JP2012055146A - Wireless power feeding system, position detection apparatus - Google Patents

Abstract

PROBLEM TO BE SOLVED: To feed a desired electric power optimally to an object on a planar propagation medium.SOLUTION: A wireless power feeding system according to the present invention stores in advance distribution data where a correspondence relation between a phase and amplitude of a transmission electrical power and electromagnetic field distribution within a planar propagation medium is described. A control part specifies the electromagnetic field distribution such that a specified electrical power may be supplied to the object on the planar propagation medium, and the phase and amplitude of the transmission electrical power at that time in accordance with the distribution data, and transmits the electrical power to the planar propagation medium with the phase and amplitude thereof.

Description

  The present invention relates to a wireless power feeding system and a position detection device using a planar propagation medium that propagates electromagnetic waves two-dimensionally.

  In recent years, networking of electronic devices has progressed in every field of social infrastructure, and the number of cords to be connected tends to increase. In data transmission, wireless is being promoted including a wireless LAN (Local Area Network), but the need for wireless is also increasing year by year for power supply. However, the wireless power feeding technology has been commercialized only for IH cooking heaters, shavers, cordless telephones, and the like that transmit at a very close distance in a contact state. With regard to three-dimensional transmission at a distance of several meters / several W or more, reduction of transmission efficiency due to radio wave diffusion becomes a major issue, and the current situation is that adoption of wireless power feeding technology has not progressed. Also, electronic devices for which wireless power feeding is commercialized have a large characteristic deterioration due to positional deviation, so that an installation location is designated and installation flexibility is poor.

  In the following Patent Document 1, as a technique for solving these problems, a planar dielectric is sandwiched between two planar conductors, electromagnetic waves can be transmitted between them, and one of the planar conductors is meshed, There is described a planar propagation medium that allows power to enter and exit just by placing an interface of a power transmission device in the vicinity via an evanescent wave that oozes out in the vicinity. In the technique described in this document, an electromagnetic wave propagating in a dielectric called a surface wave is confined in a planar propagation medium, and power is transmitted two-dimensionally along the planar propagation medium. Therefore, higher efficiency can be achieved as compared with three-dimensional transmission. In addition, power transmission is established only by installing an object to be transmitted on a planar propagation medium, so that the degree of freedom in installation is high.

  In Patent Document 2 below, as a technique for realizing improvement in power supply efficiency, which is an important issue of wireless power supply technology, it is described that power in a planar propagation medium is concentrated on a power supply target device. In the technique described in this document, a measurement wave is transmitted from the power supply target object to the power transmission side, and phase / amplitude information of the measurement wave received by a plurality of interfaces is measured. The power transmission amplitude and phase of each interface are controlled so that becomes maximum. Furthermore, it is disclosed that even if there are a plurality of power supply target objects, measurement waves are transmitted in order and power supply is performed in time series.

  In the following Patent Document 3, a technique for detecting the position of a power supply target device on a planar propagation medium is described. In this document, the RFID in the longitudinal direction of the planar propagation medium is determined by the time difference between the response of the RFID provided in the article on the planar propagation medium and the response via the planar propagation medium until the response is returned. Is estimated.

JP 2007-082178 A JP 2010-056994 A JP 2009-105600 A

  When power is supplied to multiple electronic devices in a time-sharing manner, there is a possibility that the power supply will be insufficient for electronic devices that have only a small amount of battery or no battery at all, and the operation of the device will stop. . In addition, there is a possibility that a human body or a metal can, which is a non-powered object placed on the planar propagation medium, may be overheated.

  The present invention has been made to solve the above-described problems, and an object thereof is to optimally supply a desired power to an object on a planar propagation medium.

  The wireless power feeding system according to the present invention holds in advance distribution data describing a correspondence relationship between the phase and amplitude of transmitted power and the electromagnetic field distribution in the planar propagation medium. The control unit specifies the electromagnetic field distribution in which the specified power is supplied to the object on the planar propagation medium and the phase and amplitude of the transmitted power at that time according to the distribution data, and the surface is determined by the phase and amplitude. Power is transmitted to the state propagation medium.

  According to the wireless power feeding system of the present invention, the electromagnetic field distribution in the planar propagation medium can be controlled to a desired state. Since the power supplied to the object on the planar propagation medium is determined by the electromagnetic field distribution in the planar propagation medium, it is supplied to the object on the planar propagation medium by controlling the electromagnetic field distribution. Electric power can be controlled. Thereby, the power supply to the object on the planar propagation medium can be optimized.

1 is a configuration diagram of a wireless power feeding system 100 according to Embodiment 1. FIG. 2 is a perspective view of a planar propagation medium 110. FIG. 6 is a configuration diagram of a wireless power feeding system 100 according to Embodiment 2. FIG. FIG. 6 is a configuration diagram of a wireless power feeding system 100 according to a fourth embodiment. It is a figure which shows a mode that the response signal from RFID tag 280 returns to the power transmission interface 120 via several paths. FIG. 10 is a configuration diagram of a wireless power feeding system 100 according to a fifth embodiment.

