1. Field of the Invention
The present invention relates to a power management apparatus, and a display method.
2. Description of the Related Art
In recent years, a technology called smart grid has been gaining attention. The smart grid is a technological framework to realize efficient power usage by constructing a new transmission network having a communication channel along with the transmission network and using this intelligent transmission network. The background idea of the smart grid is to realize efficient management of the amount of power use, swift handling of an incident when such an incident occurs, remote control of the amount of power use, distributed power generation using power generation facilities outside the control of a power company, or charging management of an electric vehicle. Particularly, effective utilization of in-house power generating stations using renewable energy by ordinary households or operators other than power companies and charging management of various electric vehicles typically including electric cars have been attracting considerable attention. Incidentally, renewable energy is energy generated without using fossil fuel.
Power generated by ordinary households or operators other than power companies is used by power generation operators. Remaining power after use by the power generation operators is currently purchased by power companies. However, purchasing power supplied from power generation facilities outside the control of a power company is a heavy burden to the power company. For example, amount of power supplied from photovoltaic power generation facilities depends on the weather. Moreover, amount of power supplied from in-house power generating stations of ordinary households depends on power use of ordinary households that largely changes day by day. Thus, it is difficult for power companies to receive stable power supply from power generation facilities outside the control of power companies. For the above reason, it may become difficult for power companies to purchase power in the future.
Thus, a home battery initiative that uses power generated by power generation facilities outside the control of power companies after temporarily storing the power in batteries has recently been gaining attention. For example, a method of using power generated by photovoltaic power generation facilities by storing such power in batteries and making up for shortages in the night or when the weather is bad is considered. Furthermore, a method of limiting amount of power received from a power company in accordance with the battery storage amount or using power stored in batteries in the daytime when power rates are higher by storing power, in batteries, supplied by a power company in the night when power rates are lower are considered. Also, batteries can store power as DC, which makes DC/AC conversion or AC/DC conversion during transmission unnecessary so that losses during conversion can be reduced.
Thus, various expectations regarding power management mingle with one another amid the smart grid initiative. To realize such power management, the smart grid initiative is premised on having a communication channel along with a transmission network. That is, exchanging information about power management by using this intelligent transmission network is assumed. However, in a region where a communication infrastructure is already built, instead of using a transmission network as a communication channel, information about power management may be exchanged by using a network constructed by the deployed communication infrastructure. That is, what is important in the smart grid initiative is how to efficiently manage power generation facilities and storage facilities that are not uniformly managed.
Additionally, to manage a plurality of electronic appliances, it is necessary to identify each individual electronic appliance. Therefore, in the smart grid initiative, a power management apparatus carries out authentication of each individual electronic appliance. When the authentication has succeeded, the power management apparatus permits power supply to the electronic appliance. A plurality of electronic appliances are managed by the power management apparatus in this manner. Thus, together with enhancement of efficiency of management, a method of presenting, to a user, states of a plurality of electronic appliance in an easy-to-grasp manner is desired. For example, in relation to a method of displaying power information, JP-A-2009-229281 discloses a technology of displaying change-over-time of power consumption at home.
However, under a situation where complicated power management is carried out in the smart grid initiative, merely displaying change-over-time of power consumption does not enable a user to grasp an actual, essential state of management. Particularly, even if a user monitors power consumption of all the electronic appliances at home, it is difficult to grasp under what circumstance the power of which electronic appliance is suppressed, for example. For this reason, it is desired to display more clearly, by the power management apparatus, each electronic appliance, or the like, a system configuration or power information.
In light of the foregoing, it is desirable to provide a power management apparatus, and a display method, which are new and improved, and which are capable of displaying information relating to power management in a way that is easy for a user to understand.
According to an embodiment of the present invention, there is provided a power management apparatus which includes an authentication processing unit that carries out an authentication process on each individual electronic appliance that is to be managed, a consumption amount acquiring unit that acquires information on power consumption from the electronic appliance, and an information display unit that displays an authentication state or an authentication result obtained from the authentication processing unit, together with the information on power consumption acquired by the consumption amount acquiring unit.
The power management apparatus may further include an installation location acquiring unit that acquires information on an installation location from a power supply outlet or the each individual electronic appliance managed by the power management apparatus. In this case, the information display unit groups and displays power consumption and authentication states of electronic appliances installed at a same installation location or the power consumption and authentication results of the electronic appliances, based on the installation location acquired by the installation location acquiring unit.
In a case an outlet expansion apparatus for expanding a power supply outlet is connected to the power supply outlet managed by the power management apparatus, the authentication processing unit may carry out the authentication process on the outlet expansion apparatus, the consumption amount acquiring unit may acquire, from the outlet expansion apparatus, the information on power consumption of all electronic appliances or each individual electronic appliance connected to the outlet expansion apparatus, and the information display unit may display an authentication state or an authentication result of the outlet expansion apparatus in a higher level hierarchy, and displays the information on power consumption of all the electronic appliances or the each individual electronic appliance connected to the outlet expansion apparatus in a lower level hierarchy.
The power management apparatus may further include an external consumption amount acquiring unit that acquires, in a case the electronic appliance of its owner user is used by being connected to the power supply outlet managed by the power management apparatus of another user, the information on power consumption of the electronic appliance of the owner user from the power management apparatus of such other user or from a management server managing the power management apparatuses of the owner user and such other user. In this case, the information display unit displays the information on power consumption acquired by the consumption amount acquiring unit and the information on power consumption acquired by the external consumption amount acquiring unit together but in a distinguishable format.
The power management apparatus may further include an appliance display control unit that transmits information to be displayed by the information display unit to the electronic appliance and causes the electronic appliance or the power supply outlet to display the information.
According to another embodiment of the present invention, there is provided a method of displaying power management information, which includes the steps of carrying out an authentication process on each individual electronic appliance that is to be managed, acquiring information on power consumption from the electronic appliance, and displaying an authentication state or an authentication result of the step of carrying out an authentication process together with the information on power consumption acquired in the step of acquiring information on power consumption.
According to the embodiments of the present invention described above, it becomes possible to display information relating to power management in a way that is easy for a user to understand.
Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the appended drawings. Note that, in this specification and the appended drawings, structural elements that have substantially the same function and structure are denoted with the same reference numerals, and repeated explanation of these structural elements is omitted.
<Flow of Description>
A flow of description of an embodiment of the present invention described below will be briefly mentioned here. First, an overall picture of a power management system will be described with reference to
Next, a configuration of an outlet expansion apparatus 127 will be described with reference to
(Description Items)
1-1: Overall Configuration (
1-2: Configuration of Managed Block 12 (
1-3: Configuration of External Server 3 (
2-1: Overview of Function
2-2: Details of Function
3-1: Display of System Configuration or the Like
3-2: Display of Power Consumption or the Like
4-1: Averaging
4-2: Complicating
4-3: Patternizing
5-1: Function
5-2: Operation
6-1: Functional Configuration of Information Management Unit 112
6-2: Functional Configuration of Control-Compliant Appliance 125 or the Like
6-3: Operation at the Time of Authentication/Registration
7-1: Functional Configuration of Control-Compliant Appliance 125 or the Like
7-2: Functional Configuration of Manufacturer Server 36
7-3: Operation at the Time of Authentication/Registration
7-4: Billing Method
In the following, an embodiment of the present invention will be described in detail.
<1: Overall Picture of Power Management System>
First, an overall picture of a power management system according to the present embodiment will be described.
<1-1: Overall Configuration (FIG. 1)>
As shown in
Additionally, in this specification, expressions “local” and “wide area” are used. “Local” means a small group configured from elements that can communicate without using the wide area network 2. On the other hand, “wide area” means a large group including elements that communicate via the wide area network 2. Also, a small group configured from elements arranged inside the local power management system 1 may be specifically expressed by the expression “local.” On the other hand, the entire power management system shown in
Now, the power management system described above attempts, as with the smart grid initiative described above, to enhance efficiency of power usage, and to appropriately manage various appliances operating on power, power storage means that stores power, power generating means that generates power, power supply means that supplies power from a power supply, and the like. The targets of power management in this power management system are the appliances, the power storage means, the power generating means, the power supply means, and the like provided in the local power management system 1. Additionally, a system in the smart grid initiative called HEMS (Home Energy Management System) or BEMS (Building Energy Management System) is an example of the local power management system 1.
As shown in
Furthermore, the power management apparatus 11 acquires information on the amount of stored power or the like from the power storage means. Then, the power management apparatus 11 carries out charge/discharge control on the power storage means. Furthermore, the power management apparatus 11 acquires information on the amount of power generation or the like from the power generating means. Also, the power management apparatus 11 acquires information on the amount of power supplied from outside from the power supply means. In this manner, the power management apparatus 11 acquires information from the appliances, the power storage means, the power generating means, and the power supply means provided in the local power management system 1, and controls input/output of power. Of course, the power management apparatus 11 carries out, as appropriate, similar management of structural elements other than the appliances, the power storage means, the power generating means, and the power supply means.
In the local power management system 1 shown in
The power supplier system 5 supplies power to each local power management system 1. Then, the power supplied from the power supplier system 5 is supplied to the managed block 12 in the local power management system 1 via the power information gathering apparatus 4. At this point, the power information gathering apparatus 4 acquires information, for example, on the amount of power supplied to the managed block 12. Then, the power information gathering apparatus 4 transmits the acquired information on the amount of power or the like to the power supplier system 5. By using such a mechanism, the power supplier system 5 gathers information relating to power consumption or the like of the managed block 12 in each local power management system 1.
Furthermore, the power supplier system 5 refers to the gathered information relating to power consumption or the like, controls the power information gathering apparatus 4, and controls the amount of power supply such that efficient power usage by the managed block 12 or the entire power management system is realized. At this point, the power information gathering apparatus 4 restricts the amount of power supplied from the power supplier system 5 to the managed block 12, or lifts the restriction on the amount of power according to the power consumption of the managed block 12. Additionally, the power supplier may be a power company, a corporate or non-corporate power generation manager owning a power station, a corporate or non-corporate power storage manager owning a power storage facility, or the like, for example.
