JP2016012231A - Method for managing power consumption of function extension device, portable electronic apparatus, and function extension device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To manage power consumption of a cable dock according to power management policy of a notebook PC.SOLUTION: A notebook PC 10 is connected to a cable dock 100 which extends a function of the PC by a cable 102. The notebook PC holds a power management standard including a cable dock. The power management standard defines parameters, such as a power source mode which consists of a combination of AC power sources 81 and 181 and DC power sources 83 and 183, rated capacity, residual capacity, and power consumption of a system, and a power level indicating a degree of power saving. The notebook PC applies a status value of acquired parameters to the power management standard to identify the power level, and allows the cable dock to perform a power-saving operation.

Description

  The present invention relates to a technique in which a portable electronic device manages power consumption of a function expansion device, and further relates to a technology in which the function expansion device operates according to a power management policy of the portable electronic device.

  A function expansion device for expanding the function of a portable electronic device such as a notebook personal computer (notebook PC) is known. The function expansion device is sometimes called a docking station or a port replicator. The function expansion device is usually placed in an office or home, and a notebook PC is connected and used when the user returns from the outside. The function expansion device includes a plurality of ports, and the user can connect a display, an audio device, an input device such as a mouse and a keyboard, and an external peripheral device such as a router connected to the network. Further, the function expansion device can be used while being connected to an AC / DC adapter and charging a battery built in the notebook PC. The laptop PC is simply connected to the function expansion device, and shifts to an environment where many external peripheral devices that cannot be used alone can be easily used.

  Patent Document 1 discloses an invention for controlling output power of an AC / DC adapter that supplies power to a function expansion device in a state where a notebook PC is connected. When the output power of the AC / DC adapter increases, the function expansion device limits the charging power for the battery it owns, and further reduces the charging power for the battery held by the notebook PC when the output power increases. To the notebook PC. Patent Document 2 discloses a computer system that can continuously operate any functional module in the expansion device without being affected by the power on / off state of the computer main body mounted on the expansion unit.

  Patent Document 3 discloses an invention in which the power rating of an AC adapter or a battery is reduced by controlling power when an information processing device including a battery is connected to an external connection expansion device. This document describes that the information processing device limits the charging power of the battery when the total power consumption of the external connection expansion device, the device main body, and the battery is equal to or greater than the coincidence value. Patent Document 4 discloses an invention in which a connection state between a portable device and a docking station is monitored, and the portable device selects and operates an appropriate power consumption algorithm.

JP 2009-301281 A JP 11-345051 A JP-A-2005-321973 JP 2013-239178 A

  The conventional function expansion device is arranged in a fixed place such as an office or home, and is intended to provide a function like a desktop computer to a notebook PC. Therefore, an AC / DC adapter is connected. It is assumed to be used. At this time, the function expansion device and the notebook PC are directly connected by a large connector having a large number of pins provided at the bottom of the notebook PC. While the notebook PC operates in the docked state, power is supplied from the AC / DC adapter having a large rated power through the function expansion device, so that there is little need to limit the functions of the notebook PC to reduce power consumption. In addition, the devices constituting the function expansion device may detect the idle state and individually reduce the power consumption. However, the necessity of reducing the power consumption by cooperating with the notebook PC has been studied. There wasn't.

  As described in Patent Documents 1 and 3, the power consumption in the docking state can be reduced by limiting the functions on the notebook PC side in order to suppress the power consumption below the rated power of the AC / DC adapter. The charging power was limited. In recent years, as notebook PCs have become thinner, it has become difficult to provide a connector for connecting to a function expansion device on the bottom surface of a casing, and the number of external peripheral devices that can be used has increased. A new function expansion device of a type that is connected to a small connector provided on the side of the PC with a cable has been developed. Such a function expansion device is hereinafter referred to as a cable dock.

  Since the cable dock can be made small and light, it can be used not only in the office but also in a mobile environment with a notebook PC. In a mobile environment, the cable dock may be supplied with power from a notebook PC operating on a battery. When a notebook PC operates on a battery, it performs fine power management to increase the operating time. Conventional function expansion devices are based on the premise that they are connected to an AC / DC adapter. Therefore, no particular attention has been paid to power management, but power can be supplied from a notebook PC. It is desirable that a certain function expansion device operates in conjunction with power management of a notebook PC.

  SUMMARY OF THE INVENTION Accordingly, an object of the present invention is to provide a method for managing the power consumption of a function expansion device in accordance with the power management policy of the portable electronic device in a computer system comprising a portable electronic device and a function expansion device. It is a further object of the present invention to provide a method for optimizing the balance between the extended operating time and the reduced performance of a portable electronic device to which a function expansion device is connected. It is a further object of the present invention to provide a computer system, a portable electronic device, and a function expansion device that realize such a method.

  The portable electronic device has a power management standard that defines power-related parameters and power levels, and a first controller that acquires a parameter state value. The function expansion device has a second controller capable of communicating with the first controller and controlling the operation of the devices constituting the function expansion device according to the power level specified based on the parameter state value and the power management standard.