<Embodiment 1>
FIG. 1 is a configuration diagram of a wireless power feeding system 100 according to Embodiment 1 of the present invention. The wireless power feeding system 100 is a system that supplies power to the power receiving device 200, and includes a planar propagation medium 110, a power transmission interface 120, and a power transmission device 130.

  The planar propagation medium 110 transmits electric power by propagating electromagnetic waves two-dimensionally. FIG. 1 schematically shows a side sectional view of the planar propagation medium 110. The planar propagation medium 110 is configured by stacking a planar conductor 111, a planar dielectric 112, a planar mesh conductor 113, and a protective film 114 (second planar dielectric) in this order. Propagate as The planar propagation medium 110 transmits and receives power or communication signals via evanescent waves that ooze out in the vicinity of the planar mesh conductor 113.

  Inside the protective film 114, the RFID tag 115 is two-dimensionally arranged along the surface. The RFID tag 115 holds its two-dimensional coordinates on the planar propagation medium 110.

  The power transmission interface 120 is an interface that connects the power transmission device 130 and the planar propagation medium 110. The power transmission interface 120 transmits and receives power or a communication signal between the power transmission device 130 and the planar propagation medium 110.

  The power transmission device 130 is a device that transmits power to the power reception device 200 via the power transmission interface 120 and the planar propagation medium 110, and includes an amplitude control unit 131, a phase control unit 132, a table storage unit 133, a signal processing circuit 134, and a switch. 135 and a power generation unit 136.

  The amplitude control unit 131 and the phase control unit 132 control the amplitude and phase of power supplied by the power transmission device 130, respectively. Specifically, the amplitude and phase of the voltage or current supplied to the planar propagation medium 110 via the power transmission interface 120 are controlled.

  The table storage unit 133 includes the amplitude and phase of power supplied to the planar propagation medium 110 by the power transmission device 130 in the ideal state where nothing is arranged on the planar propagation medium 110, and the planar propagation medium at that time. The distribution table data describing the correspondence with the electromagnetic field distribution in 110 is stored. This distribution table data describes a plurality of patterns of the correspondence relationship. In order to control the electromagnetic field distribution in the planar propagation medium 110 to a desired state by referring to the distribution table data, what value should the amplitude and phase of the power transmitted by the power transmission device 130 be controlled to? I know if it ’s good. Since the power received by the power receiving device 200 is determined by the electromagnetic field distribution in the planar propagation medium 110, the power supplied to the power receiving device 200 is optimized by controlling the electromagnetic field distribution in the planar propagation medium 110. Can do.

  The signal processing circuit 134 controls the amplitude control unit 131 and the phase control unit 132. Further, it receives and processes communication signals transmitted and received between the power transmission device 130 and the planar propagation medium 110.

  The switch 135 turns on / off the connection between the power transmission interface 120 and the signal processing circuit 134. When there are a plurality of power transmission interfaces 120, a switch 135 may be provided for each power transmission interface 120.

  The power generation unit 136 generates power to be supplied to the planar propagation medium 110. The amplitude control unit 131 and the phase control unit 132 control the amplitude and phase of the power generated by the power generation unit 136 in accordance with instructions from the signal processing circuit 134.

  The power receiving device 200 is a device that receives power supplied from the power transmitting device 130 via the power transmitting interface 120 and the planar propagation medium 110, and includes a power receiving interface 210, a reader interface 220, a communication interface 230, an RFID reader 240, and an output control unit. 250, a wireless communication unit 260, and a rectifier circuit 270.

  The power receiving interface 210 is an interface for receiving power from the planar propagation medium 110. The reader interface 220 is an interface for reading information held by the RFID tag 115. The communication interface 230 is an interface for transmitting information to the power transmission device 130.

  The RFID reader 240 reads the two-dimensional coordinate information held by the RFID tag 115 via the reader interface 220. The output control unit 250 controls the output of the RFID reader 240. The wireless communication unit 260 transmits and receives information to and from the power transmission device 130 via the communication interface 230. The rectifier circuit 270 rectifies the power received via the power reception interface 210 into a direct current.

  The configuration of the wireless power feeding system 100 according to the first embodiment has been described above. Next, the role of the RFID 115 will be supplemented.

  In order to provide optimal power supply to the power receiving apparatus 200, it is necessary to accurately specify the position of the power receiving apparatus 200 on the planar propagation medium 110. This problem also applies to ensuring safety by not supplying power to non-powered objects.

  However, the position detection accuracy may deteriorate due to the influence of standing waves in the planar propagation medium 110. Since the size of the planar propagation medium 110 is finite, electromagnetic wave reflection occurs at the end regardless of whether the end structure of the planar propagation medium 110 is an open structure or a short-circuit structure, and the planar propagation medium 110 is fixed in the planar propagation medium. Create a wave. Due to this standing wave, the signal level for position measurement becomes unstable. In particular, since the signal level is lowered at the point where the standing wave becomes a node, the position detection accuracy is deteriorated, and accurate position detection becomes difficult. Hereinafter, a configuration in which the RFID tag 115 is arranged in the planar propagation medium 110 in order to accurately detect the position of the power receiving device 200 will be described.

