JP2004128746A - Transceiver - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To maintain an optimum communication state under any conditions in a transceiver which induces an electric field in an electric field transmission medium on the basis of information to be transmitted and transmits and receives the information using the induced electric field. <P>SOLUTION: The amplitude of an electric signal outputted from a fixed gain amplifier 116 is measured by an amplitude measurement section 21. Connection modes of a receiver side connector 11 and a grounding side connector 13 are feedback-controlled by a controller 23 on the basis of a result of the measurement. Consequently, the strength of an electric signal to be outputted form a signal processing circuit 20 can be kept at a predetermined value, and the optimum communication state can be always maintained. <P>COPYRIGHT: (C)2004,JPO

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to a transceiver used, for example, for data communication between wearable computers, and more particularly to a transceiver for receiving information based on an electric field induced in an electric field transmission medium such as a living body. The present invention relates to a transceiver capable of receiving information through the transceiver.
[0002]
[Prior art]
2. Description of the Related Art In recent years, computers with a new concept of being able to be worn, operated, and used on a human body like clothes have been attracting attention. This computer is called a wearable computer, and can be realized by reducing the size and the performance of the portable terminal.
[0003]
In addition, research on a technology for performing data communication between a plurality of wearable computers via a human body (living body) such as a human arm, shoulder, and torso has been advanced, and this technology has already been proposed in patent documents and the like (for example, And Patent Document 1). FIG. 7 shows an image diagram in the case of performing communication between a plurality of wearable computers via such a human body. As shown in the figure, the wearable computer 1 forms a set with the transceiver 3 'in contact with the wearable computer 1, and the other set of the wearable computer 1 and the transceiver 3' can pass through the human body. Can perform data communication. The wearable computer 1 is a set of a personal computer (PC) 5 other than the wearable computer 1 worn on the human body and a transceiver 3'a installed on a wall or the like, or installed on the PC 5 and the floor. Data communication with the set of transceivers 3'b is also possible. However, the PC 5 in this case is not in contact with each other like the wearable computer 1 and the transceiver 3 ′, but is connected to the transceivers 3 ′ a and 3 ′ b via the cable 4.
[0004]
As for data communication through the human body, an electric field based on information (data) to be transmitted is transmitted by using a signal detection technique based on an electro-optical method using a laser beam and an electro-optical crystal. And information is transmitted and received using the induced electric field. The technique of data communication via the human body will be described in more detail with reference to FIGS.
[0005]
FIG. 8 is an overall configuration diagram of a transceiver 3 ′ used for performing data communication via a human body (living body 100). FIG. 9 is a configuration diagram showing a detailed configuration of the electric field detection optical unit 110 in the transceiver 3 ′.
[0006]
As shown in FIG. 8, the transceiver 3 'is used in a state where the transmission electrode 105 and the reception electrode 111 are in contact with the living body 100 via the insulating films 107 and 109, respectively. Then, the transceiver 3 ′ receives the data supplied from the wearable computer 1 via the I / O (input / output) circuit 101 and transmits the data to the transmission unit 103 as shown in FIG. In the transmitting unit 103, an electric field is induced from the transmission electrode 105 through the insulating film 107 to the living body 100, which is an electric field transmission medium, and the electric field is transmitted to another part of the living body 100 via the living body 100. To 3 '.
[0007]
Further, the transceiver 3 ′ receives the electric field induced and transmitted to the living body 100 from another transceiver 3 ′ attached to another part of the living body 100 at the receiving electrode 111 via the insulating film 109, and receives the received electric field. The generated electric field is coupled (applied) to the electro-optic crystal by the electric field detection optical unit 110, converted into an electric signal, and transmitted to the signal processing circuit 115. The signal processing circuit 115 performs signal processing such as amplification and noise removal of the transmitted electric signal, and then transmits the signal to the waveform shaping circuit 117. The waveform shaping circuit 117 performs waveform shaping of the transmitted electric signal and supplies the electric signal to the wearable computer 1 via the input / output circuit 101.
[0008]
For example, as shown in FIG. 7, the wearable computer 1 mounted on the right arm causes the transceiver 3 'to induce an electric signal related to transmission data as an electric field in the living body 100, which is an electric field transmission medium, as shown by a broken line. 100 to other parts. On the other hand, in the wearable computer 1 mounted on the left arm, the electric field transmitted from the living body 100 can be converted into an electric signal by the transceiver 3 ′ and then received as reception data.