However, under current situations, a power company is likely to be the power supplier and, in this specification, an explanation will be made assuming a case where the power company is the power supplier. Also, most of the externally-supplied power is at present purchased from the power company, which is the power supplier. However, in the future, the electricity market may become active and the power purchased in the electricity market may cover most of the externally-supplied power. In such a case, it is assumed that the local power management system 1 will be supplied with power from the power trading system 7, as shown in
The power trading system 7 carries out processes relating to power trading such as placement of a sell or buy order in the electricity market, price calculation after the execution of an order, a settlement process, placement of order for power supply, and the like. Furthermore, in the example of
Furthermore, the power management system shown in
For its part, the power management apparatus 11 may be configured to be operable by an external terminal device 6 connected via the wide area network 2. For example, a user may want to check the power state of the local power management system 1 that the user manages, by using the terminal apparatus 6. In such a case, if the power management apparatus 11 is configured to be operable by the terminal apparatus 6, the user is enabled to have the power state of the local power management system 1 that the user manages displayed by the terminal apparatus 6 and to check the power state. The user is also enabled to perform power trading by the power management apparatus 11 by using the terminal apparatus 6.
Additionally, the terminal apparatus 6 may be provided inside the local power management system 1. In this case, the terminal apparatus 6 connects to the power management apparatus 11 by using a communication path provided in the local power management system 1 without using the wide area network 2. One advantage of using the terminal apparatus 6 is that the user does not have to go to the installation location of the power management apparatus 11. That is, if the terminal apparatus 6 can be used, the power management apparatus 11 can be operated from an arbitrary place. Additionally, as a concrete form of the terminal apparatus 6, there can be assumed, for example, a mobile phone, a mobile information terminal, a notebook computer, a portable game machine, an information appliance, a facsimile, a fixed-line phone, an audio/video appliance, a car navigation system, or an electric vehicle.
In the foregoing, power management in the power management system shown in
Information that can be gathered by the power management apparatus 11 may be, for example, a model number or an appliance ID of each appliance (hereinafter, appliance information), information relating to the profile of a user (hereinafter, user information), information relating to a billing account or a credit card of a user (hereinafter, billing information), registration information relating to a service to be used (hereinafter, service information), or the like. The appliance information mentioned above is set in each appliance in advance or is manually input by a user. Also, the user information, the billing information, and the service information mentioned above are, in many cases, manually input to the power management apparatus 11 by a user. Additionally, input method of the information is not limited to these examples, and may be changed to arbitrary input method. Also, in the following explanation, the appliance information, the user information, the billing information, and the service information will be referred to as “initial information.”
The information that can be gathered by the power management apparatus 11 may be, in addition to the initial information, information relating to specifications of a battery connected to each appliance (hereinafter, appliance battery information), information relating to the state of each appliance or the like (including the power storage means, the power generating means, the power supply means, and the like) (hereinafter, appliance state information), information that can be acquired from an external system or server connected to the wide area network 2 (hereinafter, external information), and the like. The appliance state information mentioned above may be, for example, the discharge voltage or the amount of stored power of the power storage means at the time point of information gathering, the power generation voltage or the amount of power generation of the power generating means, power consumption of each appliance, and the like. Furthermore, the external information mentioned above may be the unit market price of power acquired from the power trading system 7, a list of available services acquired from the external server 3, and the like. Additionally, in the following explanation, the appliance battery information, the appliance state information, and the external information will be referred to as “primary information.”
Furthermore, the power management apparatus 11 can calculate, by itself or by using the function of the external server 3, secondary information by using the initial information and the primary information. For example, the power management apparatus 11 analyzes the primary information described above, and calculates an index value indicating the balance between the power supplied from the power supplier system 5, the power generated by the power generating means, the power charged/discharged by the power storage means, and the power consumed by the managed block 12 (hereinafter, a balance index). Also, the power management apparatus 11 calculates a billing status and a CO2 reduction status based on power consumption. Furthermore, the power management apparatus 11 calculates the degree of consumption of each appliance (a proportion of duration of use to duration of life, or the like) based on the initial information, or analyzes a user's lifestyle pattern based on the change over time in the consumed power.
Also, the power management apparatus 11 obtains various pieces of information (hereinafter, tertiary information) by performing calculation using the secondary information or by performing information exchange with a system or a server connected to the wide area network 2 or another power management apparatus 11. For example, the power management apparatus 11 obtains information relating to the status of sell/buy order or price in the electricity market (hereinafter, market data), information on the amount of surplus power or of deficit power in a neighbouring region (hereinafter, regional power information), information on an appliance suitable for a user's lifestyle pattern from the standpoint of promoting efficient power usage (hereinafter, appliance recommendation information), security information relating to a computer virus or the like, or appliance risk information relating to a fault in an appliance or the like.
By appropriately using the initial information, the primary information, the secondary information, and the tertiary information described above, the power management apparatus 11 can provide various services to a user. Meanwhile, the power management apparatus 11 is to hold important information relating to a user's privacy or the security of the local power management system 1. Also, the power management apparatus 11 is in a place to permit or prohibit power supply to the managed block 12. Thus, a high level of security is wanted from the power management apparatus 11 so that an attack from the outside of the local power management system 1 or an illegal behaviour performed within the local power management system 1 can be prevented.
As an attack that the power management apparatus 11 receives from the outside of the local power management system 1, there can be conceived a DoS attack (Denial of Service attack), a computer virus, or the like. A firewall is of course provided between the local power management system 1 and the wide area network 2, but a stricter security measure is wanted for the reason stated above. Furthermore, as the illegal behaviour performed within the local power management system 1, there can be conceived illegal modification of an appliance, the power storage means, or the like, falsification of information, connection of an unauthorized appliance, or the like. Furthermore, a measure against use, by a malicious third party, of information on consumed power reflecting a user's lifestyle pattern, or detection/recovery of breakdown (ignition or the like in some cases) of each appliance or the power management apparatus 11 may become necessary from the viewpoint of enhancing the security level.
As will be described later, the power management apparatus 11 has a function of realizing such high security level as described above. The power management apparatus 11 realizes power management for the managed block 12, service provision based on the initial information, the primary information, the secondary information, and the tertiary information gathered from the managed block 12, and the like, while maintaining the security level. Additionally, the maintenance of the high security level by the power management apparatus 11 may not be realized by the power management apparatus 11 alone. Accordingly, an appliance, the power storage means, the power generating means, the power supply means, and the like, provided in the managed block 12 are to attempt to maintain the security level in cooperation with the power management apparatus 11. Additionally, such structural elements of the managed block 12 will also be described later in detail.
<1-2: Configuration of Managed Block 12 (FIGS. 2 to 4)>
A configuration of the managed block 12 will be described in detail here with reference to
First, reference will be made to
Additionally, the control-compliant outlet 123, the electric vehicle 124, the control-compliant appliance 125, and the outlet expansion apparatus 127 are examples of the appliance described above. Also, the power storage apparatus 128 is an example of the power storage means described above. Furthermore, the first power generating apparatus 129 and the second power generating apparatus 130 are examples of the power generating means described above. The control-compliant outlet 123 and the outlet expansion apparatus 127 are also examples of the power supply means described above. Furthermore, the non-control-compliant appliance 126 is not directly subject to power management by the power management apparatus 11, and thus is not, by itself, an example of the appliance described above. However, as will be described later, by being combined with the outlet expansion apparatus 127, the non-control-compliant appliance 126 will be able to be managed by the power management apparatus 11, and will be an example of the appliance described above.
(Flow of Power)
Power supplied from the power supplier system 5, the power trading system 7, or another local power management system 1 (hereinafter, external power) is input to the power distribution apparatus 121. External AC power is assumed to be input to the power distribution apparatus 121 in the example of
Furthermore, power discharged from the power storage apparatus 128 (hereinafter, discharged power) is also input to the power distribution apparatus 121. The discharged power output from the power storage apparatus 128 is converted from DC to AC by the AC/DC converter 122, and is input to the power distribution apparatus 121. The discharged AC power input to the power distribution apparatus 121 is converted from AC to DC by the AC/DC converter 122, and is input to the control-compliant outlet 123. However, to avoid a loss in the discharged power at the AC/DC converter 122, the discharged power may also be supplied from the power storage apparatus 128 to the control-compliant outlet 123 without going through the AC/DC converter 122.
In addition to the external power input via the power distribution apparatus 121, power generated by the first power generating apparatus 129 and the second power generating apparatus 130 (hereinafter, generated power) is input to the power storage apparatus 128. Additionally, in the example of
Additionally, the first power generating apparatus 129 is power generating means for generating power using renewable energy. For example, the first power generating apparatus 129 is a photovoltaic apparatus, a wind power generating apparatus, a geothermal power generating apparatus, a hydraulic power generating apparatus, or the like. On the other hand, the second power generating apparatus 130 is power generating means for generating power using non-renewable energy which is environment-friendly compared to, for example, thermal power generation that generates power by combusting gasoline, coal, or the like, and using the combustion. For example, the second power generating apparatus 130 is a fuel cell, a natural gas power generating apparatus, a biomass power generating apparatus, or the like. Incidentally, in the case hydrogen, which is the fuel for power generation by the fuel cell, is generated using power derived from renewable energy, the fuel cell is power generating means that generates power without using non-renewable energy.
The generated power generated by the first power generating apparatus 129 and the second power generating apparatus 130, and the power stored in the power storage apparatus 128 are, on the one hand, input to the control-compliant outlet 123 via the power distribution apparatus 121 or the AC/DC converter 122, and, on the other hand, may be purchased by the power supplier system 5, the power trading system 7, or the like. In such a case, the generated power generated by the first power generating apparatus 129 and the second power generating apparatus 130, and the discharged power output from the power storage apparatus 128 are converted by the AC/DC converter 122 from DC to AC, and are transmitted to the power supplier system 5, the power trading system 7, or the like, via the power distribution apparatus 121.
