a backlight lighting voltage corresponding to the magnitude of the luminance setting value signal is output. Is output to the backlight voltage output rectifier circuit 317.
The backlight voltage output rectifier circuit 317 generates a DC voltage for lighting the liquid crystal panel backlight 81 from a DC + 12V power source. The backlight voltage output rectifier circuit 317 generates a backlight lighting voltage according to the duty of the PWM signal output from the PWM controller 34. Thereby, the brightness of the liquid crystal display 1 can be controlled.

FIG. 3 is a flowchart showing processing of the liquid crystal display 1 in the present embodiment.
As shown in FIG. 1, when the liquid crystal display 1 is connected to the power supply device 9, the processing of FIG. 3 is started. At this time, luminance information when sufficient power is supplied to the liquid crystal display 1 is stored as “original luminance” information in a nonvolatile storage unit (not shown) of the scaler 2.
Steps S10 to S15 are classification phases.
In step S <b> 10, the PSE (power feeding device 9) detects the PD controller 32 (see FIG. 2) that is a power receiving device.
In step S11, the PSE (power feeding device 9) performs event classification. If the event is one event, the process branches to step S12. If the event is two events, the process branches to step S14.
In step S <b> 12, the PSE (power supply device 9) starts 15.4 W power supply.
In step S13, the scaler 2 starts to operate at a luminance at which the LCD consumes power of 12.95 W or less, and branches to the process of step S16.

In step S <b> 14, the PSE (power supply device 9) starts 30.0 W power supply.
In step S15, the scaler 2 starts to operate at a luminance at which the LCD consumes less than 25.5W, and branches to the process in step S16.

Steps S16 to S21 are LLDP phases. In this LLDP phase, it is possible to set the LLDP update frequency, the holding time until information is discarded, and the initialization delay time. Further, default values are determined for these pieces of information, and the information can be changed by a predetermined procedure.
In step S <b> 16, the Ethernet microcomputer 33 performs LLDP negotiation by communication with the PSE (power feeding device 9) and requests the necessary power. By this negotiation, the Ethernet microcomputer 33 can know the power that can be supplied by the PSE.
In step S17, the Ethernet microcomputer 33 determines whether or not the PSE (power supply device 9) can supply the required power. Here, the required power is a predetermined value defined in the standard, and is, for example, a maximum of 51 W for UPoE and a maximum of 25.5 W for PoE +.
The PSE notifies the Ethernet microcomputer 33 of the power supply capability. If the Ethernet microcomputer 33 determines that the power supply capability notified by the PSE is greater than or equal to the required power, and therefore determines that the required power can be supplied (Yes), the Ethernet microcomputer 33 performs the process of step S18, and the power supply capability of the PSE is less than the required power. Therefore, if it is determined that the required power cannot be supplied (No), the process of step S20 is performed.
In step S18, the Ethernet microcomputer 33 instructs the scaler 2 to change the liquid crystal panel backlight 81 (LCD) to the original luminance.
In step S19, the scaler 2 operates the liquid crystal panel backlight 81 (LCD) with the original luminance, returns to the process of step S16, and repeats these processes at a predetermined LLDP update frequency.

In step S20, the Ethernet microcomputer 33 notifies the scaler 2 of power that can be used by itself. However, the Ethernet microcomputer 33 may notify the scaler 2 of the power that can be supplied by the PSE (power supply device 9).
In step S21, the scaler 2 operates at a luminance at which the liquid crystal panel backlight 81 (LCD) is less than or equal to the usable power. When the process of step S21 ends, the process returns to step S16, and these processes are repeated.
By controlling in this way, the scaler 2 can turn on the liquid crystal panel backlight 81 even before the Ethernet microcomputer 33 is supplied with 30 W from the PSE (power feeding device 9). Further, the scaler 2 can set the luminance limit according to the power supply capability of the power supply device 9 if the power supply capability of the power supply device 9 changes.