  With this configuration, the function expansion device can operate according to the power management policy of the portable electronic device. A portable electronic device is an information device that can improve convenience by connecting a function expansion device, and in one example, can be a notebook personal computer or a tablet terminal. The function expansion device may be either a type connected to a portable electronic device with a cable or a type directly connected with a connector. A function expansion device of a type connected by a cable can be manufactured in a small size and light weight, and is convenient for use in a mobile environment together with a portable electronic device, and the present invention can be effectively applied.

  The first controller acquires the parameter state value, specifies the power level, and instructs the second controller to specify the specified power level, thereby controlling the operation of the devices constituting the function expansion device. Alternatively, the second controller can acquire the parameter state value, specify the power level, and control the operation of the devices constituting the function expansion device. It is possible to supply power from one of the portable electronic device and the function expansion device to the other, and the power management standard is the type of power source such as an AC power source or a DC power source for the portable electronic device and the function expansion device. It is possible to include a power supply mode configured by a combination of

  The first battery unit that supplies power to the portable electronic device in a single state can supply power to the function expansion device in the connected state. Such a power supply mode generally occurs when a portable electronic device and a function expansion device operate in a mobile environment. At this time, if the parameter includes the remaining capacity of the first battery unit, the operation time can be extended and the performance of the first battery unit can be increased while operating the function expansion device according to the power management policy of the portable electronic device. The decline can be harmonized.

  The second battery unit that supplies power to the function expansion device in the single state can supply power to the portable electronic device in the connected state. Such a power supply mode generally occurs when the portable electronic device and the function expansion device operate in a mobile environment and the remaining capacity of the first battery unit is insufficient. At this time, if the parameter includes the remaining capacity of the second battery unit, the operation time can be extended and the performance of the second battery unit can be increased while operating the function expansion device in accordance with the power management policy of the portable electronic device. The decline can be harmonized.

  In the connected state, the AC power source can supply power to the portable electronic device and the function expansion device. The AC power source may be a power source of either a portable electronic device or a function expansion device in a single state. If the parameters at this time include the rated capacity of the AC power source and the power consumption of the portable electronic device, and if the rated capacity of the AC power source is insufficient, the power management policy of the portable electronic device is used. The function expansion device can be operated.

  According to the present invention, in a computer system including a portable electronic device and a function expansion device, a method for managing power consumption of the function expansion device according to the power management policy of the portable electronic device can be provided. Furthermore, according to the present invention, it is possible to provide a method for optimizing the balance between the extension of the operation time by the battery of the portable electronic device to which the function expansion device is connected and the decrease in performance. Furthermore, the present invention can provide a computer system, a portable electronic device, and a function expansion device that realize such a method.

It is a figure for demonstrating four types of power supply modes of the notebook PC 10 and the cable dock 100 in a connection state. It is a figure for demonstrating four types of power supply modes of the notebook PC 10 and the other cable dock 100a in a connection state. 2 is a functional block diagram for explaining an example of a main configuration of a notebook PC 10. FIG. 2 is a functional block diagram for explaining an example of a main configuration of a cable dock 100. FIG. 4 is a diagram for explaining an example of a configuration of a power management table 25. FIG. 5 is a diagram for explaining an example of a configuration of a device table 104. FIG. 4 is a flowchart for explaining a method of managing power consumption of the cable dock 100 based on a power management policy of the notebook PC 10.

[Overview of cable dock operation]
1 and 2 are diagrams for explaining an outline when the cable dock 100 operates in accordance with the power management policy of the notebook PC 10. In the present embodiment, when the notebook PC 10 and the cable dock 100 are connected, the cable dock 100 operates according to the power management policy of the notebook PC 10. Here, the connection state means a state in which the notebook PC 10 and the cable dock 100 are electrically connected by the signal line and the power line of the cable 102. However, the present invention can also be applied to a function expansion device of a type in which connectors are directly connected as in a conventional docking station.

  A dock connector 101 attached to the cable 102 is connected to the cable dock 100. The notebook PC 10 and the cable dock 100 can be connected by attaching connectors to both ends of the cable. On the other hand, each state when the notebook PC 10 and the cable dock 100 are separated is referred to as a single state. The power mode means the type of power source (AC power source or DC power source) that actually supplies power when the notebook PC 10 or the cable dock 100 is operating in a connected state or a single state. .

  The notebook PC 10 operates with either the AC power source 81 or the DC power source 83. The DC power source 83 corresponds to any one of a rechargeable battery unit of a type built in the casing, a type mounted in a bay of the casing, or an external type connected by a connector. The AC power source 81 corresponds to an AC / DC adapter connected to an outlet of a commercial power source. The AC power source 81 may be an AC / DC converter built in the casing of the notebook PC 10 instead of the AC / DC adapter. The AC power source 81 can charge the DC power source 83 while supplying power to the system.