  FIG. 2 is a perspective view of the planar propagation medium 110. The protective film 114 described with reference to FIG. 1 is omitted here. The planar mesh conductor 113 spreads in a grid pattern, and the amount of the electromagnetic field oozing out to the outside can be controlled by the mesh pitch. The planar dielectric 112 is preferably made of a material having a low dielectric constant and a low dielectric loss tangent in consideration of power efficiency.

  In FIG. 2, the end portion of the planar propagation medium 110 has an open structure, but even when the end portion is covered with a metal film or the like to form a short circuit structure, electromagnetic wave reflection occurs at the end portion. When electromagnetic wave reflection occurs, a standing wave is generated in the planar propagation medium 110, the position dependence of the electrical characteristics in the planar propagation medium 110 becomes very large, and stable electromagnetic wave propagation operation becomes difficult.

  Therefore, in the first embodiment, the RFID tag 115 for coordinate measurement is arranged in the protective film 114 that is not affected by the standing wave in the planar propagation medium 110. Thereby, the coordinates of the object placed on the planar propagation medium 110 can be measured with high accuracy.

The structure of the planar propagation medium 110 and the role of the RFID tag 115 have been described above. Next, the operation of the wireless power feeding system 100 will be described.
(Step 1: Acquire the position of the power receiving device 200)
The user places the power receiving apparatus 200 on the planar propagation medium 110 in order to supply power to the power receiving apparatus 200. The output control unit 250 gradually increases the output of the RFID reader 240 from low output to high output, and gradually increases the communication distance of the RFID reader 240 from a short distance to a long distance. The RFID reader 240 reads the two-dimensional coordinate information from the nearest RFID tag 115 via the reader interface 220. With this two-dimensional coordinate information, the position of the power receiving device 200 on the planar propagation medium 110 can be specified.

(Step 2: Send two-dimensional coordinate information)
The wireless communication unit 260 transmits the two-dimensional coordinate information read by the RFID reader 240 to the power transmission device 130. The two-dimensional coordinate information reaches the signal processing circuit 134 via the communication interface 230, the planar propagation medium 110, the power transmission interface 120, and the switch 135.

(Step 3: Determine the amplitude and phase of transmitted power)
The signal processing circuit 134 acquires, from the distribution table data held in the table storage unit 133, an electromagnetic field distribution that allows the desired power to be supplied to the power receiving device 200 in the two-dimensional coordinates received in Step 2. The power value desired by the power receiving apparatus 200 may be stored in advance in the table storage unit 133 or the like as the power value desired by the power receiving apparatus 200, or may be calculated using some calculation formula corresponding to the two-dimensional coordinates. Also good. The signal processing circuit 134 determines the amplitude and phase of transmitted power so that the power receiving apparatus 200 can obtain desired power according to the description of the distribution table data.

(Step 3: Determine amplitude and phase of transmitted power: supplement)
In step 2, when transmitting the two-dimensional coordinate information from the wireless communication unit 260 to the power transmitting device 130, information that can specify the power value desired by the power receiving device 200 is also transmitted as power demand information. Also good. For example, it is conceivable to transmit the remaining battery level of the power receiving apparatus 200.

(Step 4: Adjust transmitted power)
The signal processing circuit 134 instructs the amplitude control unit 131 and the phase control unit 132 to output the amplitude and phase of the transmission power determined in step 3. The amplitude control unit 131 and the phase control unit 132 control the amplitude and phase of transmitted power according to the instructions.

(Step 5: Power transmission)
The power transmission device 130 transmits power to the power reception device 200 using the amplitude and phase adjusted in step 4.

(Step 5: Power transmission: supplement)
Since the distribution table data is data describing an electromagnetic field distribution in a state where nothing is placed on the planar propagation medium 110, the electromagnetic field in the planar propagation medium 110 is placed with the power receiving device 200 mounted. The distribution may be slightly different from when nothing is placed. In this case, as described in step 6 below, the distribution table data describes the power transmission amplitude and power transmission phase at which the power supply is optimized by feeding back the value of the received power from the power receiving device 200 to the power transmission device 130. You may make it search in the vicinity of the value which is.

(Step 6: Repeat above)
The power transmission device 130 and the power reception device 200 may repeatedly execute the above steps 1 to 5 at a predetermined time interval, for example. In this case, even when the position of the power receiving device 200 moves, it is possible to always provide optimum power feeding. Further, in the process of repeating the above steps, the power transmission device 260 notifies the power transmission device 130 of the amplitude and phase of the power received by the power reception device 200 as power demand information, and readjusts the amplitude and phase of the transmission power. You can also.