FIG. 4 is a flowchart showing processing of the Ethernet microcomputer 33 in the present embodiment.
If the liquid crystal display 1 is connected to the power supply device 9 and 15.4 W is supplied, the Ethernet microcomputer 33 starts the processing of FIG.
In step S30, the Ethernet microcomputer 33 initializes itself. In this initialization process, negotiation between the IEEE 802.3at standard and the UPoE standard is executed.
In step S31, the Ethernet microcomputer 33 transmits UPoE correspondence information to the PSE (power feeding device 9). As a result, the Ethernet microcomputer 33 can immediately start communication negotiation by LLDP without waiting for a frame from the PSE side when itself (the liquid crystal display 1) is connected to the PSE.
In step S32, the Ethernet microcomputer 33 receives a frame from the PSE (power feeding device 9).

In step S33, the Ethernet microcomputer 33 determines whether an LLDP frame has been detected. If the Ethernet microcomputer 33 detects an LLDP frame (Yes), it performs step S34. If it does not detect an LLDP frame (No), it performs step S39.
In step S34, the Ethernet microcomputer 33 analyzes the received frame.
In step S35, the Ethernet microcomputer 33 determines whether or not the PSE (power feeding device 9) is UPoE compatible. If it is determined that the PSE is UPoE compatible (Yes), the Ethernet microcomputer 33 performs the process of step S36. If the PSE is determined not to be UPoE compatible (No), the Ethernet microcomputer 33 performs the process of step S39.

In step S36, the Ethernet microcomputer 33 transmits the frame of the current phase in LLDP to the PSE.
In step S37, the Ethernet microcomputer 33 determines whether or not communication of a predetermined frame has been completed. The Ethernet microcomputer 33 performs the process of step S38 if the communication of the predetermined frame is completed (Yes), and performs the process of step S39 if the communication of the predetermined frame is not completed (No).
In step S38, the Ethernet microcomputer 33 notifies the scaler 2 that 60W power supply is possible by the PoE status.
In step S39, the Ethernet microcomputer 33 determines whether 30 seconds have elapsed after transmission. If 30 seconds have not elapsed after transmission (No), the Ethernet microcomputer 33 returns to the process of step S32, and if 30 seconds have elapsed after transmission (Yes), the Ethernet microcomputer 33 returns to the process of step S31. Hereinafter, the Ethernet microcomputer 33 periodically repeats the processes of steps S31 to S39 at intervals set by the LLDP update frequency. The LLDP update frequency has a default value of 30 seconds and can be changed by a predetermined procedure. Thereby, the Ethernet microcomputer 33 can periodically communicate with the power supply device 9 to determine the power supply capability if the liquid crystal display 1 is connected to the power supply device 9.

While the liquid crystal display 1 is being driven, the Ethernet microcomputer 33 periodically repeats communication negotiations with the power supply apparatus 9 by LLDP. Thereby, even when the liquid crystal display 1 is limited in luminance because sufficient power is not supplied from the power supply device 9, sufficient power is supplied when the power supply capability of the power supply device 9 is increased. Therefore, it is possible to cancel the brightness limitation of itself. The cancellation of the luminance restriction includes, for example, making the luminance fixed to the minimum luminance variable.
Similarly, the liquid crystal display 1 continues its operation by limiting the luminance according to the available power even when the power supply capability of the power supply device 9 is reduced and sufficient power is not supplied. can do. This luminance limitation includes, for example, fixing the luminance to the minimum luminance and making it unchangeable.

FIG. 5 is a flowchart showing LED display processing of the scaler 2 in the present embodiment.
If the liquid crystal display 1 is connected to the power supply device 9 and 15.4 W is supplied, the Ethernet microcomputer 33 starts the LED display process of FIG.
In step S40, the scaler 2 determines whether or not it is in a power saving state. If the scaler 2 is in the power save state (Yes), the process of step S42 is performed. If the scaler 2 is not in the power save state (No), the process of step S41 is performed.
In step S41, the scaler 2 determines whether a video signal is input. If it is determined that the video signal is input (Yes), the scaler 2 performs the process of step S43. If it is determined that the video signal is not input (No), the scaler 2 performs the process of step S42.

