Description
Arrangement comprising a first electronic device and a power supply unit and method for operating an electronic device
The present application relates to an arrangement comprising a first electronic device and a power supply unit adapted to provide the first electronic device with electrical operating energy from a mains voltage. More particularly, the present application relates to electronic devices having at least one energy saving state.
Many electronic devices make use of an internal or external power supply unit for the provision of electrical operating energy from a mains voltage. For example, computer screens, such as LCD monitors, printers or scanners are usually connected to a mains voltage for operation. Often such electronic devices comprise at least one energy saving state, in which most of the functionality of the device is disabled. In such energy saving states, the electric power consumption of the electronic device is greatly reduced. For example, an LCD monitor having a typical power consumption of 40 W when in operation, may only consume power of 2 to 4 W in a so-called stand-by mode by deactivating a background illumination unit and/or a scaling unit.
However, even in stand-by or other energy saving states, the electronic device still needs to be supplied with at least some electrical energy. This is partly so because the elec- tronic device needs to monitor input elements or connections in order to determine whether it is time to return to a full operating mode. For example, a printer may monitor a network port to observe if there is any new print job available.
Because power supply units typically have a lower efficiency, if only a fraction of the nominal output power is consumed, the total loss of energy in stand-by mode may be substantial.
It is one object of the present invention to reduce the energy consumption of electronic devices in an energy saving state. It is a particular challenge to improve the energy consumption of electronic devices in an energy saving state to zero or close to zero Watt.
According to a first embodiment of the invention, an arrangement comprising a first electronic device and a power supply unit adapted to provide the first electronic device with electric operating energy from a mains voltage is provided. Therein, the first electronic device comprises an evaluation unit coupled to the power supply unit and adapted to switch the first electronic device from an operating state into at least one energy saving state, and vice-versa. It is further adapted to turn off the power supply, if the first electronic device is switched into the energy saving state, and to turn on the power supply if the first electronic device is switched into the operating state. The first electronic device further comprises a standard interface for connecting the first electronic device to a second electronic device, the standard interface being adapted to supply the evaluation unit with electric auxiliary energy received from the second electronic device.
By enabling an evaluation unit to switch off a power supply unit in at least one energy saving state, the power consumption of the power supply unit can be reduced to zero. Furthermore, in order to enable continued operation of the
evaluation unit, an auxiliary electric energy is provided from a second electronic device by means of a standard interface .
According to an advantageous embodiment, the standard interface includes an auxiliary voltage line, and the evaluation unit is connected to the auxiliary voltage line. Such auxiliary voltage lines are available in many standard interfaces, such as graphics interfaces or peripheral interfaces and en- able to provide the evaluation unit with the auxiliary energy in an easy and power-efficient way.
According to a further embodiment, the evaluation unit is coupled with a timer for determining an idle period of the first or second electronic device. In a further embodiment, the timer is arranged in the second electronic device and the coupling with the evaluation unit is implemented via the standard interface. By providing a timer, either in the first or second electronic device, coupled with the evaluation unit, an energy saving state may be activated by the evaluation unit after a predetermined period of time.
According to a further advantageous embodiment, the standard interface is a graphics interface, for example a VGA, a DVI, HDMI, a display port or a SCART/AV interface, adapted to connect the first electronic device with the second electronic device, the second electronic device being a computer or a receiver .
In an arrangement comprising an image source such as a computer, a receiver or another electronic device connected by means of a graphics interface, the image source usually controls and provides signals for the activation and deactiva-
tion of energy saving states of the first electronic device. In this case, auxiliary energy from the image source may be used to supply the first electronic device with the required electric auxiliary energy.
According to a further advantageous embodiment, the first electronic device is a display device, comprising a display screen and a scaling unit, wherein the scaling unit is coupled to the graphics interface and the display screen, the scaling unit being adapted to generate an output signal for the display screen based on a graphics signal received from the graphics interface. According to a further embodiment, the evaluation unit is integrated into the scaling unit. By integrating the evaluation unit into a display device in gen- eral, or into a scaling unit in particular, the evaluation unit can be included in the electronic comprised in an ordinary display device.
According to a further embodiment, the scaling unit comprises a microcontroller connected to the graphics interface for supplying the microcontroller with an operating energy in the power saving state, wherein the microcontroller is adapted to perform the function of the evaluation unit. According to a further embodiment, the microcontroller is further adapted to generate at least one control signal for the scaling unit in the operating mode.
By providing a microcontroller in the scaling unit, the evaluation unit can be easily implemented. In particular, if a microcontroller used to generate control signals in the operating mode is also used to control the power supply in the energy saving mode, no further components are needed to implement the evaluation device.