  The notebook PC 10 in a single state operates in accordance with a power management policy configured with power saving operation timing, a target device, a power saving level, and the like. In the power saving operation, the operating voltage and operating frequency of the CPU are lowered, and the brightness of the display is lowered, so that the performance and convenience are lowered. When the notebook PC 10 operates with the DC power source 83, the operation time can be extended by performing the power saving operation. The notebook PC 10 operating with the DC power source 83 operates in accordance with the power management policy to balance the degradation of performance and the extension of the operation time, thereby maximizing user satisfaction.

  There are types of AC / DC adapters used in offices and types used in mobile environments. Since the AC / DC adapter of the type used in the office has a rated capacity capable of supplying sufficient power to the notebook PC, it is generally not necessary to reduce the performance of the notebook PC 10 using it. On the other hand, some AC / DC adapters dedicated for use in mobile environments are manufactured with a small rated capacity in order to prioritize weight reduction. When the notebook PC 10 operates with an AC / DC adapter having a small rated capacity, it is necessary to suppress power consumption. Also at this time, the notebook PC 10 can maximize the user satisfaction by operating in accordance with the power management policy.

  Next, power management of the connected cable dock 100 will be described. The cable dock 100 operates with either an AC power source 181 or a DC power source 183. The types of the AC power source 181 and the DC power source 183 may be the same as those described in the notebook PC 10. In the connected state, power is supplied from one to the other between the notebook PC 10 and the cable dock 100 according to the respective power mode, the rated capacity of the AC power sources 81 and 181, or the remaining capacity of the DC power sources 83 and 183. You can also. There are four patterns in the overall power mode of the notebook PC 10 and the cable dock 100 in the connected state.

  Since the cable dock 100 is an auxiliary device that expands the functions of the notebook PC 10, the user's satisfaction with the notebook PC 10 can be maximized when operated according to the power management policy of the notebook PC 10. A power management policy can be embodied as a power management standard. In one example, the power management criteria can consist of a power mode, a power management table, and a device table. They are created as one table or as a distributed table and are held by the notebook PC 10 and / or the cable dock 100.

  The connected power mode will be described in detail with reference to FIGS. As an example, in the power management table, parameters and power levels related to power can be defined for each power mode. The parameters related to the power are the rated capacity of the AC power sources 81 and 181, the power consumption of the notebook PC 10 or the total power consumption of the notebook PC 10 and the cable dock 100 (hereinafter, the total power consumption), and the DC power sources 83 and 183. Of the remaining capacity.

  Each parameter has a state value reflecting the operation state of the notebook PC 10 and the cable dock 100. The power level corresponds to the degree of power saving required for the cable dock 100 according to the state value of the parameter. The device table can define the type of power saving target and the level of power saving among the devices constituting the cable dock 100 corresponding to the power level. The degree of power saving can be defined as device enable / disable setting or depth of sleep state.

  The cable dock 100 can perform a power saving operation based on the state value, the power management table, and the device table. The notebook PC 10 can reduce power consumption of devices constituting the notebook PC 10 in conjunction with the cable dock 100 or independently of the cable dock 100 based on the conventional power management standard. This embodiment includes various methods for the cable dock 100 to operate according to the power management standard of the notebook PC 10.

  In the first method, the notebook PC 10 holds the power management table, the cable dock 100 holds the device table, and the notebook PC 10 performs confirmation of the power mode and acquisition of the state value. The notebook PC 10 instructs the cable dock 100 on the power level specified by applying the state value to the power management table. The cable dock 100 performs the power saving operation by applying the instructed power level to the device table.

  In the second method, the notebook PC 10 holds the power management table and the device table, and the notebook PC 10 performs confirmation of the power mode and acquisition of the state value. The notebook PC 10 directly instructs the devices constituting the cable dock 100 based on the state value, the power management table, and the device table to perform the power saving operation.

  In the third method, the cable dock 100 receives the power management table from the notebook PC 10 and holds it together with the device table, and the cable dock 100 confirms the power mode and acquires the state value. The cable dock 100 performs a power saving operation based on the state value, the power management table, and the device table. In the following examples, the first method will be described, but the second method and the third method can also be understood from the description of the first method.

  FIG. 1 shows four types of power modes of the notebook PC 10 and the cable dock 100 in the connected state. FIG. 1A shows the mutual AC mode in which the notebook PC 10 and the cable dock 100 are supplied with power from the AC power sources 81 and 181, respectively. The DC power source 183 of the cable dock 100 can function as an auxiliary power source when the remaining capacity of the power source 83 of the notebook PC 10 is insufficient when used in a mobile environment. When the notebook PC 10 and the cable dock 100 operate with AC power sources 81 and 181 having large rated capacities, respectively, the necessity for power management is low. Therefore, in the mutual AC mode, the notebook PC 10 may not instruct the cable dock 100 to switch the power level.