[0009]
The process of returning to an electric signal by the transceiver 3 ′ is performed by the electric field detection optical unit 110 that detects an electric field by an electro-optical method using a laser beam and an electro-optical crystal. As shown in FIG. 9, the electric field detection optical unit 110 includes a current source 119, a laser diode 121, an electro-optic element (electro-optic crystal) 123, first and second wave plates 135 and 137, a deflection beam splitter 139, And the photodiodes 143a and 143b, and the ground electrode 131. Note that the signal electrode 129 corresponds to the receiving electrode 111 in the transceiver 3 'having a configuration as shown in FIG.
[0010]
Among these, the electro-optical element 123 has sensitivity only to an electric field coupled in a direction perpendicular to the traveling direction of the laser light from the laser diode 121, and the optical characteristics, that is, the birefringence, are changed by the electric field strength. The configuration is such that the polarization of the laser light is changed by the change in the birefringence. A first electrode 125 and a second electrode 127 are provided on both side surfaces of the electro-optical element 123 that face each other in the vertical direction in the drawing. The first electrode 125 and the second electrode 127 sandwich the traveling direction of the laser light from the laser diode 121 in the electro-optical element 123 from both sides, and can couple an electric field to the laser light at a right angle.
[0011]
Further, the electric field detecting optical unit 110 is connected to the signal electrode 129 (the receiving electrode 111) via the first electrode 125. The second electrode 127 facing the first electrode 125 is connected to the ground electrode 131, and is configured to function as a ground electrode for the first electrode 125. When the signal electrode 129 detects an electric field induced and transmitted to the living body 100, the signal electrode 129 transmits the electric field to the first electrode 125 and can be coupled to the electro-optical element 123 via the first electrode 125. .
[0012]
On the other hand, the laser light output from the laser diode 121 by the current control of the current source 119 is converted into parallel light through the collimating lens 133, and the parallel light is adjusted in the polarization state by the first wavelength plate 135. Incident on the electro-optical element 123. The laser light incident on the electro-optical element 123 propagates between the first and second electrodes 125 and 127 in the electro-optical element 123, and during the propagation of the laser light, the signal electrode 129 is applied to the living body as described above. When an electric field induced and transmitted by the electric field 100 is detected and the electric field is coupled to the electro-optical element 123 via the first electrode 125, the electric field is connected to the second electrode connected to the ground electrode 131 from the first electrode 125. Are formed toward the electrode 127. Since this electric field is perpendicular to the traveling direction of the laser light that has entered the electro-optical element 123 from the laser diode 121, the birefringence, which is an optical characteristic of the electro-optical element 123, changes, thereby changing the polarization of the laser light. I do.
[0013]
Next, in the electro-optical element 123, the laser light whose polarization has been changed by the electric field from the first electrode 125 is adjusted in the polarization state by the second wavelength plate 137 and enters the polarization beam splitter 139. The polarization beam splitter 139 separates the laser light incident from the second wavelength plate 137 into a P wave and an S wave, and converts the laser light into a change in light intensity. The laser beam split into a P-wave component and an S-wave component by the polarization beam splitter 139 is condensed by first and second condenser lenses 141a and 141b, respectively, and then the first component constituting the photoelectric conversion means is formed. The second and third photodiodes 143a and 143b can receive light, and convert the P-wave optical signal and the S-wave optical signal into respective electrical signals in the first and second photodiodes 143a and 143b. As described above, the current signals output from the first and second photodiodes 143a and 143b are converted into voltage signals using resistors, and then amplified and noise removed by the signal processing circuit 115 shown in FIG. After being subjected to signal processing of waveform shaping by the waveform shaping circuit 117, the signal is supplied to the wearable computer 1 via the input / output circuit 101.
[0014]
[Patent Document 1]
JP 2001-352298 A (Pages 4-5, FIG. 1-5)
[0015]
[Problems to be solved by the invention]
However, the strength of the electric field induced in the human body differs depending on the place where the human body is placed and whether the power supply source is an AC power supply or a battery. Therefore, it is necessary to adjust the receiving sensitivity according to the situation. For example, when a person wearing the wearable computer 1 and the transceiver 3 ′ shakes hands with each other, and when a person wearing the wearable computer 1 and the transceiver 3 ′ shakes hands of the transceivers 3 ′ a and 3 b connected to the PC 5 connected to AC power. Compared with the case where the electrodes are directly touched, the difference in the electric field strength induced by the human is extremely different, so that an optimum communication state satisfying both cannot be secured.