In the foregoing, the flow of power in the managed block 12 has been roughly described. Particularly, a distribution path of the power flowing via the power distribution apparatus 121 has been described here. As described above, the power distribution apparatus 121 undertakes a role of dividing the distribution path of power within the managed block 12. Thus, if the power distribution apparatus 121 stops, the distribution of power within the managed block 12 is disrupted. Therefore, the power distribution apparatus 121 is provided with an uninterruptible power supply (UPS). Additionally, in the example of
(Authentication at the Time of Power Supply)
In the managed block 12, the power flowing to the control-compliant outlet 123 or the power storage apparatus 128 via the power distribution apparatus 121 is managed by the power management apparatus 11. For example, the power management apparatus 11 controls the power distribution apparatus 121 and supplies power to the control-compliant outlet 123 or stops the supply of power to the control-compliant outlet 123.
The power management apparatus 11 also carries out authentication of the control-compliant outlet 123. Then, the power management apparatus 11 supplies power to the control-compliant outlet 123 for which authentication has been successful, and stops supply of power to the control-compliant outlet 123 for which authentication has failed. In this manner, supply or non-supply of power in the managed block 12 is determined by the success or failure of authentication by the power management apparatus 11. Authentication by the power management apparatus 11 is carried out not only on the control-compliant outlet 123, but also on the electric vehicle 124, the control-compliant appliance 125, and the outlet expansion apparatus 127. Incidentally, authentication by the power management apparatus 11 is not carried out on the non-control-compliant appliance 126, which does not possess a communication function with the power management apparatus 11 nor a computational function necessary for authentication.
Accordingly, the control-compliant outlet 123, the electric vehicle 124, the control-compliant appliance 125, or the outlet expansion apparatus 127 which has been authenticated can be supplied with power based on control by the power management apparatus 11. However, the non-control-compliant appliance 126, which is not, by itself, to be authenticated, will not be supplied with power based on control by the power management apparatus 11. Accordingly, power is continuously supplied to the non-control-compliant appliance 126 independently of control by the power management apparatus 11, or power is not at all supplied thereto. However, by having the outlet expansion apparatus 127 carry out authentication instead, it becomes possible for the non-control-compliant appliance 126 to be supplied with power based on control by the power management apparatus 11.
(Summary of Appliance Function)
The functions of the control-compliant outlet 123, the electric vehicle 124, the control-compliant appliance 125, the non-control-compliant appliance 126, and the outlet expansion apparatus 127 will be briefly summarized here.
(Control-Compliant Outlet 123)
First, the function of the control-compliant outlet 123 will be summarized. The control-compliant outlet 123 has terminals to be connected with power plugs of the electric vehicle 124, the control-compliant appliance 125, the non-control-compliant appliance 126, and the outlet expansion apparatus 127. Furthermore, the control-compliant outlet 123 has a function of supplying power supplied via the power distribution apparatus 121 to the electric vehicle 124, the control-compliant appliance 125, the non-control-compliant appliance 126, and the outlet expansion apparatus 127 connected to the terminals. That is, the control-compliant outlet 123 has a function as a power supply outlet.
The control-compliant outlet 123 also has various functions necessary for being authenticated by the power management apparatus 11. For example, the control-compliant outlet 123 has a communication function for exchanging information with the power management apparatus 11. This communication function is realized by cable communication by a power line or a signal line, or by providing the control-compliant outlet 123 with a communication module for wireless communication. The control-compliant outlet 123 also has a computational function for performing computation necessary at the time of authentication. Furthermore, the control-compliant outlet 123 holds identification information such as an appliance ID and key information necessary for authentication. By using these functions and information, the control-compliant outlet 123 is enabled to be authenticated by the power management apparatus 11. Additionally, the type of authentication may be mutual authentication using a common key, or public key authentication using a pair of a secret key and a public key.
Furthermore, the control-compliant outlet 123 may also have state display means for displaying success/failure of authentication with the power management apparatus 11 and a state during authentication (hereinafter, authentication state). In this case, the state display means provided in the control-compliant outlet 123 may display the authentication states of the electric vehicle 124, the control-compliant appliance 125, and the outlet expansion apparatus 127 connected to the control-compliant outlet 123. Furthermore, this state display means may also display whether an appliance connected to the control-compliant outlet 123 is the non-control-compliant appliance 126 or not. Additionally, this state display means is configured from an indicator lamp such as a LED or a small bulb, or a display device such as an LCD or an ELD.
As has been described, power is supplied via the power distribution apparatus 121 by control by the power management apparatus 11 to the control-compliant outlet 123 for which authentication by the power management apparatus 11 has been successful. On the other hand, supply of power to the control-compliant outlet 123 for which authentication has failed is stopped by control by the power management apparatus 11. As such, with power supply being controlled according to the success/failure of authentication, an unauthorized power supply outlet can be prevented from connecting to the power distribution apparatus 121. It becomes possible also to easily detect a power supply outlet fraudulently connected to the power distribution apparatus 121. Furthermore, in the case the state display means is provided in the control-compliant outlet 123, the authentication state of the control-compliant outlet 123 can be easily grasped, and authentication failure and breakdown of the control-compliant outlet 123 can be easily distinguished.
Now, the form of the control-compliant outlet 123 is not limited to the form of a power point for connecting a power plug. For example, a control-compliant outlet 123 that has a built-in coil that supplies power by using electromagnetic induction as with a reader/writer for a non-contact IC card, and that has a surface form without the form of a power point can also be realized. In such a case, as with a non-contact IC card, a coil for generating an induced electromotive force from a magnetic field generated by the control-compliant outlet 123 is provided in the electric vehicle 124, the control-compliant appliance 125, and the outlet expansion apparatus 127. According to such a configuration, supplying or receiving of power without the use of a power plug is made possible. Additionally, in the case of using electromagnetic induction, exchange of information using modulation of magnetic field is made possible between the control-compliant outlet 123 and the electric vehicle 124, the control-compliant appliance 125, or the outlet expansion apparatus 127.
Furthermore, the control-compliant outlet 123 has a function of measuring the amount of power supplied to the electric vehicle 124, the control-compliant appliance 125, or the outlet expansion apparatus 127 connected to the terminal. Furthermore, the control-compliant outlet 123 has a function of notifying the measured amount of power to the power management apparatus 11. Also, the control-compliant outlet 123 may have a function of acquiring the primary information from the electric vehicle 124, the control-compliant appliance 125, or the outlet expansion apparatus 127 that is connected to the terminal and of transmitting the acquired primary information to the power management apparatus 11. As such, with the information which has been measured or acquired by the control-compliant outlet 123 transmitted to the power management apparatus 11, it becomes possible for the power management apparatus 11 to grasp power status or to perform power supply control for each individual control-compliant outlet 123.
(Electric Vehicle 124)
Next, the function of the electric vehicle 124 will be summarized. The electric vehicle 124 includes a battery for storing power. The electric vehicle 124 also includes a driving mechanism that is driven using power discharged from the battery. In the case the electric vehicle 124 is an electric vehicle or a plug-in hybrid electric vehicle, this driving mechanism will include a motor, a gear, a shaft, wheels, tires, and the like, for example. The driving mechanisms of other electric vehicles 124 will at least include a motor. Furthermore, the electric vehicle 124 includes a power plug used at the time of charging the battery. Power can be received by connecting this power plug to the control-compliant outlet 123. Incidentally, in the case of a method where the control-compliant outlet 123 supplies power by using the electromagnetic induction, a coil that generates an induced electromotive force when placed in a magnetic field is provided in the electric vehicle 124.
The electric vehicle 124 also has various functions necessary for being authenticated by the power management apparatus 11. For example, the electric vehicle 124 has a communication function for exchanging information with the power management apparatus 11. This communication function is realized by cable communication by a power line or a signal line, or by providing the electric vehicle 124 with a communication module for wireless communication. The electric vehicle 124 also has a computational function for performing computation necessary at the time of authentication. Furthermore, the electric vehicle 124 holds identification information such as an appliance ID and key information necessary for authentication. By using these functions and information, the electric vehicle 124 is enabled to be authenticated by the power management apparatus 11. Additionally, the type of authentication may be mutual authentication using a common key, or public key authentication using a pair of a secret key and a public key.
Furthermore, the electric vehicle 124 also has a function of transmitting, to the power management apparatus 11, appliance battery information relating to a battery that is mounted, such as a remaining battery level, a charge amount, and a discharge amount. User information relating to a user owning the electric vehicle 124, and appliance information relating to fuel efficiency, performance, or the like, of the electric vehicle 124 are also transmitted to the power management apparatus 11. With these pieces of information transmitted to the power management apparatus 11 from the electric vehicle 124, it becomes possible for the power management apparatus 11 to carry out processes such as billing using the user information, and taxation based on the user information and the appliance information. For example, a process of imposing an environmental tax calculated based on the amount of CO2 emissions, a process of displaying a mileage based on the remaining battery level, and the like, will be able to be carried out by the power management apparatus 11.
Additionally, it is also conceivable to use the battery of the electric vehicle 124 instead of the power storage apparatus 128. For example, the battery of the electric vehicle 124 may be used instead of the power storage apparatus 128 when it is temporarily not possible to use the power storage apparatus 128, such as when the power storage apparatus 128 is broken down or is being exchanged. Furthermore, since the electric vehicle 124 is itself movable, it can carry external power as a material. That is, it can be used as a movable power storage apparatus 128. Due to such advantage, it may also be useful to have the electric vehicle 124 act as back-up power supply in case of disaster or emergency. Such usage can, of course, be realized within the framework of the local power management system 1 according to the present embodiment.