<Embodiment 1: Summary>
As described above, the wireless power feeding system 100 according to the first embodiment holds the correspondence relationship between the amplitude and phase of transmitted power and the electromagnetic field distribution in the planar propagation medium 110 in advance as distribution table data. Thereby, the electromagnetic field distribution in the planar propagation medium 110 can be controlled to a desired state. That is, the electromagnetic field distribution can be controlled so that the power supply state at a specific position on the planar propagation medium 110 is optimal.

  Further, according to the first embodiment, even when a plurality of power receiving apparatuses 200 are installed, the electromagnetic field distribution in the planar propagation medium 110 is controlled so that the power supply state at each installation position is optimal. By doing so, the electric power feeding with respect to each power receiving apparatus 200 can be optimized individually.

  Further, according to the first embodiment, even when a standing wave is generated in the planar propagation medium 110, the distribution table data taking into account the influence of the standing wave is stored in advance, so that the standing wave It is possible to mitigate the influence such as a decrease in power supply efficiency due to the occurrence.

  In addition, the wireless power feeding system 100 according to the first embodiment arranges the RFID tag 115 holding the two-dimensional coordinate information in the planar propagation medium 110, and the RFID reader 240 included in the power receiving apparatus 200 stores the two-dimensional coordinate information. read. Thereby, the position of the power receiving apparatus 200 can be detected with high accuracy.

  According to the first embodiment, since the RFID tag 115 is disposed in the protective film 114, the communication distance between the RFID tag 115 and the RFID reader 240 can be reduced. Accordingly, the wireless power feeding system 100 can be configured with the inexpensive RFID tag 115 and the RFID reader 240. Furthermore, since the output of the RFID reader 240 can be reduced, the influence of standing waves generated in the planar propagation medium 110 can be reduced.

  In the first embodiment, the RFID tag 115 is arranged in the protective film 114 that is not affected by the standing wave in the planar propagation medium 110. Thereby, the position of the power receiving apparatus 200 placed on the planar propagation medium 110 can be detected with high accuracy.

<Embodiment 2>
FIG. 3 is a configuration diagram of the wireless power feeding system 100 according to the second embodiment of the present invention. In the second embodiment, a configuration assuming that the power receiving apparatus 200 is a low-function device that does not have a wireless communication function will be described.

  In the second embodiment, the power receiving device 200 does not include the wireless communication device 260 and the communication interface 230 described in the first embodiment. Instead, the power transmission device 130 is newly provided with an RFID reader 137.

  In the second embodiment, the RFID tag 115 is desirably disposed inside the planar dielectric 112. The reason for this will be described later.

The configuration of the wireless power feeding system 100 according to the second embodiment has been described above. Next, the operation of the wireless power feeding system 100 will be described.
(Step 1: Send a reading request to the RFID tag 115)
The user places the power receiving apparatus 200 on the planar propagation medium 110 in order to supply power to the power receiving apparatus 200. The output control unit 250 gradually increases the output of the RFID reader 240 from low output to high output, and gradually increases the communication distance of the RFID reader 240 from a short distance to a long distance. As a result, a reading request is transmitted to the RFID tag 115 closest to the reader interface 220.

(Step 2: Receive a response from the RFID tag 115)
In the second embodiment, when a reading request reaches the RFID tag 115 from the RFID reader 240, the RFID tag 115 transmits a response signal. This response signal propagates in the planar propagation medium 110. In the second embodiment, since the RFID tag 115 is disposed at a deeper position than that in the first embodiment, the response signal is more easily propagated in the in-plane direction than in the first embodiment. Therefore, the RFID reader 137 included in the power transmission device 130 can also receive a response signal transmitted from the RFID tag 115. That is, even if the power receiving apparatus 200 does not transmit the two-dimensional coordinate information to the power transmitting apparatus 130, the power transmitting apparatus 130 can acquire the two-dimensional coordinate information by itself, and thus the power receiving apparatus 200 does not have a wireless transmission function. Also good.

(Step 2: Receive a response from the RFID tag 115: supplement)
The position of the RFID tag 115 in the depth direction need not be inside the planar dielectric 112. Regardless of the position in the depth direction, the response signal transmitted by the RFID tag 115 propagates in the in-plane direction, so that the RFID reader 137 can receive the response signal. However, from the viewpoint of the strength of the response signal, it is desirable that the RFID tag 115 is disposed at a position close to the central portion in the depth direction.

(Step 3 to Step 6: common with the first embodiment)
The signal processing circuit 134 acquires the two-dimensional coordinates of the RFID tag 115 from the response signal received by the RFID reader 137. The subsequent processing is the same as that of the first embodiment.

<Embodiment 2: Summary>
As described above, according to the second embodiment, the power transmission device 130 includes the RFID reader 137 that receives a response signal transmitted from the RFID tag 115, so the power reception device 200 transmits information held by the RFID tag 115. It does not have to have a function. Thereby, even when the power receiving apparatus 200 is a low-functional device that does not have a wireless communication function, the same effects as those of the first embodiment can be exhibited.