[0016]
The present invention has been made in view of the above circumstances, and has as its object to maintain an optimum communication state under any circumstances.
[0017]
[Means for Solving the Problems]
In order to achieve the above object, the invention according to claim 1 is a transceiver capable of receiving information via the electric field transmission medium by receiving information based on an electric field induced in the electric field transmission medium. A first electrode group consisting of a plurality of electrodes that can be connected to a reception electrode that is in contact with the electric field transmission medium via an insulator, and a plurality of electrodes that function as ground electrodes with respect to the first electrode group. A second electrode group consisting of an electrode is provided, and an electric field is induced and transmitted to the electric field transmission medium, thereby changing the polarization of the laser light incident between the first and second electrode groups. Electro-optical means that can be changed, reception-side connection means for connecting some or all of the electrodes of the first electrode group to the reception electrodes, and one of the second electrode groups. Part or all electrodes and the ground electrode Ground-side connecting means for connecting the electric field detection means for detecting an electric field based on the polarization of the laser light changed by the electro-optical means, and converting the electric field into an electric signal as received information, and the electric field detecting means A signal processing unit that performs signal processing on the converted electric signal and outputs the converted electric signal; an amplitude measuring unit that measures an amplitude of the electric signal that has been subjected to the signal processing by the signal processing unit; And a connection control means for controlling connection between the connection means and the ground side connection means.
[0018]
The invention according to claim 2 is a transceiver capable of receiving information via the electric field transmission medium by receiving information based on an electric field induced in the electric field transmission medium, A single first electrode connectable to a receiving electrode contacted with an insulator interposed therebetween and a second electrode group including a plurality of electrodes functioning as a ground electrode with respect to the first electrode are provided. And an electro-optic means capable of changing the polarization of laser light incident between the first electrode group and the second electrode group by inducing and transmitting an electric field to the electric field transmission medium. And ground-side connecting means for connecting some or all of the electrodes of the second electrode group to the ground electrode; and detecting an electric field based on the polarization of the laser light changed by the electro-optical means. Receives the electric field Electric field detection means for converting an electric signal converted by the electric field detection means into a signal, signal processing means for performing signal processing on the electric signal converted by the electric field detection means, and amplitude measurement for measuring the amplitude of the electric signal processed by the signal processing means And a connection control means for controlling connection of the ground side connection means based on a measurement result by the amplitude measurement means.
[0019]
The invention according to claim 3 is a transceiver capable of receiving information via the electric field transmission medium by receiving information based on an electric field induced in the electric field transmission medium. A first electrode group including a plurality of electrodes that can be connected to a receiving electrode that is in contact with an insulator, and a single second electrode that functions as a ground electrode with respect to the first electrode group. An electro-optic device provided to change the polarization of laser light incident between the first electrode group and the second electrode by inducing and transmitting an electric field to the electric field transmission medium. Means, receiving-side connecting means for connecting some or all of the electrodes of the first electrode group and the receiving electrode, and detecting an electric field based on the polarization of the laser light changed by the electro-optical means And the electric field is Electric field detecting means for converting the electric signal converted by the electric field detecting means into a signal, a signal processing means for performing signal processing on the electric signal converted by the electric field detecting means, and an amplitude measuring means for measuring an amplitude of the electric signal processed by the signal processing means And a connection control means for controlling connection of the reception-side connection means based on a measurement result by the amplitude measurement means.
[0020]
BEST MODE FOR CARRYING OUT THE INVENTION
The transceiver according to the embodiment of the present invention induces an electric field based on information to be transmitted in an electric field transmission medium (such as the living body 100) while receiving information based on the electric field induced in the electric field transmission medium. Is a transceiver capable of transmitting and receiving information via an electric field transmission medium. Hereinafter, the transceiver 3 according to the first to fourth embodiments will be described. _1-4 Will be described.
[0021]
[First Embodiment]
Hereinafter, a first embodiment of the present invention will be described with reference to FIGS. FIG. 1 shows a transceiver 3 according to the first embodiment. ₁ FIG. FIG. 2 shows an electro-optical element 123. ₁ It is an expansion perspective view of. FIG. 3 shows an electro-optical element 123. ₁ FIG. 4 is a diagram showing a relationship between the sensitivity (state of an electric field) of the receiving side and the connection mode of the receiving side connection part 11 and the ground side connection part 13.