According to a further advantageous embodiment, the power supply comprises a switching element for controlling the power supply unit connected to the first electronic device, and the evaluation unit is adapted to open the switching element in the energy saving state. By opening the switching element in the energy saving state, the power supply unit can be deactivated.
According to a further advantageous embodiment, the switching element is arranged in a primary supply line arranged between a mains voltage and a power supply unit, and the power supply unit is turned off by opening the switching element. According to a further embodiment, the switching element comprises a relay for electrically disconnecting the mains voltage from the power supply unit. By using a switching element arranged in a primary supply line, for example a relay, the power supply unit can be electrically disconnected from the mains voltage .
According to a further embodiment, a bypass switch is arranged in parallel to the switching element, adapted to connect the power supply unit with the mains voltage. By using a bypass switch, the power supply unit may be reactivated manu- ally.
According to a further advantageous embodiment, the power supply unit comprises a switching power converter and the switching element comprises at least one semiconductor switch for controlling the duty cycle of the switching power converter using a pulse width modulated control signal, and the power supply unit is turned off by deactivating the pulse width modulated control signal. By deactivating a pulse width
modulated control signal, a switching power converter can be switched off without the need for any further components in the power supply unit.
According to a further embodiment, the pulse width modulated control signal is provided by a microcontroller of the evaluation unit. By integrating the generation of the pulse width modulated control signal with the other functionality of the evaluation unit, the number or components required to implement the arrangement with the energy saving state can be further reduced. In fact, in an electronic device already comprising a microcontroller controlled switching power supply, no further electrical components may be required.
According to second aspect, a method for operating a first electronic device having a power saving state and an operating state is provided. The method comprises the steps of:
receiving electric auxiliary energy from a second elec- tronic device by means of a standard interface connecting the first and the second electronic device,
operating an evaluation unit of the first electronic device with the received electric auxiliary energy,
detecting an activation signal using the evaluation unit, and
switching the first electronic device in the operating state by activating a power supply unit coupled to the evaluation unit for providing the first electronic device with electric operating energy.
The method steps detailed above enable the activation of the first electronic device from an energy saving state without the need for a power supply unit of the first electronic device being powered all the time.
Further advantageous embodiments are described in the claims attached hereto and in the following detailed description.
An embodiment of the present invention is described with ref- erence to the following figures.
FIG. 1 shows a schematic illustration of an arrangement comprising a first and a second electronic device.
FIG. 2 shows a flow chart of a method for operating the first electronic device.
FIG. 1 shows an arrangement 1 comprising a first electronic device 2. The first electronic device 2 is coupled with a second electronic device 3. The second electronic device 3 may be, for example, a computer or similar electronic device. The first electronic device 2 may be a peripheral electronic device, for example a computer monitor or a printer.
The first electronic device 2 and the second electronic device 3 are coupled by one or more standard interfaces 4. In the embodiment shown in FIG. 1, four standard interfaces 4a to 4d are available for connecting the first electronic device 2 with the second electronic device 3. For example, the first standard interface 4a may be a display port interface, the second standard interface 4b may be a VGA interface, the third standard interface 4c may be a DVI interface, and the fourth standard interface 4d may be an HDMI interface.
FIG. 1 further shows that the first electronic device comprises four first connectors 5a to 5d and that the second electronic device 3 comprises four second connectors 6a to 6d corresponding to the standard interfaces 4a to 4d, respectively. However, in practice, the first electronic device 2 and the second electronic device 3 may have different numbers and types of standard interfaces 4 and first and second connectors 5 and 6, respectively. For the arrangement 1 to oper- ate in accordance with the invention, it suffices if one compatible standard interface 4 is shared by the first and second electronic device 2 and 3.
The first electronic device 2 is connected with a power sup- ply unit 7, which may be internal or external to the first electronic device 2. The power supply unit 7 couples the first electronic device 2 with a mains voltage 10. For this purpose, the power supply unit 7 comprises an AC/DC power module 11, a latching relay 12, a switch 13, and a capacitor 14.
The relay 12 or the switch 13 may be used to connect the AC/DC power module with one or two contacts of the mains voltage 10. If both the switch 13 and the relay 12 are opened, the AC/DC power module 11 is physically disconnected from the mains voltage 10 and hence will consume no electrical energy. By opening the switch 13, the first electronic device can be put into a energy saving mode as described below, by closing it, it operates like a conventional device.
The first electronic device 2 comprises a sealer board 8 and an LCD panel 9. The sealer board 8 comprises a sealer chip 15, a DC/DC converter 16 and a microcontroller 17. The sealer
chip 15 is adapted to scale analog or digital data received from one of the standard interface 4a to 4d in order to generate appropriate driving signals for the LCD panel 9. For example, the integrated circuit MST 6251DA-LF-165 by MStar may be used. The DC/DC converter 16 is adapted to convert an auxiliary voltage VAUX provided from one of the standard interfaces 4a to 4d to an operational voltage VCc provided to the microcontroller 17.