<Embodiment 3>
In the first and second embodiments described above, when a standing wave exists in the planar propagation medium 110, when the position of the RFID tag 115 overlaps a node portion of the standing wave, information held by the RFID tag 115 is retained. The accuracy of detecting the position of the power receiving device 200 is reduced.

  Therefore, it is conceivable to reduce the influence of the standing wave by reducing the arrangement interval of the RFID tags 115 to be shorter than ½ of the effective wavelength of the electromagnetic wave propagating in the planar propagation medium 110. In this case, since all the RFID tags 115 are not positioned at the nodes of the standing wave, the influence of the standing wave can be reduced and the position of the power receiving apparatus 200 can be detected with high accuracy.

<Embodiment 4>
In the fourth embodiment of the present invention, another method for detecting the position of the power receiving apparatus 200 on the planar propagation medium 110 when the power receiving apparatus 200 does not have a wireless communication function will be described.

  FIG. 4 is a configuration diagram of the wireless power feeding system 100 according to the fourth embodiment. In the fourth embodiment, the power receiving device 200 includes an RFID tag 280. The RFID tag 280 is disposed at a portion where the power receiving device 200 and the planar propagation medium 110 face each other. The configurations of the planar propagation medium 110 and the power transmission interface 120 are the same as those in the first and second embodiments. The configuration of the power transmission device 130 is the same as that of the second embodiment.

The configuration of the wireless power feeding system 100 according to the fourth embodiment has been described above. Next, the operation of the wireless power feeding system 100 will be described.
(Step 1: Send a reading request to the RFID tag 280)
The user places the power receiving apparatus 200 on the planar propagation medium 110 in order to supply power. The RFID reader 137 transmits a read request to the RFID tag 280 via the switch 135, the power transmission interface 120, and the planar propagation medium 110. The RFID tag 280 that has received the read request returns a response signal along with its own ID along the same route. The RFID reader 137 receives a response signal from the RFID tag 280.

(Step 2: Estimate the distance to the RFID tag 280)
The signal processing circuit 134 estimates the distance between the power transmission interface 120 and the RFID tag 280 based on the elapsed time until the RFID reader 137 transmits a read request and receives the response signal, and based on the distance, the RFID tag 280 two-dimensional coordinates are estimated. When a plurality of power transmission interfaces 120 are used, the distance between each power transmission interface 120 and the RFID tag 280 can be similarly estimated, and the two-dimensional coordinates of the RFID tag 280 can be estimated using the principle of triangulation. As the number of power transmission interfaces 120 increases, the two-dimensional coordinates of the RFID tag 280 can be estimated more accurately.

(Step 3 to Step 6: common with the first embodiment)
The signal processing circuit 134 assumes that the power receiving device 200 exists at the position of the RFID tag 280 estimated in step 2. Thereafter, Steps 3 to 6 are performed according to the same procedure as in the first embodiment.

  FIG. 5 is a diagram illustrating a state in which a response signal from the RFID tag 280 returns to the power transmission interface 120 via a plurality of paths. Since electromagnetic wave reflection occurs at the end of the planar propagation medium 110, there may be a plurality of response signal paths returning to the power transmission interface 120. Hereinafter, a method of estimating the distance to the RFID tag 280 using an appropriate response signal will be described.

  In FIG. 5A, power transmission interfaces 120a, 120b, 120c, and 120d are connected to the planar propagation medium 110 on which the RFID tag 280 is placed. Here, for the sake of simplicity of explanation, a plurality of reflections are not taken into consideration, and only one reflection is an object. In this case, P1, P2, P3, and P4 shown in FIG. 5A are candidates for the route from the RFID tag 280 to the power transmission interface 120a.

  FIG. 5B is a graph showing the path lengths D1, D2, D3, and D4 corresponding to the paths P1 to P4 shown in FIG. 5A and the signal strengths S1, S2, S3, and S4 corresponding to the respective paths. It has become. Compared to S2, S3, and S4 that are reflected once at the edge of the planar propagation medium 110, S1 that directly reaches the power transmission interface 120a without reflection has a stronger response signal. That is, it is understood that the distance from the power transmission interface 120 to the RFID tag 280 should be estimated using the response signal having the strongest signal strength.

  Similarly, the response signal that travels directly from the RFID tag 280 toward the power transmission interface 120a seems to have the shortest elapsed time since the reading request was transmitted. Therefore, the distance from the power transmission interface 120 to the RFID 280 may be estimated using a response signal that is first reached after the reading request is transmitted.

<Embodiment 4: Summary>
As described above, according to the fourth embodiment, the signal processing circuit 134 estimates the distance between the RFID tag 280 included in the power receiving apparatus 200 and the power transmission interface 120, and specifies the position of the RFID tag 280 based on this. . Thereby, even when the power receiving apparatus 200 is a low-functional device that does not have a wireless communication function, the same effects as those of the first embodiment can be exhibited.

<Embodiment 5>
In the fifth embodiment of the present invention, a method for detecting the position when the non-power-feeding object 300 is placed on the planar propagation medium 110 will be described. Examples of the non-power supply target 300 include a human body (when a person places his / her hand on the planar propagation medium 110).