In step S42, the scaler 2 displays the LED 7 in orange, and the process returns to step S40.
In step S43, the scaler 2 determines the PoE status. If it is determined that the PoE status is PoE operation or LLDP negotiation, the scaler 2 performs the process of step S44. If the PoE status is determined to be PoE + operation or UPoE operation, the scaler 2 Process.
In step S44, the scaler 2 displays the LED 7 in pink, and the process returns to step S40.
In step S45, the scaler 2 displays the LED 7 in blue, and the process returns to step S40.
As a result, the liquid crystal display 1 can display information according to its own luminance limit by the scaler 2.

FIG. 6 is a diagram showing an OSD setting screen in the present embodiment.
The OSD setting screen shown in FIG. 6 is displayed on the liquid crystal panel 8. The scaler 2 displays this OSD setting screen when it is detected that one of the left and right cursor keys is pressed. This OSD setting screen shows a case where the power supply device is PoE compatible and the usable power of the liquid crystal display 1 is 12.95 W.

The icon on the left side of the upper row indicates a speaker. The bar graph on the right side of the speaker icon indicates the speaker volume setting.
The icon on the left side of the middle row indicates the luminance setting, and is invalid displayed in FIG. The bar graph on the right side of the luminance setting icon indicates the luminance setting of the liquid crystal panel backlight 81, and is invalid displayed in the same manner as the luminance setting icon. Due to the invalid display of the brightness setting, the liquid crystal display 1 indicates to the user that the current brightness cannot be changed.
The icon on the left side of the lower row indicates a power switch. The bar graph on the right side of the power switch icon indicates the setting of the off timer time. In this example, “OFF” is displayed, so the off timer is not set.

FIG. 7 is a diagram illustrating an OSD setting screen according to the modification.
The liquid crystal display 1 according to the modification has a brightness setting range of 0 to 50 when the connected power supply device 9 is compatible with PoE +, and a brightness setting range of 0 to 100 when the connected power supply device 9 is compatible with UPoE. is there.
In the scaler 2 of the modified example, if the power supply device 9 to be connected is PoE + compatible and the brightness of the liquid crystal panel backlight 81 is limited, the brightness setting range on the manual setting screen of the liquid crystal panel backlight 81 is set to 0. To 50. As a result, the liquid crystal display 1 can indicate to the user that the brightness of the liquid crystal panel backlight 81 is not a failure and that the brightness of the liquid crystal panel backlight 81 is limited.
The OSD setting screen shown in FIG. 7 shows a case where the power supply device is PoE + compatible and the usable power of the liquid crystal display 1 is 25.5 W. The luminance of the liquid crystal display 1 is set to a maximum of 50. At this time, the liquid crystal display 1 is instructed by the user to further increase the brightness setting by pressing the right cursor key.
As shown in FIG. 7, the brightness setting icon in the middle row and the brightness bar graph are displayed effectively. As the right cursor key is pressed, guidance is displayed on the display screen below the bar graph. This guidance can be set to a maximum luminance of 50 or more when connected to a UPoE compatible device, and the wording “Connecting IEEE802.3at compatible device” indicating the power supply capability of the power supply device 9 and further increasing the maximum luminance. "Is included. Thereby, the liquid crystal display 1 can indicate to the user the cause of the current brightness limitation and the solution to the problem.

The present invention is not limited to the above-described embodiment, and can be modified without departing from the spirit of the present invention. For example, there are the following (a) to (d).
(A) The display of the present invention is not limited to the liquid crystal system, and may be applied to a cathode ray tube system, an organic EL (Organic Electro-Luminescence) system, a plasma system display, or the like.

(B) The power over Ethernet (registered trademark) -supported power receiving apparatus of the present invention is not limited to UPoE standard negotiation, and may transmit and receive frames for IEEE802.3at standard negotiation. Thus, the present invention can be applied to an apparatus that can be driven with 25.5 W of electric power.
(C) The power over Ethernet (registered trademark) power receiving device of the present invention and the power saving mode thereof are not limited to the luminance limitation in the liquid crystal display. For example, speaker volume limitation or mute on display, volume limitation on IP phone, radio wave intensity limitation on wireless LAN access point, illumination light amount limitation on WEB camera, frame rate limitation on WEB camera, pixel on WEB camera It may be applied to a number limit.
(D) The liquid crystal display 1 displays the information according to the brightness limitation not limited to the LED 7, but may be displayed on the liquid crystal panel 8 by OSD, or may be notified by sound or warning sound through a speaker. . Thereby, it is easier to understand than indicated by the color of the LED 7, and it is possible to notify the user of the luminance limitation.