  When in the connected state, the AC power source 81 may not be physically connected. Alternatively, power may be supplied from only one of the AC power sources 81 and 181 electrically. 1B and 1C include a cable dock 100 having such a structure. In another example, the cable dock 100 may be of a type that cannot be connected to the AC power source 181. FIGS. 1B and 1D include a cable dock 100 having such a structure. Although it is a premise of the present invention that the notebook PC 10 can operate with the DC power source 27, the cable dock 100 may not include the DC power source 183 as described in FIG.

  FIG. 1B shows a state of the PC_AC mode in which the AC power source 81 is connected only to the notebook PC 10. In this case, the notebook PC 10 can operate with the AC power source 81 and the cable dock 100 can operate with the DC power source 183 while the DC power source 183 has a large remaining capacity. While operating in this state, the notebook PC 10 may not instruct the cable dock 100 to switch the power level.

  When the remaining capacity of the DC power source 183 decreases, power can be supplied from the notebook PC 10 to the cable dock 100. When the rated capacity of the AC power source 81 is large, the notebook PC 10 may not instruct the cable dock 100 to switch the power level. When the rated capacity of the AC power source 81 is small, the power consumption of the notebook PC 10 is restricted. When the notebook PC 10 starts to supply power to the cable dock 100, the power level is specified using the rated capacity of the AC power source 81 and the consumed power of the notebook PC 10 or the entire consumed power as parameters, and the cable dock 100. It is possible to instruct power level switching.

  FIG. 1C shows a dock AC mode in which an AC power source 181 is connected only to the cable dock 100. In this case, power can be supplied from the cable dock 100 to the notebook PC 10. When the rated capacity of the AC power source 181 is large, the notebook PC 10 may not instruct the cable dock 100 to switch the power level. If the rated capacity of the AC power source 181 is small and the remaining capacity of the DC power source 183 is insufficient, the notebook PC 10 can be supplemented with the power of the DC power source 83 to maintain the system performance. The remaining capacity of the DC power source 83 gradually decreases. At this time, when the remaining capacity of the DC power source 83 is insufficient, the notebook PC 10 specifies the power level using the rated capacity of the AC power source 181 and the consumed power of the notebook PC 10 or the entire consumed power as parameters, and the cable dock 100. It is possible to instruct power level switching.

  FIG. 1D shows the state of the mutual DC mode in which neither the notebook PC 10 nor the cable dock 100 is connected to the AC power sources 81 and 181. In this case, the notebook PC 10 and the cable dock 100 operate with the respective DC power sources 83 and 183, and can control power consumption according to their own power management policies as necessary. In this state, the notebook PC 10 can be prevented from instructing the cable dock 100 to switch the power level. Since the power consumption of the cable dock 100 is much smaller than that of the notebook PC 10, if this state continues, the remaining capacity of the DC power source 83 will be insufficient first.

  When the remaining capacity of the DC power source 83 is insufficient, power can be supplied to the notebook PC 10 from the DC power source 183 of the cable dock 100. At this time, the notebook PC 10 specifies the power level using the remaining capacity of the DC power sources 83 and 183 and the consumed power of the notebook PC 10 or the entire consumed power as parameters, and instructs the cable dock 100 to switch the power level. Can do.

  FIG. 2 shows four types of power modes of the notebook PC 10 and the other cable dock 100a in the connected state. The cable dock 100a is different from the case of FIG. 1 in that it does not operate with a DC power source. As in the case of FIG. 1, the AC power source 81 may not be physically connected when connected. Alternatively, power may be supplied from only one of the AC power sources 81 and 181 electrically. 2B and 2C include a cable dock 100a having such a structure. In another example, the cable dock 100a may be of a type that cannot be connected to the AC power source 181. 1B and 1D include a cable dock 100a having such a structure.

  FIG. 2A shows a mutual AC mode in which the notebook PC 10 and the cable dock 100a are supplied with power from the AC power sources 81 and 181, respectively. When the notebook PC 10 and the cable dock 100a operate with the AC power sources 81 and 181 having large rated capacities, respectively, the notebook PC 10 does not instruct the cable dock 100a to switch the power level because the necessity for power management is low. Good.

  FIG. 2B illustrates a PC_AC mode in which the AC power source 81 is connected only to the notebook PC 10. In this case, power can be supplied from the notebook PC 10 to the cable dock 100a. When the rated capacity of the AC power source 81 is large, the notebook PC 10 may not instruct the cable dock 100 to switch the power level. When the rated capacity of the AC power source 81 is small, the notebook PC 10 specifies the power level using the rated capacity of the AC power source 81, the remaining capacity of the DC power source 83 and the power consumption of the notebook PC 10 or the total power consumption as parameters. Then, it is possible to instruct the cable dock 100 to switch the power level.

  FIG. 2C shows a dock AC mode in which the AC power source 181 is connected only to the cable dock 100a. In this case, power can be supplied to the notebook PC 10 from the cable dock 100a. When the rated capacity of the AC power source 181 is large, the notebook PC 10 may not instruct the cable dock 100 to switch the power level. When the rated capacity of the AC power source 181 is small, the notebook PC 10 specifies the power level using the rated capacity of the AC power source 181, the remaining capacity of the DC power source 83 and the power consumption of the notebook PC 10 or the total power consumption as parameters. The power level can be instructed to the cable dock 100a.