  Since the non-powered object 300 is not assumed to be supplied with electric power, the RFID reader 240 and the RFID tag 280 do not have a configuration for detecting the position. Therefore, in the fifth embodiment, the electromagnetic wave transmitted from the power transmission device 130 is used like a radar to detect the position of the non-power supply target 300.

  FIG. 6 is a configuration diagram of the wireless power feeding system 100 according to the fifth embodiment. The power transmission device 130 includes a mixer 138 in addition to the configurations described in the first to fourth embodiments. In FIG. 6, the configuration in which the mixer 138 is provided in addition to the configuration described in the first embodiment is illustrated, but the mixer 138 may be provided under the configuration in the other embodiments.

  The mixer 138 receives the reflected wave received by the power transmission interface 120 and the modulation signal output from the power generation unit 136, and outputs an IF (Intermediate Frequency) frequency signal to the signal processing circuit 134.

The configuration of the wireless power feeding system 100 according to the fifth embodiment has been described above. Next, the operation of the wireless power feeding system 100 will be described.
(Step 1: Transmit modulated signal)
First, the signal processing circuit 134 and the power generation unit 136 generate a modulated signal with a low power of the milliwatt class instead of a high power at the time of power feeding. The modulation signal is input to the planar propagation medium 110 via the power transmission interface 120. The modulation signal transmitted by the power transmission device 130 in this step is a so-called radar modulation signal. Signals used as radar modulation signals are generally two-frequency CW (Continuous Wave) and FMCW (Frequency Modulation Continuous Wave).

(Step 2: Receive the reflected wave)
In the planar propagation medium 110, impedance mismatch occurs due to the non-power-feeding object 300 being placed, and a reflected wave is generated. The reflected wave reaches the mixer 138 via the power transmission interface 120 and the switch 135. The mixer 138 also receives the modulation signal output from the power generation unit 136. The mixer 138 outputs the IF frequency signal to the signal processing circuit 134.

(Step 3: Calculate 2D coordinates)
The signal processing circuit 134 can calculate the distance of the non-feed object 300 by observing the phase of the reflected wave of the modulation signal. Furthermore, by using two or more power transmission interfaces 120 and observing the phase difference of each reflected wave, the direction in which the non-power-feed target 300 is present can be obtained. As a result, the two-dimensional coordinates of the non-powered object 300 can be acquired.

(Step 4: Adjust the amplitude and phase of the modulation signal)
In some cases, the reflected wave from the non-powered object 300 is not observed due to the standing wave in the planar propagation medium 110. In this case, the signal processing circuit 134 instructs the amplitude control unit 131 and the phase control unit 132 to change the amplitude and phase of the modulation signal so that the reflected wave can be received, and performs Step 1 to Step 3 again. To do.

(Step 5: Power transmission)
The signal processing circuit 134 adjusts the electromagnetic field distribution in the planar propagation medium 110 so that the position of the non-power-feeding object 300 becomes the power null point. When the power receiving device 200 is also placed on the planar propagation medium 110 at the same time, in addition to the above, the electromagnetic field in the planar propagation medium 110 is supplied so that desired power is supplied at the position of the power receiving device 200. Adjust the distribution. The method for adjusting the electromagnetic field distribution is the same as in the first to fourth embodiments.

<Embodiment 5: Summary>
As described above, the wireless power feeding system 100 according to the fifth embodiment transmits the modulation signal to the non-powered object 300 and demodulates the reflected wave. Thereby, the distance from the power transmission interface 120 to the non-power-feed target 300 can be measured using a so-called radar principle. Further, the direction in which the non-power-feed target 300 is present can also be specified using the phase difference of the reflected waves at the plurality of power transmission interfaces 120. With these functions, it is possible to specify the position of the non-power-feed target 300 that does not have a configuration for detecting the position.

  In the fifth embodiment, the switch 135 can be replaced with a circulator or a directional coupler. Furthermore, although the power transmission interface 120 is arranged on one side of the planar propagation medium 110, it can also be arranged on each of a plurality of sides. Thereby, power supply performance and position detection performance can be improved. The same applies to other embodiments.

  In the fifth embodiment, the two-dimensional coordinates of the non-powered object 300 are acquired by comparing the phases of the reflected waves of the modulation signal. However, the modulation signal is not used and the planar propagation medium 110 is used. The two-dimensional coordinates of the non-powered object 300 can also be obtained by scanning the area where the electromagnetic field distribution is the maximum intensity point and observing the amplitude of the reflected wave.

  Further, in the fifth embodiment, the method of detecting the position of the non-power-feed target 300 that does not have a configuration for position detection has been described. However, the position of the power receiving device 200 may be detected using a similar method. it can. However, the position can be detected more accurately by using a configuration such as the RFID tag 115 or 280.

<Embodiment 6>
In the first to fifth embodiments described above, one planar propagation medium 110 is used. However, a configuration in which a plurality of planar propagation media 110 are arranged side by side and a power transmission interface 120 is connected to each planar propagation medium 110. Can also be adopted.