1 Liquid crystal display (power receiving device)
2 Scaler (control unit)
3 Power supply board (Power receiving part)
311 Pulse transformer 312 Diode bridge 313 Transformer 314 Rectifier smoothing element 315 DC / DC converter 316 Regulator 317 Backlight voltage output rectifier circuit 32 PD controller (determination unit)
33 Ethernet microcomputer (Judgment part)
34 PWM controller 4 DVI terminal 5 Storage unit
6 Switch board 7 LED (Display section)
8 LCD panel (display, display)
81 LCD panel backlight (display, display)
9 Power supply device

Claims (11)

A power receiving unit that receives power supply from a power supply device via a network cable;
An output unit that performs a predetermined output by the power received by the power reception unit;
A determination unit for determining the power supply capability of the power supply device;
If it is determined that its power consumption than feeding capacity of the feeding device is large, and a control unit that limits the maximum output by the output unit in accordance with the power supply capacity of the pre-Symbol power supply device,
A display unit for displaying information on the maximum output limited by the control unit;
A power over Ethernet (registered trademark) -supported power receiving device. If it is detected that the determination unit is connected to the power supply device, the determination unit transmits a communication frame for negotiating the power supply capability to the power supply device.
The power over Ethernet (registered trademark) -supported power receiving device according to claim 1. If the determination unit is connected to the power supply device, it periodically communicates with the power supply device to determine the power supply capability,
Wherein, if the feeding capacity of the feeding device is changed, limiting the maximum output by the output unit in accordance with the power supply capacity of the pre-Symbol power supply device,
The power over Ethernet (registered trademark) -supported power receiving device according to claim 1. A power receiving unit that receives power supply from a power supply device via a network cable;
An output unit that performs a predetermined output by the power received by the power reception unit;
A determination unit for determining the power supply capability of the power supply device;
If it is determined that its power consumption than feeding capacity of the feeding device is large, and a control unit that limits the maximum output by the output unit in accordance with the power supply capacity of the pre-Symbol power supply device,
A display unit for displaying information on the maximum output limited by the control unit ;
A display compatible with Power over Ethernet (registered trademark). If the determination unit is connected to the power supply device, it periodically communicates with the power supply device to determine the power supply capability,
Wherein, if the feeding capacity of the feeding device is changed, limiting the maximum output by the output unit in accordance with the power supply capacity of the pre-Symbol power supply device,
5. The power over Ethernet (registered trademark) compatible display according to claim 4. The output unit is a display that emits light with the power received by the power receiving unit ,
Wherein the control unit limits the brightness of the display,
5. The power over Ethernet (registered trademark) compatible display according to claim 4. The output unit is a speaker that operates with the power received by the power receiving unit ,
Wherein the control unit limits the volume of the speaker,
5. The power over Ethernet (registered trademark) compatible display according to claim 4. When the maximum output by the output unit is limited , the control unit displays the setting item of the maximum output by the output unit in the manual setting screen as invalid.
5. The power over Ethernet (registered trademark) compatible display according to claim 4. If the maximum output by the output unit is limited , the control unit limits the settable range of the setting item of the maximum output by the output unit in the manual setting screen,
5. The power over Ethernet (registered trademark) compatible display according to claim 4. The control unit also displays the power supply capability of the power supply apparatus determined by the determination unit in the setting item of the maximum output by the output unit in the manual setting screen,
5. The power over Ethernet (registered trademark) compatible display according to claim 4. Wherein the control unit has a maximum output is limited by the output unit in accordance with the power supply capacity of the pre-Symbol feeding apparatus, and, in the manual setting screen, the upper limit of the setting items can be set range of the maximum output by the output unit Display guidance when instructed to exceed,
The power over Ethernet (registered trademark) compatible display according to any one of claims 8 to 10, wherein the display is compatible with the power over Ethernet (registered trademark).

Images