The microcontroller 17 is adapted to monitor interrupt lines 18 and 19 connected to the standard interfaces 4 and the AC/DC power module 11, respectively. The first interrupt line 18 is connected, for example, to a vertical and/or horizontal synchronization signal which is part of one or several of the standard interfaces 4a to 4d. If the microcontroller 17 observes an interrupt on the first interrupt line 18, for example a falling or rising flank because a horizontal and/or vertical synchronization signal is provided via the VGA interface 4b, it may close the relay 12 of the power supply unit 7 by means of a control line 20. The second interrupt line 19 indicates whether the AC/DC power module 11 is provided with an AC input voltage, i.e. the mains voltage 10. That is, the second interrupt line 19 indicated whether the relay 12 or the switch 13 are closed. If the second interrupt line 19 indicates an AC power, the first electronic device is switched into an operating state by the microcontroller 17. Otherwise, it is switched into a energy saving state, in which the microcontroller is either supplied by the second electronic device 3 with auxiliary energy only or completely switched off.
If, for example the switch 13 is closed, the microcontroller 17 may also close the relay 12 to permanently activate the
power supply unit 7 independently from the second electronic device 3. In this way, the microcontroller 17 may activate the power supply unit 7, which was previously disconnected from the mains voltage 10 in order to power up the first electronic device 2 in general and the sealer board 8 in particular. Conversely, if the microcontroller 17 detects by means of the first interrupt line 18 or by means of a idle- timer, that the first electronic device 2 should be deactivated, it may open the relay 12 by means of the control line 20 and consequently isolate the AC/DC power module 11 from the mains voltage 10. In order to operate the microcontroller 17 independently from the power supply unit 7, a low energy microcontroller 17 should be used, for example a Myson CS8955 microcontroller.
The microcontroller 17 may be used to control and provide the energy for the operation of the relay 12 directly, i.e. without a further amplification circuit. In such an arrangement, the capacitor 14 may be used to supply the energy needed for the state change of the latching relay 12. Typical microcontroller electrical current driving capability, i.e. their power output, is limited and may not be sufficient for the relay operation, i.e. a latching relay state change. For example, the relay coil latching power draw is typically 150 mW to 200 mW. The maximum output power of a general purpose output pin of a microcontroller is typically less than the needed power for the relay latching. For example, its power output is less than 40 mW typically. In order to overcome this discrepancy, the serial capacitor 14 arranged parallel to latching relay 12 may be charged by the microcontroller 17. Then, the serial capacitor finally provides the previously stored power necessary for the relay latching operation .
- l i ¬
lt should be noted that for display devices in particular, well-established energy saving modes exist. In particular, in the VESA DPMS sleep mode, an electrical auxiliary energy is provided by a graphics component of a computer. In this mode, the power supply unit 7 of the first electronic device 2, e.g. an LCD monitor, may be deactivated, limiting the power consumption of the first electronic device to the electrical auxiliary energy, e.g. to below 250 mW. In VESA DPMS off mode, i.e. if the computer is switched into standby or completely turned off, the electrical auxiliary energy is also tunred off, thus reducing the energy consumption of the first electrical device to zero. Nevertheless, the first electronic device 2 may be woken up and turned into the operating state without any user interaction as described below.
FIG. 2 shows a flow chart of a method for operating the first electronic device 2 according to an embodiment of the invention .
In a first step 21, an auxiliary voltage VAUX is received by means of a standard interface 4 connecting the first electronic device 2 to a second electronic device 3. For example, the display port connector 5a receives a voltage of 3.3 V with a maximum load of 500 mA on pin 20. The VGA connector 5b receives an auxiliary voltage of 5 V with a maximum load of 50 mA on pin 8. The DVI connector 5c receives an auxiliary voltage of 5 V and a maximum load of 50 mA on pin 14. The HDMA connector 5d receives an auxiliary voltage of 5 V and a maximum load of 50 mA on pin 18. In this way, an auxiliary energy of at least 250 mW can be obtained by means of any one of the standard interfaced 4a to 4d.
Other types of standard interfaces may also provide auxiliary voltages. For example, an USB port often used to connect other peripheral devices to a computer system provides a voltage of 5 V on pin 1. Other standard interfaces such as serial or parallel ports or IEEE 1394 interfaces also provide voltages of 3.3 or 5 V. In addition, electrical energy comprised in other types of signals, such as a clock signal, may be converted into an auxiliary electrical energy, for example by rectifying an alternating current component or smoothing a modulated signal into a direct current.