  In this case, the signal processing circuit 134 first specifies on which planar propagation medium 110 the power receiving device 200 or the non-power-feeding object 300 is placed. Thereafter, the position of the power receiving device 200 or the non-power-feeding object 300 on the specified planar propagation medium 110 is specified by the method described in the first to fifth embodiments. Thereby, the position of the power receiving apparatus 200 or the non-power-feeding object 300 can be detected with high accuracy.

<Embodiment 7>
In the first to sixth embodiments described above, the power transmission interface 120 transmits and receives power or communication signals. However, for example, when the power transmission frequency and the communication frequency are set differently to avoid interference, the communication interface May be provided separately.

  In the first to sixth embodiments described above, when a plurality of power transmission interfaces 120 are provided, as many wires as the number of the power transmission interfaces 120 may be provided to connect each power transmission interface 120 and the signal processing circuit 134 via the switch 135. Wiring may be shared between the power transmission interfaces 120. However, if there are a plurality of power transmission interfaces 120 and wirings, the effect of space diversity can be expected, so that more stable communication can be performed.

  In the above first to sixth embodiments, the distribution table data may be created by actually measuring the electromagnetic field distribution in the planar propagation medium 110 using an electromagnetic field probe or the like, or may be created by, for example, electromagnetic field simulation. Good. In addition, only the amplitude and coordinates that are the maximum intensity points of the electromagnetic field distribution generated in the planar propagation medium 110 may be held in the distribution table data.

  However, when there are a plurality of power receiving devices 200, it is desirable to obtain an electromagnetic field distribution having a plurality of maximum values so that power can be efficiently received at a plurality of coordinates. In addition, when the power receiving device 200 that should not be fed in the fully charged state is placed on the planar propagation medium 110 in addition to the non-powered object 300, the power null point is located at that position. Is desirable. Therefore, it is desirable to prepare distribution table data that holds as many electromagnetic field distribution patterns as possible.

  The configurations described in the first to sixth embodiments can be appropriately combined. For example, the configuration for detecting the position of the non-power-feed target 300 described in the fifth embodiment and the configuration described in the other embodiments can be used in combination.

<Eighth embodiment>
The wireless power feeding system 100 described in the first to seventh embodiments can also be used as a position detection device that identifies the position of an object such as the power receiving device 200 or the non-power feeding target 300 on the planar propagation medium 110.

  100: wireless power feeding system, 110: planar propagation medium, 111: planar conductor, 112: planar dielectric, 113: planar mesh conductor, 114: protective film, 115: RFID tag, 120: power transmission interface, 130: Power transmission device 131: Amplitude control unit 132: Phase control unit 133: Table storage unit 134: Signal processing circuit 135: Switch 136: Power generation unit 137: RFID reader 138: Mixer 200: Power reception device 210: power receiving interface, 220: reader interface, 230: communication interface, 240: RFID reader, 250: output control unit, 260: wireless communication device, 270: rectifier circuit, 280: RFID tag, 300: non-powered object.

Claims (20)