[0022]
As shown in FIG. ₁ Can be roughly divided into the same as the conventional transceiver 3 ′, the I / O (input / output) circuit 101, the transmission unit 103, the transmission electrode 105, the insulating films 107 and 109, the reception electrode 111, the electric field detection optical unit 10, the signal It comprises a processing circuit 20 and a waveform shaping circuit 117. The same functions and components as those in the related art are denoted by the same reference numerals, but will be described again here.
[0023]
First, the I / O circuit 101 includes the transceiver 3 ₁ Is a circuit for inputting and outputting data to and from an external processing device such as a computer. The transmission unit 103 has a function of inducing an electric field related to the data (information) output from the I / O circuit 101 in a living body based on the data (information). The transmission electrode 105 can be in contact with the living body 100 with the insulating film 107 interposed therebetween, is an electrode used for inducing an electric field in the living body 100 by the transmitting unit 103, and is used as a transmitting antenna. The insulating film 107 is used for the transceiver 3 ₁ This is for preventing the transmission electrode 105 from directly contacting the living body 100 when the is attached to the living body 100, and is an insulating film disposed between the transmission electrode 105 and the living body 100.
[0024]
Further, the receiving electrode 111 can be in contact with the living body 100 with the insulating film 109 interposed therebetween, and the wearable computer 1 and the transceiver 3 mounted on other parts of the living body 100 can be used. ₁ These electrodes are used to receive an electric field induced and transmitted to the living body 100 from the body, and are used as a receiving antenna. The insulating film 109 is an insulating film disposed between the receiving electrode 111 and the living body 100, like the insulating film 107.
[0025]
Further, the electric field detection optical unit 10 has a function of detecting an electric field received by the reception electrode 111 and converting the electric field into an electric signal as reception information, similarly to the conventional electric field detection optical unit 110. Since it includes components different from the conventional electric field detection optical unit 110, it will be described later in detail. Similarly to the conventional signal processing circuit 115, the signal processing circuit 20 performs signal processing such as amplification and noise removal of the electric signal transmitted from the electric field detection optical unit 10, and performs waveform processing on the waveform shaping circuit 117 (I / I / O). Although it has a function of outputting to the O-circuit 101), since it includes components different from those of the conventional signal processing circuit 115, this is also described in detail later. Further, the waveform shaping circuit 117 has a function of shaping the waveform of the electric signal transmitted from the signal processing circuit 20 and supplying the electric signal to the wearable computer 1 via the I / O circuit 101.
[0026]
Next, the components of the electric field detection optical unit 10 will be described in detail.
[0027]
The electric field detection optical unit 10 includes a current source 119, a laser diode 121, and an electro-optical element 123. ₁ , A first electrode group including the electrodes A and B, a second electrode group including the electrodes C and D, the receiving-side connection unit 11, the ground-side connection unit 13, the ground electrode 131, the deflection detection optical system 140, the first and the second. It has second photodiodes 143a and 143b, and first and second fixed resistors 145a and 145b.
[0028]
Among them, the current source 119 supplies a current for driving the laser diode 121. The laser diode 121 emits a laser beam when an electric current flows, and the electro-optical element 123 ₁ Is a semiconductor element to be incident on the substrate. Electro-optical element 123 ₁ Is an element that couples the electric field induced in the living body 100 via the receiving electrode 111 to change the polarization of the laser light as described above. The electric field is generated by an electro-optical method using the laser light and the electro-optical element. Can be detected. In FIG. 1, the collimator lens 133 and the first and second wave plates 135 and 137 shown in FIG. 9 are omitted due to the size of the paper, but they are actually present. The ground electrode 131 is connected to the electro-optical element 123. ₁ This is an electrode for facilitating extraction of the electric field coupled to the substrate.
[0029]
Further, the electro-optical element 123 in the present embodiment ₁ , An electrode A, an electrode B, an electrode C, and an electrode D are provided on four surfaces facing each other in the vertical and horizontal directions in FIG. As shown in FIG. 2, these four electrodes A, B, C, and D are provided with the electro-optical element 123 of the laser light from the laser diode 121. ₁ It is an electrode used to couple the electric field at right angles to the laser light by sandwiching the traveling directions in the inside from four directions. The electrodes C and D as the second electrode group function as ground electrodes with respect to the electrodes A and B as the first electrode group.