(Control-Compliant Appliance 125)
Next, the function of the control-compliant appliance 125 will be summarized. The control-compliant appliance 125 has various functions necessary for being authenticated by the power management apparatus 11. For example, the control-compliant appliance 125 has a communication function for exchanging information with the power management apparatus 11. This communication function is realized by cable communication by a power line or a signal line, or by providing the control-compliant appliance 125 with a communication module for wireless communication. The control-compliant appliance 125 also has a computational function for performing computation necessary at the time of authentication. Furthermore, the control-compliant appliance 125 holds identification information such as an appliance ID and key information necessary for authentication. By using these functions and information, the control-compliant appliance 125 is enabled to be authenticated by the power management apparatus 11. Additionally, the type of authentication may be mutual authentication using a common key, or public key authentication using a pair of a secret key and a public key.
Furthermore, the control-compliant appliance 125 also has a function of transmitting, to the power management apparatus 11, appliance battery information relating to a battery that is mounted, such as a remaining battery level, a charge amount, and a discharge amount. User information relating to a user owning the control-compliant appliance 125, and appliance information relating to the type, performance, or the like, of the control-compliant appliance 125 are also transmitted to the power management apparatus 11. With these pieces of information transmitted to the power management apparatus 11 from the control-compliant appliance 125, it becomes possible for the power management apparatus 11 to carry out processes such as billing using the user information, and taxation based on the user information and the appliance information. For example, a process of imposing an environmental tax calculated based on the amount of CO2 emissions, a display process for recommending an appliance with higher environmental performance, and the like, will be able to be carried out by the power management apparatus 11.
(Non-Control-Compliant Appliance 126, Outlet Expansion Apparatus 127)
Next, the functions of the non-control-compliant appliance 126 and the outlet expansion apparatus 127 will be summarized. Unlike the control-compliant outlet 123, the electric vehicle 124, and the control-compliant appliance 125 described above, the non-control-compliant appliance 126 does not possess a function necessary to be authenticated by the power management apparatus 11. That is, the non-control-compliant appliance 126 is an existing home electric appliance, an existing video appliance, or the like. The non-control-compliant appliance 126, which does not pass authentication, is not enabled to be subjected to power management by the power management apparatus 11, and in some cases, is not enabled to receive power. Therefore, to enable use of the non-control-compliant appliance 126 in the local power management system 1, delegate means for performing authentication becomes necessary.
The outlet expansion apparatus 127 undertakes two roles. One role is a function of performing delegate authentication such that the non-control-compliant appliance 126 is enabled to be used in the local power management system 1. The other role is a function of increasing the number of appliances to be connected to the control-compliant outlet 123. One or more terminals to be connected with the power plug of the electric terminal 124, the control-compliant appliance 125, or the non-control-compliant appliance 126 is provided to the outlet expansion apparatus 127. When using the outlet expansion apparatus 127 provided with a plurality of terminals, the number of the electric vehicles 124, the control-compliant appliances 125, and the non-control-compliant appliances 126 that can be connected to the control-compliant outlet 123 can be increased. That is, the outlet expansion apparatus 127 functions as a power strip having an advanced function.
In the foregoing, the functions of the control-compliant outlet 123, the electric vehicle 124, the control-compliant appliance 125, the non-control-compliant appliance 126, and the outlet expansion apparatus 127 have been briefly summarized. Incidentally, the functions described above are not the only functions of the control-compliant outlet 123, the electric vehicle 124, the control-compliant appliance 125, the non-control-compliant appliance 126, and the outlet expansion apparatus 127. Taking these functions as basics, functions necessary for operation of power management by the power management apparatus 11 described below will be further supplemented.
(Communication Function)
Here, a communication function of the power management apparatus 11, the control-compliant outlet 123, the electric vehicle 124, the control-compliant appliance 125, the outlet expansion apparatus 127, or the like, within the local power management system 1 will be described with reference to
As shown in
However, as shown in
Incidentally, the power information gathering apparatus 4 may be included, as a connection destination, in the communication network constructed within the local power management system 1, as shown in
(Specific Examples of Appliances and Various Apparatuses)
Here, specific examples of some structural elements of the local power management system 1 will be introduced with reference to
As the electric vehicle 124, an electric vehicle and a plug-in hybrid electric vehicle can be given as specific examples, for example. Also, as the control-compliant appliance 125 and the non-control-compliant appliance 126, a home appliance, a personal computer, a mobile phone, and a video appliance can be given as specific examples, for example. As the power storage apparatus 128, a lithium-ion rechargeable cell, a NAS rechargeable cell, and a capacitor can be given as specific examples, for example. Also, as the first power generating apparatus 129, a photovoltaic apparatus, a wind power generating apparatus, and a geothermal power generating apparatus can be given as specific examples, for example. Furthermore, as the second power generating apparatus 130, a fuel cell, a natural gas power generating apparatus, and a biomass power generating apparatus can be given as specific examples, for example. As described, various apparatuses and appliances are used as the structural elements of the local power management system 1.
In the foregoing, the configuration of the managed block 12 has been described. However, the function of each structural element included in the managed block 12 is not limited to that described above. The function of each structural element is supplemented as necessary for power management by the power management apparatus 11. Additionally, a supplementary function of each structural element will be described in detail in the explanation of the configuration of the power management apparatus 11 and other structural elements to be described later.
<1-3: Configuration of External Server 3 (FIGS. 5 and 6)>
Next, the configuration of the external server 3 will be described with reference to
The service providing server 31 has a function of providing a service that uses a function of the power management apparatus 11 or the like. The billing server 32 has a function of providing the power management apparatus 11 with billing information according to the power consumed in the local power management system 1, and requesting a user to settle the usage fee, based on information on the amount of power managed by the power management apparatus 11. Also, the billing server 32 carries out, in cooperation with the service providing server 31, a billing process on a service used by a user. Additionally, the billing process may be carried out for an owner user of the electric vehicle 124, the control-compliant appliance 125, or the like, that consumed power, or may be carried out for a user of the power management apparatus 11 managing information on the power consumed.
The system management server 33 has a function of managing the entire power management system shown in
In the example of
As described, with the system management server 33 exercising general control over a plurality of local power management systems 1, a mechanism is realized of billing a user who has used power even if the user has used power in the local power management system 1 of another user. Especially, charging of the electric vehicle 124 is, in many cases, performed outside the local power management system 1 managed by oneself. In such a case, if the function described above of the system management server 33 is used, fee can be reliably billed to the user of the electric vehicle 124.
The analysis server 34 has a function of analyzing information gathered by the power management apparatus 11, or information that another server connected to the wide area network 2 holds. For example, in the case of optimizing region-based power supply control, the amount of information gathered from the local power management systems 1 will be huge, and to calculate an optimal control method for each local power management system 1 by analyzing the information, tremendous amount of computation will have to be performed. Such computation is burdensome to the power management apparatus 11, and thus is carried out by using the analysis server 34. Additionally, the analysis server 34 can also be used for other various computational processes. Furthermore, the certificate authority server 35 is for authenticating a public key, and for issuing a public key certificate.
The manufacturer server 36 is managed by the manufacturer of an appliance. For example, the manufacturer server 36 of the electric vehicle 124 holds information relating to the design of the electric vehicle 124. Similarly, the manufacturer server 36 of the control-compliant appliance 125 holds information relating to the design of the control-compliant appliance 125. Furthermore, the manufacturer server 36 holds information for identifying each manufactured appliance, such as each electric vehicle 124 and each control-compliant appliance 125. The manufacturer server 36 has a function of identifying the electric vehicle 124 or the control-compliant appliance 125 located within each local power management system 1 by using these pieces of information and cooperating with the power management apparatus 11. By using this function, the power management apparatus 11 can carry out authentication of the electric vehicle 124 or the control-compliant appliance 125, or detect connection of an unauthorized appliance.
The map DB server 37 holds a map database. Accordingly, a server or the power management apparatus 11 connected to the wide area network 2 can access the map DB server 37 and use the map database. For example, in a case a user used power outside his/her local power management system 1, the system management server 33 can search the usage location from the map database and provide the user with information on the usage location together with billing information. As described, there are various types of external server 3, and in addition to the server configuration illustrated here, different types of external servers 3 can also be added as appropriate.
<2: Configuration of Power Management Apparatus 11 (FIGS. 7 to 9)>
In the foregoing, an overall picture of the power management system according to the present embodiment has been described. In the following, the configuration of the power management apparatus 11 mainly in charge of power management in the power management system will be described with reference to
<2-1: Overview of Function>
First, an overall functional configuration of the power management apparatus 11 will be described with reference to
The local communication unit 111 is communication means for communicating via a communication network constructed within the local power management system 1. The information management unit 112 is means for managing appliance information of each structural element included in the local power management system 1 and information relating to power. Also, the authentication process for the control-compliant outlet 123, the electric vehicle 124, the control-compliant appliance 125, the outlet expansion apparatus 127, or the like, is carried out by the information management unit 112. The storage unit 113 is storage means for holding information used for authentication and information used for power management. The wide area communication unit 114 is communication means for exchanging information with an external system and server via the wide area network 2.
The control unit 115 is control means for controlling operation of each structural element included in the local power management system 1. The display unit 116 is display means for displaying information relating to power consumed in the local power management system 1, the user information, the billing information, other types of information relating to power management, information relating to power management outside the local power management system 1, information relating to power trading, and the like. Additionally, as the display means, an LCD, an ELD or the like is used, for example. The input unit 117 is input means for a user to input information. Additionally, as the input unit 117, a keyboard, a button, or the like is used, for example. Furthermore, it is also possible to construct a touch panel by combining the display unit 116 and the input unit 117.
As described, the power management apparatus 11 includes the communication means (the local communication unit 111, the wide area communication unit 114) for exchanging information with an appliance, an apparatus, a system, a server, or the like, within or outside the local power management system 1. Furthermore, the power management apparatus 11 includes the control means (the control unit 115) for controlling an appliance or an apparatus within the local power management system 1. Also, the power management apparatus 11 includes information management means (the information management unit 112) that gathers information from an appliance, an apparatus, a system, a server, or the like, within or outside the local power management system 1, and provides a service or authenticates an appliance or an apparatus within the local power management system 1 by using the information. Also, the power management apparatus 11 includes the display means (the display unit 116) for displaying information relating to power within or outside the local power management system 1.