A planar propagation medium configured by superimposing a planar conductor and a planar dielectric, and propagating electromagnetic waves two-dimensionally;
An interface connected to the planar propagation medium;
A power transmission device for supplying power to the planar propagation medium via the interface;
A control unit for controlling the phase and amplitude of the transmission power supplied by the power transmission device;
Distribution data describing the correspondence between the phase and amplitude of transmitted power supplied by the power transmission device and the electromagnetic field distribution in the planar propagation medium when power is supplied to the planar propagation medium with the phase and amplitude. When,
A position detector that identifies the position of an object present on the planar propagation medium;
With
The controller is
Obtaining a specified value of power to be supplied to the object;
In accordance with the description of the distribution data, specify the phase and amplitude of the transmitted power at which the electromagnetic field distribution corresponding to the specified value is obtained at the position of the object on the planar propagation medium specified by the position detection unit. And
According to the specified phase and amplitude, the power supplied from the power transmission device to the planar propagation medium is controlled. The planar propagation medium is
A plurality of RFID tags for holding two-dimensional coordinates on the planar propagation medium;
The position detector is
The wireless power feeding system according to claim 1, wherein the position of the object is specified based on the two-dimensional coordinates held by the RFID tag. The object is
An RFID reader for reading coordinate information held by the RFID tag;
A communication unit that transmits coordinate information read by the RFID reader;
With
The position detector is
The wireless power feeding system according to claim 2, wherein the position of the object is specified based on the coordinate information transmitted by the communication unit. The object is
A power receiving unit that receives power supplied from the power transmission device via the planar propagation medium;
The communication unit is
Transmitting power demand information indicating the power to be supplied to the object;
The controller is
The wireless power feeding system according to claim 3, wherein the specified value is determined according to the power demand information transmitted by the communication unit. The planar propagation medium is configured by stacking a planar conductor, a planar dielectric, a planar mesh conductor, and a second planar dielectric in this order, and the RFID tag is placed inside the second planar dielectric. The wireless power feeding system according to claim 3, wherein the wireless power feeding system is arranged. The object is
A transmission unit that transmits a reading request to the coordinate information held by the RFID tag;
The power transmission device is:
An RFID reader that reads a response signal transmitted by the RFID tag as a response to the read request;
The position detector is
The wireless power feeding system according to claim 2, wherein the position of the object is specified based on the coordinate information included in the response signal received by the RFID reader. The planar propagation medium is configured by stacking a planar conductor, a planar dielectric, and a planar mesh conductor in this order, and the RFID tag is disposed inside the planar dielectric. 6. The wireless power feeding system according to 6. The wireless power feeding system according to claim 2, wherein the RFID tags are arranged at an interval shorter than ½ of an effective wavelength of electromagnetic waves propagating in the planar propagation medium. An RFID reader for reading coordinate information held by the RFID tag;
The RFID reader includes an output control unit that changes an output,
The output control unit
The wireless power feeding system according to claim 2, wherein the communication distance of the RFID reader is gradually increased from a short distance to a long distance by gradually increasing the output of the RFID reader. The object comprises an RFID tag;
The power transmission device is:
An RFID reader that transmits a read request to the RFID tag and receives a response signal thereof,
The position detector is
The RFID reader estimates the distance from the interface to the object using the time until the RFID reader transmits the read request and receives the response signal, or the strength of the response signal, and the object is based on the distance. The wireless power feeding system according to claim 1, wherein the position of is identified. The power transmission device is:
Transmitting a modulation signal to the planar propagation medium via the interface, receiving a reflected wave of the modulation signal from the object via the interface;
The position detector is
The wireless power feeding system according to claim 1, wherein a distance from the interface to the object is estimated using the reflected wave, and a position of the object is specified based on the distance. A plurality of the interfaces are connected to the planar propagation medium,
The position detector is
The wireless power feeding system according to claim 11, wherein the direction of the object viewed from the interface is specified using the phases of the reflected waves received by each of the plurality of interfaces. The controller is
Changing the intensity of the reflected wave by changing the phase and amplitude of the modulated signal according to the description of the distribution data;
The position detector is
The wireless power feeding system according to claim 11, wherein a distance from the interface to the object is estimated using each reflected wave whose intensity is changed and a description of the distribution data corresponding to the reflected wave. Arranging a plurality of the above-mentioned planar propagation media in a predetermined position,
At least one of the interfaces is connected to each of the planar propagation media,
The position detector is
Identify on which planar propagation medium the object is present,
The wireless power feeding system according to claim 1, wherein the position of the object on the specified planar propagation medium is specified. The wireless power feeding system according to claim 1, wherein the interface is connected to the planar propagation medium in different directions at a plurality of locations of the planar propagation medium. A planar propagation medium configured by superimposing a planar conductor and a planar dielectric, and propagating electromagnetic waves two-dimensionally;
An interface connected to the planar propagation medium;
A power transmission device for supplying power to the planar propagation medium via the interface;
A position detector that identifies the position of an object present on the planar propagation medium;
With
The power transmission device is:
Transmitting a modulation signal to the planar propagation medium via the interface, receiving a reflected wave of the modulation signal from the object via the interface;
The position detector is
A position detection device that estimates a distance from the interface to the object using the reflected wave, and identifies the position of the object based on the distance. The planar propagation medium is
A plurality of RFID tags for holding two-dimensional coordinates on the planar propagation medium;
The object is
An RFID reader for reading coordinate information held by the RFID tag;
A communication unit that transmits coordinate information read by the RFID reader;
With
The position detector is
The position detection device according to claim 16, wherein the position of the object is specified based on the coordinate information transmitted by the communication unit. The planar propagation medium is
A plurality of RFID tags for holding two-dimensional coordinates on the planar propagation medium;
The object is
A transmission unit that transmits a reading request to the coordinate information held by the RFID tag;
The power transmission device is:
An RFID reader that reads a response signal transmitted by the RFID tag as a response to the read request;
The position detector is
The position detection device according to claim 16, wherein the position of the object is specified based on the coordinate information included in the response signal received by the RFID reader. Distribution data describing the correspondence between the phase and amplitude of transmitted power supplied by the power transmission device and the electromagnetic field distribution in the planar propagation medium when power is supplied to the planar propagation medium with the phase and amplitude. With
The controller is
Changing the intensity of the reflected wave by changing the phase and amplitude of the modulated signal according to the description of the distribution data;
The position detector is
The position detection device according to claim 16, wherein a distance from the interface to the object is estimated using each reflected wave whose intensity is changed and a description of the distribution data corresponding to the reflected wave. Arranging a plurality of the above-mentioned planar propagation media in a predetermined position,
At least one of the interfaces is connected to each of the planar propagation media,
The position detector is
Identify on which planar propagation medium the object is present,
The position detection apparatus according to claim 16, wherein the position of the object on the specified planar propagation medium is specified.

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