[0030]
In addition, the reception side connection unit 11 selectively switches the electrodes A and B as the first electrode group among the four electrodes A, B, C and D, or simultaneously connects the reception electrodes 111 (signal electrodes 129). This is a switch for connection, and the connection mode is controlled by a control unit 23 described later. That is, under the control of the control unit 23, a part (electrode A or electrode B) or all (electrode A and electrode B) of the first electrode group can be connected to the receiving electrode 111.
[0031]
Similarly, the ground-side connection unit 13 is used to selectively switch the electrodes C and D as the second electrode group among the four electrodes A, B, C and D, or to connect the electrodes C and D to the ground electrode 131 at the same time. The connection is controlled by a control unit 23 described later. That is, under the control of the control unit 23, a part (electrode C or electrode D) or all (electrode C and electrode D) of the second electrode group can be connected to the ground electrode 131.
[0032]
The deflection detection optical system 140 includes the deflection beam splitter 139 in FIG. 9 and first and second condenser lenses 141a and 141b. The deflecting beam splitter 139 separates the laser light incident from the second wavelength plate 137 into a P-wave component and an S-wave component, and ₁ Is an optical system that converts the amount of change in the polarization of the laser light whose polarization has been changed into the intensity change of the laser light. The first and second condenser lenses 141a and 141b are lenses for condensing the laser beams separated into the P-wave component and the S-wave component, respectively, and then respectively input the laser beams to the photodiodes 143a and 143b. is there. The electro-optical element 123 ₁ When the P-wave component and the S-wave component of the laser beam are separated from each other and emerge, the intensity changes of these two components are in opposite phases. In other words, there is a relationship that as one intensity increases, the other intensity decreases.
[0033]
Further, the first and second photodiodes 143a and 143b are light receiving elements that convert laser light (P-wave component and S-wave component) into current signals according to the intensity of the laser light. The first and second fixed resistors 145a and 145b are resistors for converting current signals converted by the first and second photodiodes 143a and 143b into voltage signals, and have fixed resistance values. I have.
[0034]
Next, components of the signal processing circuit 20 will be described in detail.
[0035]
The signal processing circuit 20 includes a differential amplifier 112, a noise removal filter 114, a fixed gain amplifier 116, an amplitude measuring unit 21, and a control unit 23.
[0036]
Among them, the differential amplifier 112 is an amplifier that differentially amplifies the voltage signals from the first and second fixed resistors 145a and 145b. The noise elimination filter 114 is a filter that limits the band of the signal output from the differential amplifier 112 and removes unnecessary noise. The fixed gain amplifier 116 is an amplifier that amplifies the signal output from the noise removal filter 114, and has a fixed gain. The amplitude measuring unit 21 is a device that measures the amplitude of the voltage signal output from the fixed gain amplifier 116.
[0037]
The control unit 23 is a computer that outputs a switching control signal or a simultaneous connection control signal to the reception-side connection unit 11 and the ground-side connection unit 13 based on the measurement value from the amplitude measurement unit 21. For example, if the voltage signal (electric signal) output from the fixed gain amplifier 116 is smaller than a predetermined value, the electro-optical element 123 ₁ The connection mode of the receiving-side connection unit 11 and the ground-side connection unit 13 is controlled so as to increase the sensitivity. As a result, the intensity of the laser light converted by the polarization detection optical system 140 increases, and thus the amplitudes of the current signals from the first and second photodiodes 143a and 143b and the voltage signals from the first and second fixed resistors. Will be higher. Conversely, if the voltage signal (electric signal) output from the fixed gain amplifier 116 is larger than a predetermined value, the electro-optical element 123 ₁ Is controlled so as to lower (dull) the sensitivity of the connection. As a result, the intensity of the laser light converted by the polarization detection optical system 140 decreases, and thus the amplitudes of the current signals from the first and second photodiodes 143a and 143b and the voltage signals from the first and second fixed resistors. Becomes lower. This is control for stabilizing the amplitude of the voltage signal (electric signal) output from the signal processing circuit 20 to the waveform shaping circuit 117 at a constant level.