To safely and efficiently manage power within the local power management system 1, first, an appliance, an apparatus, or the like, within the local power management system 1 has to be correctly identified. Also, to safely and efficiently manage power within the local power management system 1, analysis of the information relating to power within and outside the local power management system 1 and performance of appropriate power control are also necessary. The function of the information management unit 112 is used for management of information performed to fulfill the above. Accordingly, the function of the information management unit 112 will be described in greater detail. Additionally, the function of the control unit 115 is used for control of a specific appliance, apparatus, or the like.
<2-2: Details of Function>
In the following, a functional configuration of the information management unit 112 will be described in detail with reference to
As shown in
(Appliance Management Unit 1121)
As shown in
(Power Trading Unit 1122)
As shown in
(Information Analyzing Unit 1123)
As shown in
Furthermore, estimation by the information analyzing unit 1123 is performed by using, as data for learning, the time-series data or an analysis result obtained by analyzing the time-series data, and by using an estimation formula obtained based on a predetermined machine learning algorithm. For example, by using a genetic learning algorithm (see JP-A-2009-48266, for example), the estimation formula can be automatically constructed. Also, by inputting the past time-series data or analysis result to the estimation formula, an estimation result can be obtained. Furthermore, by sequentially inputting calculated estimation results to the estimation formula, time-series data can be estimated.
Furthermore, the information analyzing unit 1123 performs calculation of present or future CO2 emissions, calculation of power supply pattern for reducing the power consumption (power saving pattern), calculation of power supply pattern for reducing CO2 emissions (low CO2 emissions pattern), and calculation or recommendation of appliance configuration, appliance arrangement or the like capable of reducing the power consumption and the CO2 emissions in the local power management system 1. The CO2 emissions are calculated based on the total power consumption or the power consumption distinguished for each power generation method.
In the case of using the total power consumption, approximately average CO2 emissions are calculated. On the other hand, in the case of using the power consumption distinguished for each power generation method, comparatively accurate CO2 emissions are calculated. Additionally, by at least distinguishing between power supplied from the outside, power generated by the first power generating apparatus 129 and power generated by the second power generating apparatus 130, more accurate CO2 emissions can be calculated than when the total power consumption is used. Tax, such as carbon tax, and billing are, in many cases, determined according to the CO2 emissions. Thus, it is assumed that enabling accurate calculation of the CO2 emissions will increase a sense of fairness among users and contribute to widespread use of power generating means based on renewable energy.
(Display Information Generating Unit 1124)
As shown in
(System Management Unit 1125)
As shown in
In the foregoing, the functional configuration of the power management apparatus 11 has been described. Additionally, the functional configuration of the power management apparatus 11 described here is only an example, and functions other than the above may be added as necessary.
<3: Display Contents/Display Method of Display Unit 116 (FIGS. 10 to 17)>
Display contents to be displayed on the display unit 116 and a display method will be described here with reference to
<3-1: Display of System Configuration or the Like>
First, a display method that enables a user to easily grasp the configuration or state of an appliance or the like provided in the local power management system 1 will be described with reference to
The display configuration of
The non-control-compliant appliance 126 does not possess an authentication function, but in the case delegate authentication is performed by the outlet expansion apparatus 127, even the non-control-compliant appliance 126 is displayed on the display unit 116, as shown in
With the authentication state clearly indicated in this manner, it becomes possible to swiftly detect an unauthorized appliance or the like. Furthermore, since grouping is performed for each installation location, the installation location of an unauthorized appliance or the like can be swiftly recognized, and the unauthorized appliance or the like can be swiftly removed. Furthermore, in the case a certain appliance or the like is in an unusable state, whether the appliance is broken down or whether it is just that authentication is not possible can be easily grasped.
<3-2: Display of Power Consumption or the Like>
Next, the display method of enabling a user to easily grasp the power consumption of an appliance or the like provided within the local power management system 1 will be described with reference to
The display configuration of
The display configuration of
Incidentally, information relating to a non-authenticated appliance or the like may be hidden. The display configuration of
According to this configuration, the power consumption and the billed amount at each usage location can be displayed, as with the display configuration illustrated in
<4: Method of Concealing Power Consumption Pattern (FIGS. 18 to 22)>
Here, a method of concealing a power consumption pattern will be described with reference to
The power consumption pattern of the managed block 12 reflects the lifestyle pattern of the user. As one example, in the power consumption pattern illustrated in
In this way, the power consumption pattern reflects the lifestyle pattern of the user. If such power consumption pattern were known by a malicious third party, such third party could then misuse the power consumption pattern. As examples, the third party could attempt to enter the home while the user is out, conduct high-pressure sales visits when the user is at home, or commit a robbery while the user is asleep.
For this reason, it is necessary to strictly manage information on power consumption or to provide an arrangement for concealing the power consumption pattern. As described earlier, information on the amount of power supplied from the power supplier system 5 is gathered by the power information gathering apparatus 4 that is managed by the power supplier. This means that a time-series pattern on power consumption by the managed block 12 will be exposed to at least the power supplier.
For this reason, out of the above measures, it is preferable to provide an arrangement for concealing the power consumption pattern to prevent the lifestyle pattern of a user from being discovered by a third party. One way to conceal a power consumption pattern is to create discrepancies between the time-series pattern of the amount of power supplied from the power supplier system 5 and the user's lifestyle pattern. For example, the power supplier system 5 could supply power when the user is not at home, or the local system could stop receiving power from the power supplier system 5 when the user is at home.
Such measures are realized using the power storage apparatus 128. For example, supplied power received from the power supplier system 5 when the user is not at home may be stored in the power storage apparatus 128 and power stored in the power storage apparatus 128 may be used when the user is at home to suppress the amount of power supplied from the power supplier system 5. To further increase security, it would be preferable to carry out charging/discharging control of the power storage apparatus 128 to make the power consumption pattern a specified pattern and thereby mostly eradicate the characteristics that appear in the power consumption pattern due to the user's lifestyle pattern.
<4-1: Averaging>
As shown in
<4-2: Complicating>
Note that so long as there is a discrepancy between the power consumption pattern and the lifestyle pattern, it is not necessary to set the power consumption at a constant value. To make the power consumption a constant value, a power storage apparatus 128 with sufficient capacity to absorb peaks in power consumption would be necessary. However, a power storage apparatus 128 with such large capacity is costly and it is not realistic to provide such an apparatus in an ordinary household merely to conceal a power consumption pattern. For this reason, a method of creating a discrepancy between the power consumption pattern and the lifestyle pattern using a power storage apparatus 128 of smaller capacity is preferable. As shown in
One conceivable method of complicating a power consumption pattern so as to produce comparatively small peaks and troughs throughout the pattern is described below. Although a large-capacity power storage apparatus 128 would be necessary to suppress a large peak to close to the average value, comparatively small peaks can be generated and moved using a storage apparatus with much smaller capacity. Although it is possible to complicate a power consumption pattern in units of one day, it is also effective to complicate a power consumption pattern so as to produce a different power consumption pattern every day and/or to eradicate cycles based on days of the week or month. An arrangement that complicates of the timing of events such as going out, coming home, going to bed, and getting up that are especially liable to misuse is also capable of sufficiently suppressing dishonest behavior without excessively complicating charging/discharging control of the power storage apparatus 128.
<4-3: Patternizing>
Also, as shown in
<5: Configuration of Outlet Expansion Apparatus 127 (FIGS. 23 to 38)>
Here, the configuration of the outlet expansion apparatus 127 will be described with reference to
<5-1: Function>
First, a functional configuration of the outlet expansion apparatus 127 will be described with reference to
The electronic vehicle 124, the control-compliant appliance 125, or the non-control-compliant appliance 126 is connected to the power supply outlet 1271. Then, the power supply outlet 1271 supplies power to the electric vehicle 124, the control-compliant appliance 125, or the non-control-compliant appliance 126 in accordance with the control by the power-supply control unit 1273. Also, the plugging/unplugging sensor 1272 is connected to the power supply outlet 1271, and physical plugging/unplugging of the electric vehicle 124, the control-compliant appliance 125, or the non-control-compliant appliance 126 can be detected. The physical plugging/unplugging of the electric vehicle 124, the control-compliant appliance 125, or the non-control-compliant appliance 126 detected by the plugging/unplugging sensor 1272 is notified to the power-supply control unit 1273.
The power-supply control unit 1273 is control means for controlling power supply to the electric vehicle 124, the control-compliant appliance 125, or the non-control-compliant appliance 126 connected to the power supply outlet 1271. Furthermore, the power-supply control unit 1273 includes an ammeter. Accordingly, the power-supply control unit 1273 can measure the current supplied to the power supply outlet 1271. Furthermore, the contents of notification received by the power-supply control unit 1273 from the plugging/unplugging sensor 1272 and a change in the current measured by the ammeter of the power-supply control unit 1273 are input to the connection detection unit 1274. Furthermore, information on the current measured by the ammeter of the power-supply control unit 1273 is input to the local communication unit 1275.
In the case the contents of notification received by the power-supply control unit 1273 from the plugging/unplugging sensor 1272 and the change in the current measured by the ammeter of the power-supply control unit 1273 are input, the connection detection unit 1274 detects, based on these pieces of input information, connection state (connection/non-connection) of the electric vehicle 124, the control-compliant appliance 125, or the non-control-compliant appliance 126 to the power supply outlet 1271. Then, information on the connection state detected by the connection detection unit 1274 is input to the local communication unit 1275. The local communication unit 1275 to which the information on the connection state and the information on the current are input uses the communication network in the local power management system 1 and transmits these pieces of input information to the power management apparatus 11 directly or via the control-compliant outlet 123.