  FIG. 2D shows a PC_DC mode in which the AC power sources 81 and 181 are not connected to either the notebook PC 10 or the cable dock 100a. In this case, power can be supplied from the notebook PC 10 to the cable dock 100a. At this time, the notebook PC 10 can specify the power level using the remaining capacity of the DC power source 83 and the power consumption of the notebook PC 10 or the total power consumption as parameters, and can instruct the cable dock 100a to switch the power level. .

[Notebook PC]
FIG. 3 is a functional block diagram for explaining an example of the main configuration of the notebook PC 10. Many of the hardware and software that make up the notebook PC 10 are well known and will be described to the extent necessary for understanding the present invention. The CPU 11, HDD 17, USB connector 19, PC connector 31, and embedded controller (EC) 23 are connected to the I / O controller (chip set). A system memory 13 and a GPU 15 are connected to the CPU 11, and a display 16 is connected to the GPU 15.

  The GPU 15 conforms to the DP (DisplayPort) 1.2 standard, and is connected to the PC connector 31 via the DP line 55. The GPU 15 can output a data stream to each of the display 16 and the PC connector 31. The GPU 15 generates micro packets corresponding to SST (Single Stream Transport) or MST (Multi-stream Transport) according to the number of external displays logically connected to the output port of the cable dock 100 (FIG. 4). To do.

  When the video driver recognizes that a plurality of external displays are logically connected to the cable dock 100, the GPU 15 operates in the MST and transmits a micro packet of a format called MTP (Multi-stream Transport Packet). Generate. A header including an identifier of each external display is added to the MTP. When the video driver recognizes that one external display is logically connected to the cable dock 100, the GPU 15 operates in SST and outputs a micro packet in a format called TU (Transfer Unit). To do.

  The I / O controller 21 has a built-in USB controller connected to the PC connector 31 via a USB 3.0 standard USB line 53. The EC 23 is connected to the PC connector 31 by a signal line 51. The signal line 51 is pulled up to the power supply VCC by the MOSFET 24 and a resistor. The PC connector 31 is formed on the side surface of the casing of the notebook PC 10 and is connected to the dock connector 101 of the cable dock 100.

  The EC 23 is connected to the power block 27 and the battery unit 28. The EC 23 is a microcomputer that mainly manages the power and temperature of the notebook PC 10 and includes a CPU, a RAM, a firmware ROM, an EEPROM, and the like that operate independently of the CPU 11. In connection with the present invention, the EC 23 periodically acquires the power consumption of the notebook PC 10, the presence / absence of connection of the AC / DC adapter 30, the rated power of the AC / DC adapter 30 and the like from the power block 27 as parameter state values, The remaining capacity is acquired from the battery unit 28 as the parameter state value.

  The EC 23 can communicate with the dock controller 103 (FIG. 4) by the one-wire protocol through the signal line 51 by controlling the voltage of the power supply VCC that pulls up the signal line 51 and the MOSFET 24. The EC 23 and the dock controller 103 may be connected by a bus such as LPC or I2C. The EC 23 can also communicate with the dock controller 103 via the USB line 53. The EC 23 periodically changes the power consumption of the cable dock 100 from the dock controller 103, whether the AC / DC adapter 112 is connected, the rated power of the AC / DC adapter 112, the remaining capacity of the battery unit 110, etc. Get as a value.

  The EC 23 stores a power management table 25 reflecting the power management policy of the notebook PC 10 in the EPROM. The EC 23 applies the state values of the parameters of the notebook PC 10 and the cable dock 100 to the power management table 25 to specify the power level of the cable dock 100. The configuration of the power management table 25 will be described with reference to FIG. The EC 23 specifies the power level of the notebook PC 10 from the parameter state value, and can reduce the power consumption of each device constituting the notebook PC 10 at the same timing as the cable dock 100 or at a different timing.

  For example, in the power management of the notebook PC 10, the operating frequency of the CPU 11 is lowered or the brightness of the LCD 16 is lowered. In other examples, the charging of the battery unit 28 is stopped or the charging power is limited. The power management that the notebook PC 10 performs on its own device follows the conventional method. The EC 23 sends a mode switching signal corresponding to the specified power level of the cable dock 100 to the dock controller 103 through the signal line 51. The power level of the cable dock 100 is 1 to 4 in one example.

  The power block 27 includes a plurality of DC / DC converters for supplying power of a predetermined voltage to devices constituting the notebook PC 10, a charger for charging the battery unit 28, a switching circuit for switching a power source, and consumption. A power detection circuit and the like are included. The power block 27 is connected to the PC connector 31 by a power line 57. The power block 27 can supply the power of the AC / DC adapter 30 or the power of the battery unit 28 to the cable dock 100 through the power line 57. The power block 27 can receive power from the cable dock 100 through the power line 57.