[0038]
FIG. 3 shows the electro-optical element 123. ₁ And the connection between the receiving side connection unit 11 and the ground side connection unit 13. 3A shows that the sensitivity is the highest in FIG. 3A and the sensitivity decreases as going from FIG. 3A to FIG. 3E. This utilizes the property that the sensitivity of the electro-optical element changes depending on the direction in which the electric field is applied, and the sensitivity is determined by the plane orientation. For example, FIG. 3A shows a state of an electric field (lines of electric force) when the receiving-side connection unit 11 is switched to the electrode A and the ground-side connection unit 13 is switched to the electrode C. FIG. 3B shows the state of the electric field when the receiving-side connecting portion 11 is switched to the electrode A (partially connected) and the ground-side connecting portion 13 is connected simultaneously to the electrodes C and D (all connected). Is shown. In this case, the electric field is strongest on the angle side formed by the electrodes A and D (the lines of electric force are dense), and the electric field becomes weaker (the lines of electric force are weaker) toward the laser beam direction.
[0039]
Subsequently, the transceiver 3 according to the first embodiment ₁ The operation of will be described.
[0040]
First, transceiver 3 ₁ Receives the data supplied from the wearable computer 1 by the transmission unit 103 via the I / O circuit. As a result, the transmitting unit 103 induces an electric field from the transmitting electrode 105 through the insulating film 107 to the living body 100 serving as an electric field transmission medium, and the electric field is transmitted through the living body 100 to another transceiver attached to another site. Or to a PC or the like.
[0041]
In addition, transceiver 3 ₁ Receives an electric field induced and transmitted to the living body 100 from another transceiver or a PC attached to another part of the living body 100 at the receiving electrode 111 via the insulating film 109. Here, the reception-side connection unit 11 and the ground-side connection unit 13 have a connection mode determined in advance by connection control of the control unit 23. That is, one or both (part or all) of the electrodes A and B, which are the first electrode group, are connected to the reception electrode 111 by the reception-side connection unit 11, and the second connection is performed by the ground-side connection unit 13. One or both (part or all) of the electrode group C and the electrode D are connected to the ground electrode 131. Therefore, the received electric field is generated by the electro-optical element 123. ₁ In FIG. 3, the laser beams are combined in the state shown in FIG. 3 to change the polarization of the laser beams. Then, the changed laser light is separated into a P-wave component and an S-wave component by the polarization detection optical system 140, and the polarization change amount of the laser light whose polarization has been changed by the electro-optical element 123 is converted into the intensity change of the laser light. I do.
[0042]
Next, the P-wave component of the intensity change amount of the laser beam is converted into a current signal by the first photodiode 143a, and the S-wave component is converted into a current signal by the second photodiode 143b. Then, these current signals are converted into voltage signals by the first and second fixed resistors 145a and 145b, respectively, and transmitted to the differential amplifier 112.
[0043]
Next, the voltage signals from the first and second fixed resistors 145a and 145b are differentially amplified by the differential amplifier 112, and the noise removal filter 114 is used to limit the band of the voltage signal to remove unnecessary noise. The signal is amplified by the amplifier 116 and transmitted to the waveform shaping circuit 117. Then, the waveform shaping circuit 117 performs waveform shaping of the voltage signal, and supplies the voltage signal to the wearable computer 1 via the I / O circuit 101.
[0044]
On the other hand, the voltage signal amplified by the fixed gain amplifier 116 is also transmitted to the amplitude measuring unit 21. The amplitude measuring unit 21 measures the amplitude of the received voltage signal, and transmits it to the control unit 23. The control unit 23 controls the connection mode of the reception-side connection unit 11 and the ground-side connection unit 13 based on the measurement value from the amplitude measurement unit 21 to change the connection state so as to maintain the optimum communication state.
[0045]
As described above, according to the present embodiment, the amplitude measurement unit 21 and the control unit 23 perform feedback control of the connection mode of the reception-side connection unit 11 and the ground-side connection unit 13, and output from the signal processing circuit 20. This has the effect of stabilizing the strength of the electrical signal to a constant value and maintaining the optimum communication state at all times.
[0046]
[Second embodiment]
Hereinafter, a second embodiment of the present invention will be described with reference to FIG. FIG. 4 shows a transceiver 3 according to the second embodiment. ₂ Electro-optical element 123 ₂ It is an enlarged view of a part. This embodiment is different from the first embodiment in that the electro-optical element 123 is used. ₂ And the configuration of the receiving-side connection unit 31 and the ground-side connection unit 33 are different, and only the control method of the control unit 23 is different, and the other configurations are the same. Therefore, only this difference will be described.