When the electric vehicle 124, the control-compliant appliance 125, or the non-control-compliant appliance 126 is connected to the power supply outlet 1271 and information on the connection state is transmitted to the power management apparatus 11, the power management apparatus 11 transmits, to the outlet expansion apparatus 127, information indicating the upper limit of current (hereinafter, maximum current) that may be supplied from the power supply outlet 1271. The information on the maximum current is received by the local communication unit 1275, and is input to the maximum current setting unit 1276. The maximum current setting unit 1276 sets the maximum current of the power-supply control unit 1273 based on the input information on the maximum current. The power-supply control unit 1273 in which the maximum current is set controls power supply to the power supply outlet 1271 within a range of current not exceeding the maximum current.
Additionally, the power-supply control unit 1273 does not supply power to the power supply outlet 1271 until the electric vehicle 124 or the control-compliant appliance 125 connected to the power supply outlet 1271 is registered/authenticated by the power management apparatus 11 or delegate authentication of the non-control-compliant appliance 126 connected to the power supply outlet 1271 is completed. Thus, when the maximum current is set, registration/authentication process for the electric vehicle 124, the control-compliant appliance 125, or the non-control-compliant appliance 126 connected to the power supply outlet 1271 is carried out by the registration/authentication unit 1277. Incidentally, at the time of registration/authentication, a predetermined amount of power is supplied as appropriate from the power-supply control unit 1273 to the electric vehicle 124 or the control-compliant appliance 125 connected to the power supply outlet 1271.
The registration/authentication of the electric vehicle 124 and the control-compliant appliance 125 and the delegate authentication of the non-control-compliant appliance 126 are performed by the registration/authentication unit 1277. Additionally, the function and the operation of the registration/authentication unit 1277 will be described in detail in the description of an operation flow described later. If the registration/authentication of the electric vehicle 124 or the control-compliant appliance 125 or the delegate authentication of the non-control-compliant appliance 126 is successful, the registration/authentication unit 1277 notifies the power-supply control unit 1273 of the success/failure of the registration/authentication or the delegate authentication. When the success of the registration/authentication or the delegate authentication is notified, the power-supply control unit 1273 starts supplying power to the power supply outlet 1271. On the other hand, when failure of the registration/authentication or delegate authentication is notified, the power-supply control unit 1273 stops supplying power to the power supply outlet 1271.
In this manner, the power-supply control unit 1273 performs power supply control according to the limitation by the maximum current determined by the power management apparatus 11 or the success/failure of the registration/authentication. Particularly, the power-supply control unit 1273 performs power supply control for each power supply outlet 1271 even if there are a plurality of power supply outlets 1271. Thus, the number of the power supply outlets 1271 may be set to any number. Furthermore, the non-control-compliant appliance 126 is enabled to be included in the power management by the power management apparatus 11 by the function of the registration/authentication unit 1277. Furthermore, since the registration/authentication unit 1277 is configured to perform registration/authentication with each power supply outlet 1271 as a unit, the electric vehicle 124 or the control-compliant appliance 125 and the non-control-compliant appliance 126 can be simultaneously connected.
Additionally, the mode management unit 1278 and the environmental sensor 1279 are also provided in the outlet expansion apparatus 127. The mode management unit 1278 is means for managing the operation mode of the outlet expansion apparatus 127. Also, the environmental sensor 1279 is means for acquiring environmental information (appliance temperature, surrounding temperature, humidity, atmospheric pressure, and the like) at the installation location of the outlet expansion apparatus 127. Additionally, the environmental information is used for abnormality detection of the outlet expansion apparatus 127 or the like.
The type of the operation mode may be, for example, a standby mode, a normal mode, a cut-off mode, or an error mode. The standby mode is an operation mode where connection of an appliance or the like to the power supply outlet 1271 is waited for. The normal mode is an operation mode of a state where an appliance or the like is connected to the power supply outlet 1271. The cut-off mode is an operation mode defining an operation for a case where an appliance or the like is removed from the power supply outlet 1271. And the error mode is an operation mode defining an operation for a case of occurrence of an abnormality. The mode management unit 1278 sets the operation mode as appropriate, and notifies the power-supply control unit 1273 of the set operation mode.
In the foregoing, the functional configuration of the outlet expansion apparatus 127 has been described.
<5-2: Operation>
Next, an operation flow of the outlet expansion apparatus 127 will be described with reference to
(5-2-1: Operation in Standby Mode)
First, an operation flow of the outlet expansion apparatus 127 in the standby mode will be described with reference to
As shown in
In the case the process is proceeded to step S302, the outlet expansion apparatus 127 uses the functions of the registration/authentication unit 1277, and the mode management unit 1278 and performs an appliance connection protocol shown in
(5-2-2: Operation in Normal Mode)
Next, an operation flow of the outlet expansion apparatus 127 in the normal mode will be described with reference to
As shown in
In the case the process is proceeded to step S313 in step S312, the outlet expansion apparatus 127 cuts off the power supply to the power supply outlet 1271 (S313). Then, the outlet expansion apparatus 127 uses the functions of the power-supply control unit 1273 and the local communication unit 1275 and notifies the power management apparatus 11 of the cut off of power supply (S314). Then, the outlet expansion apparatus 127 uses the function of the mode management unit 1278 and sets the operation mode to the cut-off mode.
On the other hand, in the case the process is proceeded to step S315 in step S312, the outlet expansion apparatus 127 uses the functions of the power-supply control unit 1273 and the local communication unit 1275 and notifies the power management apparatus 11 of the measured current value (S315). Then, the outlet expansion apparatus 127 uses the function of the local communication unit 1275 and determines whether an ACK (confirmation information indicating normal reception of the measured current) is received from the power management apparatus 11 or not (S316). In the case the ACK is received from the power management apparatus 11, the outlet expansion apparatus 127 returns the process to step S311. On the other hand, in the case the ACK is not received from the power management apparatus 11, the outlet expansion apparatus 127 uses the function of the mode management unit 1278 and sets the operation mode to the error mode.
(Modification)
Additionally, the operation flow in the normal mode can be modified to the operation flow as shown in
As shown in
In the case the process is proceeded to step S313 in step S312, the outlet expansion apparatus 127 cuts off the power supply to the power supply outlet 1271 (S313). Then, the outlet expansion apparatus 127 uses the functions of the power-supply control unit 1273 and the local communication unit 1275 and notifies the power management apparatus 11 of the cut off of power supply (S314). Then, the outlet expansion apparatus 127 uses the function of the mode management unit 1278 and sets the operation mode to the cut-off mode.
On the other hand, in the case the process is proceeded to step S315 in step S312, the outlet expansion apparatus 127 uses the functions of the power-supply control unit 1273 and the local communication unit 1275 and notifies the power management apparatus 11 of the measured current value (S315). Then, the outlet expansion apparatus 127 uses the function of the local communication unit 1275 and determines whether the ACK (confirmation information indicating normal reception of the measured current) is received from the power management apparatus 11 or not (S316). In the case the ACK is received from the power management apparatus 11, the outlet expansion apparatus 127 proceeds with the process to step S317 (
In the case the process is proceeded to step S317 (see
In the case the process is proceeded to step S319 in step S318, the outlet expansion apparatus 127 cuts off the power supply to the power supply outlet 1271 (S319). Then, the outlet expansion apparatus 127 uses the functions of the power-supply control unit 1273 and the local communication unit 1275 and notifies the power management apparatus 11 of the cut off of power supply (S320). Then, the outlet expansion apparatus 127 uses the function of the mode management unit 1278 and sets the operation mode to the cut-off mode.
On the other hand, in the case the process is proceeded to step S321 in step S318, the outlet expansion apparatus 127 uses the functions of the power-supply control unit 1273 and the local communication unit 1275 and notifies the power management apparatus 11 of the measured value (S321). Then, the outlet expansion apparatus 127 uses the function of the local communication unit 1275 and determines whether the ACK (confirmation information indicating normal reception of the measured amount) is received from the power management apparatus 11 or not (S322). In the case the ACK is received from the power management apparatus 11, the outlet expansion apparatus 127 returns the process to step S311 (
(5-2-3: Operation in Cut-Off Mode)
Next, an operation flow of the outlet expansion apparatus 127 in the cut-off mode will be described with reference to
As shown in
(5-2-4: Operation in Error Mode)
Next, an operation flow of the outlet expansion apparatus 127 in the error mode will be described with reference to
As shown in
In the case the process is proceeded to step S342 in step S341, the outlet expansion apparatus 127 uses the functions of the registration/authentication unit 1277 and the mode management unit 1278 and performs the appliance connection protocol shown in
In the case the process is proceeded to step S344 in step S341, the outlet expansion apparatus 127 uses the function of the connection detection unit 1274 and determines whether the appliance or the like has been removed from the power supply outlet 1271 or not (S344). In the case the appliance or the like has been removed from the power supply outlet 1271, the outlet expansion apparatus 127 proceeds with the process to step S345. On the other hand, in the case the appliance or the like has not been removed from the power supply outlet 1271, the outlet expansion apparatus 127 returns the process to step S341. In the case the process is proceeded to step S345, the outlet expansion apparatus 127 resets connection state of the appliance or the like and information on the connection state and notifies the power management apparatus 11 of the reset via the local communication unit 1275 (S345). Then, the outlet expansion apparatus 127 uses the function of the mode management unit 1278 and sets the operation mode to the standby mode.
(5-2-5: Operation at the Time of Authentication)
Next, the appliance connection protocol regarding registration/authentication relating to the following three cases will be described with reference to
(Case 1)
(Case 1)
First, the appliance connection protocol according to Case 1 mentioned above will be described with reference to
As shown in
When the authentication process is completed in step S356, the process proceeds to the step of
When power is consumed by the outlet expansion apparatus 127, a time-series pattern of power consumption corresponding to the consumption pattern is detected by the control-compliant outlet 123, and the detection result is transmitted from the control-compliant outlet 123 to the power management apparatus 11 (S361). The power management apparatus 11 that received this detection result uses the function of the information analyzing unit 1123 and verifies whether or not the received detection result and the random number generated in step S357 match (S362). In the case the verification is positive, the power management apparatus 11 uses the function of the appliance management unit 1121 and links the outlet expansion apparatus 127 and the control-compliant outlet 123. For example, the appliance management unit 1121 records, in the storage unit 113, the appliance ID of the outlet expansion apparatus 127 and the appliance ID of the control-compliant outlet 123 in association with each other.