  The AC / DC adapter 30 corresponds to the AC power source 81 for the notebook PC 10 in a single state and may be built in the casing of the notebook PC 10 or may be independent from the notebook PC 10 so that it can be connected by a power connector. The battery unit 28 corresponds to a DC power source 83 for the notebook PC 10 in a single state, and includes a rechargeable battery, a protection circuit, a remaining capacity calculation circuit, a communication circuit, and the like.

[Cable dock]
FIG. 4 is a functional block diagram for explaining an example of a main configuration of the cable dock 100. The configuration of the cable dock 100a in FIG. 2 differs from the cable dock 100 only in that the battery unit 110 and the charger are not included and the configuration of the device table 104 is different. The cable dock 100 includes a dock connector 101, a dock controller 103, an MST hub 105, a USB hub 107, a power block 109, and a battery unit 110.

  The dock connector 101 can be attached to the cable 102 (FIG. 1) and connected to the PC connector 31 of the notebook PC 10. The dock connector 101 is connected to the dock controller 103 via the signal line 151, connected to the USB hub 107 via the USB line 153, connected to the MST hub 105 via the DP line 155, and connected to the power block 109 via the power line 157. Has been.

  The signal line 151, USB line 153, DP line 155, and power line 157 are connected to the signal line 51, USB line 53, DP line 55, and power line of the notebook PC 10 via the dock connector 101 and the PC connector 31. 57. The signal line 151 is pulled down to the ground via the MOSFET 152 and a resistor. The signal lines 51 and 151 may be pulled up on the cable dock 100 side and pulled down on the notebook PC 10 side.

  The dock controller 103 is connected to the MST hub 105, the USB hub 107, the battery unit 110, and the power block 109. The dock controller 103 is a microcomputer including a CPU, RAM, EEPROM, and firmware. The dock controller 103 periodically acquires the power consumption of the cable dock 100, the presence / absence of connection of the AC / DC adapter 110, the rated power of the AC / DC adapter 110, and the like as parameter state values from the power block 109, The remaining capacity is acquired from the battery unit 110 as a parameter state value. The dock controller 103 can communicate with the EC 23 through the signal line 151 by controlling the MOSFET 152 with a one-wire protocol.

  The dock controller 103 detects the connection with the notebook PC 10 through the signal line 151, controls the operation of the power block 109, and supplies power to the MST hub 105, the USB hub 107, and other devices. The dock controller 103 periodically checks the power consumption of the cable dock 100, whether or not the AC / DC adapter 112 is connected, the rated power of the AC / DC adapter 112, the remaining capacity of the battery unit 110, and the like through the signal line 151. Send to.

  The dock controller 103 stores the device table 104 in the EEPROM. The dock controller 103 applies the mode switching signal received through the signal line 151 to the device table 104, and instructs the MST hub 105, the USB hub 107, the power block 109, and the like corresponding to the power level. Reduce action. The configuration of the device table 104 will be described later with reference to FIG.

  The cable dock 100 includes a DP connector 113, an HDMI (registered trademark) connector 117, and a DVI connector 121 as casings as output ports related to the MST hub 105. The MST hub 105 supports MST defined by the DP1.2 standard. The MST hub 105 is connected to a DP connector 113, a DP / HDMI (High-Definition Multimedia Interface) protocol converter 115, and a DP / DVI (Digital Visual Interface) protocol converter 119. The protocol converters 115 and 119 are connected to the HDMI connector 117 and the DVI connector 121, respectively.

  An external display corresponding to each standard can be connected to the DP connector 113, the HDMI connector 117, and the DVI connector 121. The MST hub 105 refers to the header of the micro packet received by the MST from the GPU 15 to generate logical image data according to the standard of the destination external display, and the connectors 113 and 117 to which the destination external display is connected. , 121.

  The MST hub 105 can recognize which output connector 113, 117, 121 is connected to the external display through a HPD (Hot Plug Detect) line. The dock controller 103 enables or disables the MST hub 105 by a mode switching signal. When the MST hub 105 is set to disable, the operation stops and almost no power is consumed.

  The cable dock 100 has a USB 2.0 standard receptacle 123, a USB 3.0 standard receptacle 125, a charging receptacle 127 having a large charging capacity, an RJ45 connector 131, and a combo jack 135 as output ports related to the USB hub 107. It has. The charging receptacle 127 corresponds to DCP (Dedicated Charging Port) or CDP (Charging Downstream Port) defined by the USB standard.

  Connected to the USB hub 107 are a receptacle 123, a receptacle 125, a charging receptacle 127, a USB / Ethernet (registered trademark) protocol converter 129, and a USB / audio protocol converter 133. The protocol converter 129 is connected to an RJ45 connector 131 for connection to a network, and the protocol converter 133 is connected to a combo jack 135 for connection to an audio device.