[0047]
In FIG. 1, the electro-optical element 123 ₁ Has a rectangular (or square) cross section, whereas the electro-optical element 123 of the present embodiment has ₂ Has an octagonal cross section as shown in FIG. Further, a total of eight electrodes A ', B', C ', D', E ', F', G ', H' are provided on each side. The reception-side connection unit 31 is a switch for connecting the first electrode group and the reception electrode 111 by the control unit 23 in the same manner as the reception-side connection unit 11, but the four electrodes A ′ and B are used as the first electrode group. The difference is that connection control is performed for part or all of ', C', and D '. The ground-side connection unit 33 is a switch that connects the second electrode group to the ground electrode 131 by the control unit 23 in the same manner as the ground-side connection unit 13. However, the four electrodes E ′ are used as the second electrode group. , F ′, G ′, and H ′.
[0048]
With such a configuration, for example, a connection mode in which the electrodes A ′ and B ′ of the first electrode group are connected to the receiving electrode 111 and the electrode F ′ of the second electrode group is connected to the ground electrode 131 is adopted. Alternatively, a connection mode in which the electrode C ′ of the first electrode group is connected to the receiving electrode 111 and the electrode E ′ of the second electrode group is connected to the ground electrode 131 can be adopted.
[0049]
As described above, according to the present embodiment, the electro-optical element 123 provided with more electrodes than in the first embodiment. ₂ Is effective in that the sensitivity of the electro-optical element can be more finely controlled.
[0050]
In the present embodiment, eight electrodes are provided, and in the first embodiment, four electrodes are provided. However, the present invention is not limited to this, and more electrodes may be provided. May be provided. However, at least three electrodes are required to control the sensitivity.
[0051]
[Third embodiment]
Hereinafter, a third embodiment of the present invention will be described with reference to FIG. FIG. 5 shows a transceiver 3 according to the third embodiment. ₃ Electro-optical element 123 ₃ It is an enlarged view of a part. This embodiment is different from the first embodiment in that the electro-optical element 123 is used. ₃ And the configuration of the receiving-side connection unit 41 are different, and there is no connection unit corresponding to the ground-side connection unit 33. Further, only the control method of the control unit 23 is different. Only the differences will be described.
[0052]
In FIG. 1, the electro-optical element 123 ₁ The electrodes are provided one by one on the four sides of the electro-optical element 123 of the present embodiment. ₃ As shown in FIG. 5, seven electrodes a, b, c, d, e, f and g are divided and provided in parallel on one side of the receiving electrode 111, and one electrode is provided on one side of the ground electrode 131. α is provided. The reception-side connection unit 41 is a switch that connects the first electrode group and the reception electrode 111 by the control unit 23 in the same manner as the reception-side connection unit 11, but the first electrode group includes seven electrodes a and b. , C, d, e, f, and g in connection control.
[0053]
In addition, since the laser beam undergoes a change in deflection only where an electric field exists, when only the electrode a is connected, the polarization of the laser beam changes only in the portion of the electric field generated by the electrode a and the electrode α, and from there the electrode It only passes through between b, c, d, e, f, g and the electrode α. Therefore, when the amplitude of the voltage signal (electric signal) output from the signal processing circuit 20 to the waveform shaping circuit 117 is large, the electro-optical element 123 ₃ In order to lower (dull) the sensitivity of (i), control is performed such that only the electrode a among the electrodes a, b, c, d, e, f, and g is connected to the receiving electrode 111. Conversely, when the amplitude of the voltage signal is small, the electro-optical element 123 ₃ In order to increase the sensitivity of the receiving electrode 111, control is performed such that many of the electrodes a, b, c, d, e, f, and g, such as the electrodes a, b, and c, are connected to the receiving electrode 111.
[0054]
As described above, according to the present embodiment, the electro-optical element 123 ₃ In spite of providing the electrodes on the two sides, the use of a plurality of electrodes has an effect that the sensitivity of the electro-optical element can be more finely controlled.
[0055]
Although seven electrodes are provided in the present embodiment, the present invention is not limited to this. More electrodes may be provided, or fewer electrodes may be provided. However, in order to control the sensitivity, at least two electrodes (for example, electrodes a and b) are required.