When the linking of the outlet expansion apparatus 127 and the control-compliant outlet 123 is completed in this manner, the process proceeds to the step of
When the operation mode of the appliance or the like is decided, the power management apparatus 11 uses the function of the appliance management unit 1121 and sets in the outlet expansion apparatus 127 a maximum current according to the operation mode of the appliance or the like (S365). At this point, the outlet expansion apparatus 127 uses the function of the maximum current setting unit 1276 and sets, in the power-supply control unit 1273, the maximum current decided with the power management apparatus 11. When setting of the maximum current is complete, the power management apparatus 11 uses the function of the control unit 115 and instructs the control-compliant outlet 123 to supply power to the outlet expansion apparatus 127 (S366). Then, power is supplied from the control-compliant outlet 123 to the outlet expansion apparatus 127 and power control of the appliance or the like is started by the outlet expansion apparatus 127.
(Case 2)
Next, the appliance connection protocol according to Case 2 mentioned above will be described with reference to
As shown in
When the authentication process is completed in step S376, the process proceeds to the step of
When power is consumed by the control-compliant appliance 125, a time-series pattern of power consumption corresponding to the consumption pattern is detected by the outlet expansion apparatus 127, and the detection result is transmitted from the outlet expansion apparatus 127 to the power management apparatus 11 (S381). The power management apparatus 11 that received this detection result uses the function of the information analyzing unit 1123 and verifies whether or not the received detection result and the random number generated in step S377 match (S382). In the case the verification is positive, the power management apparatus 11 uses the function of the appliance management unit 1121 and links the control-compliant appliance 125 and the outlet expansion apparatus 127. For example, the appliance management unit 1121 records, in the storage unit 113, the appliance ID of the control-compliant appliance 125 and the appliance ID of the outlet expansion apparatus 127 in association with each other.
When the linking of the control-compliant appliance 125 and the outlet expansion apparatus 127 is completed in this manner, the process proceeds to the step of
When the operation mode of the appliance or the like is decided, the power management apparatus 11 uses the function of the appliance management unit 1121 and sets in the outlet expansion apparatus 127 a maximum current according to the operation mode of the appliance or the like (S385). At this point, the outlet expansion apparatus 127 uses the function of the maximum current setting unit 1276 and sets, in the power-supply control unit 1273, the maximum current decided with the power management apparatus 11. When the setting of the maximum current is complete, the power management apparatus 11 uses the function of the control unit 115 and instructs the outlet expansion apparatus 127 to supply power to the control-compliant appliance 125 (S386). Then, power is supplied from the outlet expansion apparatus 127 to the control-compliant appliance 125 and power control of the control-compliant appliance 125 is started by the outlet expansion apparatus 127.
(Case 3)
Next, the appliance connection protocol according to Case 3 mentioned above will be described with reference to
As shown in
When the authentication fails, the power management apparatus 11 instructs the outlet expansion apparatus 127 to stop power supply to the non-control-compliant appliance 126 (S397). The outlet expansion apparatus 127 that received this instruction stops power supply to the non-control-compliant appliance 126 (S398). Next, the power management apparatus 11 notifies a warning or the like to a user (S399). For example, the warning or the like is displayed on the display unit 116.
After the warning or the like is displayed, the process proceeds to the step of
Next, the power management apparatus 11 uses the function of the appliance management unit 1121 and sets in the outlet expansion apparatus 127 a maximum current according to the operation mode of the non-control-compliant appliance 126 (S402). At this point, the outlet expansion apparatus 127 uses the function of the maximum current setting unit 1276 and sets, in the power-supply control unit 1273, the maximum current decided by the power management apparatus 11. When the setting of the maximum current is complete, the power management apparatus 11 uses the function of the control unit 115 and instructs the outlet expansion apparatus 127 to supply power to the non-control-compliant appliance 126 (S403). Then, power is supplied from the outlet expansion apparatus 127 to the non-control-compliant appliance 126 and operation of the non-control-compliant appliance 126 is started.
Also, when the non-control-compliant appliance 126 is removed from the outlet expansion apparatus 127, the process proceeds to the step of
In the foregoing, the configuration and the operation of the outlet expansion apparatus 127 have been described. Here, the registration/authentication process for enabling use of the non-control-compliant appliance 126 or increasing the number of connected appliances and the like by using the outlet expansion apparatus 127 has been described.
<6: Authentication/Registration of Appliance 1 (FIGS. 39 to 45)>
Next, a process of authentication/registration of the control-compliant appliance 125 or the like by the power management apparatus 11 will be described with reference to
<6-1: Functional Configuration of Information Management Unit 112>
First, a functional configuration of the information management unit 112 relating to registration/authentication described here will be briefly described with reference to
<6-2: Functional Configuration of Control-Compliant Appliance 125 or the Like>
Next, a functional configuration of the control-compliant appliance 125 relating to registration/authentication described here will be briefly described with reference to
As shown in
The local communication unit 1251 is communication means for exchanging information via the communication network in the local power management system 1. Also, the control unit 1252 is control means for controlling operation of each structural element included in the control-compliant appliance 125. Furthermore, the impedance measuring circuit 1253 is a circuit for measuring impedance of the part X, the part Y, or the part Z (see
Accuracies of electrical parts used by the control-compliant appliance 125 or the like are varied by a few percent for individual pieces. Therefore, if electrical characteristics of the electrical parts can be detected with sufficient accuracy, individual pieces can be identified. In the case of a semiconductor circuit, individual pieces vary with respect to the transistor characteristics. Therefore, if the transistor characteristics of semiconductor circuits can be detected with sufficient accuracy, individual semiconductor circuits can be identified. Of course, variation in individual pieces naturally occurring at the time of manufacture may be used, but it is also possible to uniquely vary each individual piece. Also, in the case the control-compliant appliance 125 is provided with a secondary cell, a parameter relating to charging control thereof or the like can also be used as information for identifying the piece.
The control-compliant appliance 125 shown in
<6-3: Operation at the Time of Authentication/Registration>
Based on the explanation of the configurations of the information management unit 112 and the control-compliant appliance 125, the operations of the information management unit 112 and the control-compliant appliance 125 performed at the time of authentication/registration will be described with reference to
(Operation in the Case of Non-Registration)
First, the operations of the information management unit 112 and the control-compliant appliance 125 in the case where the control-compliant appliance 125 is non-registered will be described with reference to
As shown in
When the fingerprint is measured, the control-compliant appliance 125 transmits the appliance ID of itself and the measured fingerprint to the appliance management unit 1121 (S103). The appliance management unit 1121 that received the appliance ID and the fingerprint checks the received fingerprint against a fingerprint registered in a fingerprint database configured in the storage unit 113 (S104). Incidentally, in the example of
Accordingly, the state of the control-compliant appliance 125 being non-registered is detected by the appliance management unit 1121 (S105). When non-registration is detected, the appliance management unit 1121 inquires of a user whether or not to register this control-compliant appliance 125 (S106, S107). In the case the user gives an instruction that it is to be registered, the appliance management unit 1121 proceeds with the process to a registration process for the control-compliant appliance 125. On the other hand, in the case the user gives an instruction that it is not to be registered, the appliance management unit 1121 cancels the authentication process and places the control-compliant appliance 125 in an unusable state.
(Operation at the Time of Registration)
Next, a registration process by the appliance management unit 1121 carried out at the time of registering the control-compliant appliance 125 will be described with reference to
As shown in
In the case the digital signature is authentic, the appliance management unit 1121 proceeds with the process to step S114. On the other hand, in the case the digital signature is not authentic, the appliance management unit 1121 cancels the processes relating to registration and authentication of the control-compliant appliance 125 and places the control-compliant appliance 125 in an unusable state. In the case the process proceeds to step S114, the appliance management unit 1121 registers the acquired fingerprint in the fingerprint database (S114). For example, the appliance management unit 1121 registers the fingerprint in the fingerprint database in association with the appliance ID of the control-compliant appliance 125. When the fingerprint is registered, the appliance management unit 1121 proceeds with the process to the authentication process.
Additionally, in the case of acquiring the fingerprint from the control-compliant appliance 125 to be registered, the operation of the appliance management unit 1121 at the time of registering the control-compliant appliance 125 may be modified to a simplified operation as shown in
(Operation at the Time of Authentication)
Next, operations of the information management unit 112 and control-compliant appliance 125 carried out at the time of authentication performed in the case the fingerprint of the control-compliant appliance 125 is already registered will be described with reference to
As shown in
When the fingerprint is measured, the control-compliant appliance 125 transmits the appliance ID of itself and the measured fingerprint to the appliance management unit 1121 (S133). The appliance management unit 1121 that received the appliance ID and the fingerprint checks the received fingerprint against a fingerprint registered in the fingerprint database configured in the storage unit 113 (S134).
In the case the result of the check is match of the received fingerprint and a fingerprint registered in the fingerprint database, the appliance management unit 1121 transmits to the control-compliant appliance 125 a notification to the effect that authentication is complete (authentication complete notification) (S135). On the other hand, in the case the result of the check is non-match of the received fingerprint and a fingerprint registered in the fingerprint database, the appliance management unit 1121 repeats the authentication process of steps S131 to S134 or performs an operation of cutting off power to the control-compliant appliance 125.