[Power management table]
FIG. 5 is a diagram for explaining an example of the configuration of the power management table 25. FIG. 5 illustrates four power management tables 25a to 25d corresponding to the power supply modes described with reference to FIGS. The power management table 25a is referred to by the EC 23 when the power supply mode is the PC_AC mode in FIG. Since the notebook PC 10 does not supply power to the cable dock 100 while the remaining capacity of the battery unit 110 is large, the power level 4 is set so that the cable dock 100 does not perform power saving operation. Note that the power level 4 can be set even when the rated capacity of the AC / DC adapter 30 is large.

  When the remaining capacity of the battery unit 110 decreases and the notebook PC 10 starts to supply power to the cable dock 100, the power depends on the rated power of the AC / DC adapter 30 and the power consumption of the notebook PC 10 or the overall power consumption. Levels 1 to 4 are set. In the power management table 25a, a low power level is set such that the smaller the rated power of the AC / DC adapter 30 and the lower the power consumption, the lower the power consumption of the cable dock 100.

  The power management table 25b is referred to by the EC 23 when the power mode is the dock AC mode of FIG. While the remaining capacity of the battery unit 28 is large, even if the rated power of the AC / DC adapter 112 is small, the notebook PC 10 can operate without reducing the performance by compensating for the insufficient power of the battery unit 28. Is set to power level 4 which does not require power saving operation. The power level 4 can be set even when the rated capacity of the AC / DC adapter 112 is large.

  When the remaining capacity of the battery unit 28 decreases because the rated power of the AC / DC adapter 112 is small, it is necessary to reduce the power consumption of the cable dock 100. For the power saving operation of the cable dock 100 at this time, the power management table 25b includes power levels 1 to 4 according to the rated power of the AC / DC adapter 112 and the power consumption of the notebook PC 10 or the total power consumption. Is set. In the power management table 25b, a power level is set so that the power consumption of the cable dock 100 is reduced as the rated power of the AC / DC adapter 112 is smaller and the power consumption is larger.

  The power management table 25c is referred to by the EC 23 when the power supply mode is the mutual DC mode of FIG. In the power management table 25c, power levels 1 to 3 are set according to the total remaining capacity of the battery units 28 and 110. In the power management table 25c, the power level is set so that the power consumption of the cable dock 100 is lowered as the total remaining capacity is smaller and the overall power consumption is larger.

  The power management table 25d is applied to the cable dock 100 or the cable dock 100a from which the battery unit 110 is removed. The power management table 25d is referred to by the EC 23 when the power supply mode is the PC_DC mode in FIG. In the power management table 25d, power levels 1 and 2 are set according to the remaining capacity of the battery unit 28. In the power management table 25d, the power level is set so that the power consumption of the cable dock 100 is lowered as the remaining capacity is smaller and the overall power consumption is larger.

[Device table]
FIG. 6 is a diagram for explaining an example of the configuration of the device table 104. The device table 104 is used for controlling the operation of the device when the dock controller 103 receives a mode switching signal from the EC 23. When the dock controller 103 receives the mode switching signal indicating the power level 4, the dock controller 103 does not perform control for the power saving operation. At this time, each device can perform a power saving operation with a unique algorithm. When dock controller 103 receives a mode switching signal indicating power level 3, dock controller 103 disables the port for charging receptacle 127 of USB hub 107 and the port for converter 133. Further, the dock controller 103 sets the power block 109 to stop charging the battery unit 110.

  When the dock controller 103 receives the mode switching signal indicating the power level 2, only the ports of the receptacles 123 and 125 of the USB hub 107 are enabled and the other ports are disabled. When the dock controller 103 receives the mode switching signal indicating the power level 1, it enables only the port of the receptacle 123 of the USB hub 107 and disables the other ports.

[Operation procedure]
Next, a method for managing the power consumption of the cable dock 100 based on the power management policy of the notebook PC 10 will be described with reference to the flowchart of FIG. In block 201, the notebook PC 10 and the cable dock 100 are connected in one of the power supply modes shown in FIG. 1, and the notebook PC 10 and the cable dock 100 are operating. The notebook PC 10 recognizes peripheral devices connected to the output port of the cable dock 100. In block 203, the EC 23 stores the power management table 25, and the dock controller 103 stores the device table 104. The EC 23 knows the current power level of the cable dock 100.

  In block 205, the notebook PC 10 shifts the system to the sleep state of any of the S3, S4, and S5 states when the idle time is long or by a user operation. At this time, when the notebook PC 10 instructs the cable dock 100 to enter the same sleep state in block 251, the cable dock 100 also transitions to the same sleep state in block 253. In block 207, the notebook PC 10 uses the current power mode from the state values such as the connection state of the AC / DC adapters 30 and 112 and the connection state of the battery units 28 and 110 acquired through the power block 27 and the dock controller 103. The power management tables 25a to 25d to be determined are determined.

  In block 209, the EC 23 periodically acquires the state values of the parameters of the notebook PC 10 from the power block 27 and the battery unit 28. The state value includes the remaining capacity of the battery unit 28, the power consumption, the rated power of the AC / DC adapter 30, and the like. At block 211, the dock controller 103 periodically obtains the state values of the parameters of the cable dock 100 from the power block 109 and the battery unit 110.