In a second step 22, an evaluation unit of the first electronic device 2 is operated. In the exemplary embodiment shown in FIG. 1, the microcontroller chip 17 acts as an evaluation unit and is operated using the auxiliary energy received from one of the standard interfaces 4. In order to match the auxiliary voltage VAUX received from any one of the first connectors 5a to 5d to the power requirements of the microcontroller 17, the DC/DC converter 16 is used. For exam- pie, a down converter converting the various auxiliary voltages provided by the first connectors 5a to 5d down to a common voltage of 3 V may be used.
In a power saving mode, that is when the power supply unit 7 is deactivated, only very few functional elements of the first electronic device 2 in general and the sealer board 8 in particular are provided with the auxiliary power generated by the DC/DC converter 16. In particular, the sealer chip 15 is completely deactivated. The microcontroller 17 may be op- erated at a lower voltage or lower operating frequency than in a fully switch-on mode. In addition, further components of the sealer board 8 not shown in FIG. 1, such as analog to
digital converters of low-voltage differential signaling circuits may be deactivated.
In a further step 23, the evaluation unit detects an activa- tion signal. For example, the microcontroller 17 might detect that a synchronization signal is provided via one of the standard interfaced 4a to 4d by means of the first interrupt line 18. Alternatively, another activation signal may be received from the power supply unit 7 itself or from a timer circuit integrated into the microcontroller 17. In a further embodiment, the microcontroller 17 activates the power supply unit 7 and the sealer board 8 at predetermined time intervals in order to actively supervise one of the standard interfaces 4a to 4d, if no wake-up signal in form of a synchronization signal is provided by the second electronic device 3 via the standard interfaces 4a to 4d, .
In a further step 24, the power supply unit 7 is switched on. For example, the AC/DC power module 11 may be connected to the mains voltage 10. According to the embodiment shown in FIG. 1, the relay 12 is closed. Preferably, the relay 12 is implemented as a latching optoelectrical relay, a solid state relay, or an electromechanical latching type relay. Latching relays have the advantage that they do not require energy in order to remain in a particular switching state. Use of an optoelectrical relay or solid state relay has the advantage that the wear of the relay is greatly reduced with respect to electromechanical relay. Consequently, the operation of the relay 12 can be guaranteed over a longer period of time. As detailed above, in a first phase, a capacitor 14 may be charged before, in a second phase, the relay 12 is switched using the previously stored energy.
In a further step 25, the power supply unit provides an operating voltage V3 to the electronic device 2. In particular, the AC/DC power module 11 generates a supply voltage V3 to operate the sealer board 8. The evaluation unit, for example the microcontroller 17, also receives a feedback signal from the AC/DC power module 11 to confirm that the power supply unit 7 is now switched on and the first electronic device 2 is in an operational mode. In this mode, the microcontroller 17 may continue to monitor the standard interfaced 4a to 4d in order to detect the switch-off signal received from the second electronic device 3. In this case, the evaluation unit 4 may deactivate the power supply unit 7 by means of the control line 20 and the relay 12. This step is not, however, shown in FIG. 2.
In a preferred embodiment, the microcontroller 17 controls the operation of the AC/DC power module 11. In particular, the AC/DC power module 11 may comprise a switching power converter and the microcontroller 17 may provide a pulse width modulated control signal via a general purpose I/O (GPIO) pin in order to regulate the switching power converter. In order to enable a closed loop control of the switching power supply, a feedback pin from the power supply 7, such as the control line 19 may be used to control the operation of the AC/DC power module 11.
In the energy saving mode, if the power supply unit 7 is to be deactivated, the microcontroller 17 may completely deactivate the pulse width modulated control signal and conse- quently deactivate the power supply unit 7. In this case, no additional relay 12 may be required in the power supply unit 7. Of course, also a combination of both techniques may be applied. For example, a relay 12 arranged between the AC
mains voltage 10 and an input of the AC/DC power module 11 and a switching element arranged at or close to the output of the AC/DC power module 11 may be deactivated by the microcontroller 17.
Furthermore, the power supply unit 7 may be internal or external to the first electronic device 2. Finally, functional elements shown as separate components in FIG. 1 may be integrated into one semiconductor circuit or separated into sev- eral semiconductor circuits. For example, the functionality of the sealer chip 15 and the microcontroller 17 may be integrated into one common chip, as long as the functional area responsible for the scaling of the received data signal can be deactivated.
Finally, the circuit and method described above are not restricted to an arrangement comprising a computer and a connected monitor or other peripheral devices. Equally, they may be used with any arrangement comprising a first electronic device acting as a slave and a second electronic device acting as a master.