In the foregoing, the registration/authentication operation for the control-compliant appliance 125 has been described. As described, since registration/authentication is performed by using the characteristics of the electrical part mounted on the control-compliant appliance 125, unauthorized modification of the control-compliant appliance 125 becomes easy to detect. Also, in the case of the control-compliant appliance 125 illustrated in
<7: Authentication/Registration of Appliance 2 (FIGS. 46 to 51)>
Next, an authentication process for the control-compliant appliance 125 or the like by the power management apparatus 11 will be described with reference to
<7-1: Functional Configuration of Control-Compliant Appliance 125 or the Like>
First, a functional configuration of the control-compliant appliance 125 relating to authentication described here will be briefly described with reference to
As shown in
Based on the control by the control unit 1252, each appliance ammeter 1255 measures the current flowing through each part. Also, the measured values of the current by the appliance ammeters 1255 provided in the part group are input to the control unit 1252. For example, the control unit 1252 makes current flow through a certain part X in a predetermined pattern, and measures the current by the appliance ammeter 1255. Accuracies of electrical parts used by the control-compliant appliance 125 or the like are varied by a few percent for individual pieces. Therefore, if electrical characteristics of the electrical parts can be detected with sufficient accuracy, the part X can be identified from the measured value of the current.
Additionally, as shown in
<7-2: Functional Configuration of Manufacturer Server 36>
Next, a functional configuration of the manufacturer server 36 will be described with reference to
As shown in
The wide area communication unit 361 is communication means for exchanging information with a system, a server, the power management apparatus 11, and the like, connected to the wide area network 2. The appliance management unit 362 is means for managing information relating to the control-compliant appliance 125 (appliance ID, the design, or the like) manufactured by the manufacturer managing the manufacturer server 36. The storage unit 363 is storage means for holding information relating to the control-compliant appliance 125, a program for generating an operation command for the control-compliant appliance 125, a program defining an operation of a current value simulator described later, key information used at the time of communication, and the like.
The decryption unit 364 is means for decrypting a ciphertext by using the key information. The operation command generating unit 365 is means for generating an operation command for the control-compliant appliance 125 based on information decrypted from the ciphertext by the decryption unit 364. The current value simulator 366 is means for simulating the value of the current that flows when the control-compliant appliance 125 is operated according to a predetermined operation command. The current value comparing unit 367 is means for comparing a current value of the control-compliant appliance 125 acquired via the power management apparatus 11 and the current value simulated by the current value simulator 366. The billing processing unit 368 is means for performing a billing process on a user of the control-compliant appliance 125 as appropriate.
In the foregoing, the functional configuration of the manufacturer server 36 has been briefly described.
<7-3: Operation at the Time of Authentication/Registration>
Next, operations of the control-compliant appliance 125, the power management apparatus 11, the manufacturer server 36, and the control-compliant outlet 123 carried out at the time of authentication will be described with reference to
As shown in
The power management apparatus 11 that received the public key generates a random number by the function of the information management unit 112 (S506). Then, by the function of the information management unit 112, the power management apparatus 11 encrypts the generated random number and generates a ciphertext (S507). Next, by the function of the local communication unit 111, the power management apparatus 11 transmits the ciphertext to the control-compliant appliance 125 (S508). The control-compliant appliance 125 that received the ciphertext decrypts the ciphertext by using a secret key that was given at the time of manufacture and restores the random number (S509). The control-compliant appliance 125 that restored the random number generates an operation command based on the random number (S510).
Furthermore, the power management apparatus 11 that generated the ciphertext in step S507 transmits the ciphertext to the manufacturer server 36 by using the function of the wide area communication unit 114 (S511). The manufacturer server 36 that received the ciphertext decrypts, by the function of the decryption unit 364, the ciphertext by using a secret key and restores the random number (S512). The manufacturer server 36 that restored the random number generates an operation command based on the restored random number (S513). The manufacturer server 36 and the control-compliant appliance 125 will be in a state of holding the operation command based on the random number at a stage the processes of steps S510 and S513 are completed.
When the processes of steps S510 and S513 are complete, the process proceeds to the step of
The control-compliant outlet 123 transmits the current value measured in step S516 to the manufacturer server 36 (S519). Also, the control-compliant appliance 125 transmits the current value measured in step S515 to the manufacturer server 36 (S520). The manufacturer server 36 that received the current values from the control-compliant appliance 125 and the control-compliant outlet 123 compares the current value calculated in step S518 and the current values measured by the control-compliant appliance 125 and the control-compliant outlet 123 and determines whether they match or not (S521).
The determination result above is transmitted from the manufacturer server 36 to the power management apparatus 11 (S522). The power management apparatus 11 that received the determination result transmits to the control-compliant outlet 123, according to the determination result, an instruction that power supply to the control-compliant appliance 125 be continued or stopped (S523). The control-compliant outlet 123 that received the instruction that power supply be stopped stops power supply to the control-compliant appliance 125 (S524). On the other hand, the control-compliant outlet 123 that received the instruction that power supply be continued continues power supply to the control-compliant appliance 125 (S524).
In the foregoing, the operations of the control-compliant appliance 125, the control-compliant outlet 123, the power management apparatus 11, and the manufacturer server 36 relating to the authentication process have been described.
<7-4: Billing Method>
Here, a billing method for a case an appliance or the like owned by another user is used within the local power management system 1 that one manages will be described with reference to
For example, as shown in
<8: Example Hardware Configuration of Power Management Apparatus 11 (FIG. 52)>
The function of each structural element of the power management apparatus 11 described above can be realized by using, for example, the hardware configuration of an information processing apparatus illustrated in
As shown in
The CPU 902 functions as an arithmetic processing unit or a control unit, for example, and controls entire operation or a part of the operation of each structural element based on various programs recorded on the ROM 904, the RAM 906, the storage unit 920, or a removal recording medium 928. The ROM 904 is means for storing, for example, a program to be loaded on the CPU 902 or data or the like used in an arithmetic operation. The RAM 906 temporarily or perpetually stores, for example, a program to be loaded on the CPU 902 or various parameters or the like arbitrarily changed in execution of the program.
These structural elements are connected to each other by, for example, the host bus 908 capable of performing high-speed data transmission. For its part, the host bus 908 is connected through the bridge 910 to the external bus 912 whose data transmission speed is relatively low, for example. Furthermore, the input unit 916 is, for example, a mouse, a keyboard, a touch panel, a button, a switch, or a lever. Also, the input unit 916 may be a remote control that can transmit a control signal by using an infrared ray or other radio waves.
The output unit 918 is, for example, a display device such as a CRT, an LCD, a PDP or an ELD, an audio output device such as a speaker or headphones, a printer, a mobile phone, or a facsimile, that can visually or auditorily notify a user of acquired information. Moreover, the CRT is an abbreviation for Cathode Ray Tube. The LCD is an abbreviation for Liquid Crystal Display. The PDP is an abbreviation for Plasma Display Panel. Also, the ELD is an abbreviation for Electro-Luminescence Display.
The storage unit 920 is a device for storing various data. The storage unit 920 is, for example, a magnetic storage device such as a hard disk drive (HDD), a semiconductor storage device, an optical storage device, or a magneto-optical storage device. The HDD is an abbreviation for Hard Disk Drive.
The drive 922 is a device that reads information recorded on the removal recording medium 928 such as a magnetic disk, an optical disk, a magneto-optical disk, or a semiconductor memory, or writes information in the removal recording medium 928. The removal recording medium 928 is, for example, a DVD medium, a Blu-ray medium, an HD-DVD medium, various types of semiconductor storage media, or the like. Of course, the removal recording medium 928 may be, for example, an electronic device or an IC card on which a non-contact IC chip is mounted. The IC is an abbreviation for Integrated Circuit.
The connection port 924 is a port such as an USB port, an IEEE1394 port, a SCSI, an RS-232C port, or a port for connecting an externally connected device 930 such as an optical audio terminal. The externally connected device 930 is, for example, a printer, a mobile music player, a digital camera, a digital video camera, or an IC recorder. Moreover, the USB is an abbreviation for Universal Serial Bus. Also, the SCSI is an abbreviation for Small Computer System Interface.
The communication unit 926 is a communication device to be connected to a network 932, and is, for example, a communication card for a wired or wireless LAN, Bluetooth (registered trademark), or WUSB, an optical communication router, an ADSL router, or various communication modems. The network 932 connected to the communication unit 926 is configured from a wire-connected or wirelessly connected network, and is the Internet, a home-use LAN, infrared communication, visible light communication, broadcasting, or satellite communication, for example. Moreover, the LAN is an abbreviation for Local Area Network. Also, the WUSB is an abbreviation for Wireless USB. Furthermore, the ADSL is an abbreviation for Asymmetric Digital Subscriber Line.
<9: Summary>
Lastly, technical contents according to an embodiment of the present invention will be summarized.
The power management apparatus described above can be expressed as follows. The power management apparatus includes an authentication processing unit, a consumption amount acquiring unit, and an information display unit. The authentication processing unit is for carrying out an authentication process on each individual electronic appliance that is to be managed. Also, the consumption amount acquiring unit is for acquiring information on power consumption from the electronic appliance. Furthermore, the information display unit is for displaying an authentication state or an authentication result obtained from the authentication processing unit together with the information on power consumption acquired by the consumption amount acquiring unit.
As described, if not correctly authenticated by the power management apparatus, an electronic appliance is not provided with power. Thus, success/failure of authentication of each individual electronic appliance or whether or not authentication is being carried out is information of interest to a user using the electronic appliance. Thus, the power management apparatus mentioned above displays, together with power consumption of each individual electronic appliance, whether the electronic appliance is, at the time point, authenticated or not or whether authentication is being carried out or not. By adopting such display method, a user is enabled to appropriately grasp information on each individual electronic appliance. As a result, for example, in a case it is not possible to use an electronic appliance, the user can easily check whether the electronic appliance is broken down, whether authentication has simply failed, or whether authentication is being carried out.
It should be understood by those skilled in the art that various modifications, combinations, sub-combinations and alterations may occur depending on design requirements and other factors insofar as they are within the scope of the appended claims or the equivalents thereof.
The present application contains subject matter related to that disclosed in Japanese Priority Patent Application JP 2010-013585 filed in the Japan Patent Office on Jan. 25, 2010, the entire content of which is hereby incorporated by reference.
Number | Date | Country | Kind |
---|---|---|---|
P2010-013585 | Jan 2010 | JP | national |