  The state value includes the remaining capacity of the battery unit 110, the rated power of the AC / DC adapter 112, the power consumption of the cable dock 100, and the like. The EC 23 periodically acquires the state values from the dock controller 100 through the signal lines 51 and 151. The power supply of the EC 23 and the dock controller 103 is secured so that data transmission through the signal lines 51 and 151 is possible even while the notebook PC 10 and the dock controller 103 perform the power saving operation.

  In block 213, the EC 23 applies the acquired state value to any of the power management tables 25a to 25d to identify the power level. If the EC 23 determines in block 215 that the power level of the cable dock 100 needs to be changed, the block 23 sends a mode switching signal corresponding to the new power level to the dock controller 103 in block 217. At block 219, the dock controller 103 applies the indicated power level to the device table 104 to control the MST hub 105 and USB hub 107. At this time, information indicating that the peripheral device connected to the output port to be stopped can be displayed on the display 16.

  Although the present invention has been described with the specific embodiments shown in the drawings, the present invention is not limited to the embodiments shown in the drawings, and is known so far as long as the effects of the present invention are achieved. It goes without saying that any configuration can be adopted.

10 Notebook PC
23 Embedded Controller (EC)
25 Power management table 26 DC power source 28 Battery unit 30 AC / DC adapter 31 PC connector (receptacle)
81 Notebook PC AC Power Source 83 Notebook PC DC Power Limit 100, 100a Cable Dock 101 Dock Connector (Plug)
103 Dock Controller 104 Device Table 110 Battery Unit 112 AC / DC Adapter 181 Cable Dock AC Power Source 183 Cable Dock DC Power Limit

Claims (20)

A computer system including a portable electronic device and a function expansion device,
The portable electronic device is
Power management standards that define power-related parameters and power levels;
A first controller for obtaining a state value of the parameter;
The function expansion device is
A second controller capable of communicating with the first controller and controlling operation of a device constituting the function expansion device according to the power level specified based on the state value of the parameter and the power management standard; Having a computer system.   The computer system according to claim 1, wherein the first controller acquires a state value of the parameter, specifies the power level, and instructs the second controller to specify the specified power level.   The computer system according to claim 1, wherein the second controller obtains a state value of the parameter to identify the power level.   Power can be supplied from one of the portable electronic device and the function expansion device to the other, and the power management standard is composed of a combination of types of power sources on which the portable electronic device and the function expansion device operate. The computer system of claim 1 including a power mode.   The computer system according to claim 4, wherein a first battery unit that supplies power to the portable electronic device in a single state supplies power to the function expansion device in a connected state.   The computer system according to claim 5, wherein the parameter includes a remaining capacity of the first battery unit.   The computer system according to claim 4, wherein a second battery unit that supplies power to the function expansion device in a single state supplies power to the portable electronic device in a connected state.   The computer system according to claim 7, wherein the parameter includes a remaining capacity of the second battery unit.   The computer system according to claim 4, wherein an AC power source supplies power to the portable electronic device and the function expansion device in a connected state.   The computer system according to claim 9, wherein the parameters include a rated capacity of the AC power source and power consumption of the portable electronic device. A method in which a portable electronic device manages power consumption of a function expansion device,
The portable electronic device defining power related parameters and power levels;
Obtaining a state value of the parameter;
Applying the state value to the parameter to identify the power level;
The function expansion device reducing power consumption based on the identified power level. The portable electronic device identifying the power level;
The method of claim 11, comprising: the portable electronic device indicating the identified power level to the function expansion device.   The method according to claim 11, wherein the defining includes defining a device type of the function expansion device that performs a power saving operation in response to a plurality of the power levels.   The method according to claim 11, wherein in the defining step, the parameter and the power level are set corresponding to a combination of respective power sources of the portable electronic device and the function expansion device.   The power source includes an AC power source and a DC power source, and the parameter includes any of a rated capacity of the AC power source, a remaining capacity of the DC power source, or power consumption of the portable electronic device. The method described in 1. A portable electronic device capable of connecting a function expansion device,
A connector for connecting the function expansion device;
A power management table that defines parameters and power levels related to the power of the portable electronic device;
A portable electronic device comprising: a controller that instructs the function expansion device to specify the power level specified by applying the state value of the parameter to the power management table.   The portable electronic device according to claim 16, wherein when the controller instructs the function expansion device, the controller that controls the devices constituting the portable electronic device to operate at a predetermined power level. A function expansion device that can be connected to a portable electronic device,
A connector for connecting to the portable electronic device;
A device table that defines devices that perform power-saving operations according to the power level; and
A function expansion apparatus comprising: a controller that controls power consumption of the device by applying a power level specified based on a parameter related to power of the portable electronic device to the device table.   The function expansion device according to claim 18, wherein the function expansion device is connected to the portable electronic device with a cable and can be used in a mobile environment together with the portable electronic device.   The function expansion device according to claim 19, wherein the function expansion device includes a battery unit that supplies power to the portable electronic device.

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