[0056]
[Fourth embodiment]
Hereinafter, a fourth embodiment of the present invention will be described with reference to FIG. FIG. 6 shows a transceiver 3 according to the fourth embodiment. ₄ Electro-optical element 123 ₄ It is an enlarged view of a part. This embodiment is different from the first embodiment in that the electro-optical element 123 is used. ₄ And the configurations of the receiving side connection unit 51 and the ground side connection unit 53 are different, and only the control method of the control unit 23 is different. This embodiment is a modification of the third embodiment, and will be described in comparison with the third embodiment.
[0057]
Electro-optical element 123 of this embodiment ₄ As shown in FIG. 6, seven electrodes a1, b1, c1, d1, e1, f1, and g1 as a first electrode group are provided in parallel on one side of the receiving electrode 111 side. However, the difference is that seven electrodes a2, b2, c2, d2, e2, f2, and g2 as a second electrode group are provided on one side of the ground electrode 131. . The third embodiment is the same as the third embodiment in that a receiving-side connecting portion 51 for connecting a part or all of the first electrode group to the receiving electrode 111 is provided, but a part of the second electrode group is provided. Alternatively, the difference is that a ground-side connection portion 53 for connecting the whole to the ground electrode 131 is also provided.
[0058]
With such a configuration, for example, a connection mode such that the electrode a1 of the first electrode group is connected to the reception electrode 111 and the electrode g2 of the second electrode group is connected to the ground electrode 131, or the first electrode It is possible to adopt a connection mode in which all the electrodes of the group are connected to the reception electrode 111 and the electrodes a2 and f2 of the second electrode group are connected to the ground electrode 131.
[0059]
As described above, according to the present embodiment, the electro-optical element 123 ₃ By using a plurality of electrodes on both sides in spite of providing electrodes on the two sides, there is an effect that the sensitivity of the electro-optical element can be more finely controlled than in the third embodiment.
[0060]
In the present embodiment, seven electrodes are provided on each side. However, the present invention is not limited to this, and more or less electrodes may be provided. Further, the number of electrodes on each side may be different. For example, three electrodes a1, b2, and c3 are provided on the receiving electrode 111 side (the receiving side connection unit 51 side), and two electrodes a2 and b2 are provided on the ground electrode 131 side (the ground side connection unit 53 side). This is the case. However, in order to control the sensitivity, it is necessary to provide at least two electrodes on one side and at least one electrode on the other side. For example, there is a case where one electrode a1 is provided on the receiving electrode 111 side, and two electrodes a2 and b2 are provided on the ground electrode 131 side.
[0061]
In each of the above embodiments, the signal processing circuit 20 and the waveform shaping circuit 117 are described as separate circuits. However, the present invention is not limited to this, and the signal processing circuit 20 may include the waveform shaping circuit 117. Good. In this case, the output from the fixed gain amplifier 111 may not be used for feedback control, and the output from the waveform shaping circuit 117 may be used.
[0062]
In the above embodiment, the transmission electrode 105 and the reception electrode 111 are separate electrodes. However, the present invention is not limited to this. The transmission electrode 105 and the reception electrode 111 may be formed as one electrode and used as a transmission / reception electrode.
[0063]
【The invention's effect】
As described above, according to the present invention, by controlling the connection between the receiving-side connecting unit and the ground-side connecting unit based on the measurement result by the amplitude measuring unit, the intensity of the electric signal output from the signal processing unit is kept constant. The value can be stabilized, and an effect that the optimum communication state can always be maintained can be achieved.
[Brief description of the drawings]
FIG. 1 shows a transceiver 3 according to a first embodiment of the present invention. ₁ FIG.
FIG. 2 is an electro-optical element 123 according to the first embodiment of the invention. ₁ FIG.
FIG. 3 shows an electro-optical element 123. ₁ FIG. 6 is a diagram showing a relationship between the sensitivity (state of an electric field) of the light emitting device and connection modes of the receiving side connection portion 11 and the ground side connection portion 13.
FIG. 4 shows an electro-optical element 123 according to a second embodiment of the present invention. ₂ The enlarged view of FIG.
FIG. 5 shows an electro-optical element 123 according to a third embodiment of the present invention. ₃ The enlarged view of FIG.
FIG. 6 shows an electro-optical element 123 according to a fourth embodiment of the present invention. ₄ The enlarged view of FIG.
FIG. 7 is an image diagram in the case of performing communication between a plurality of wearable computers via a human body (living body 100).
FIG. 8 is an overall configuration diagram of a conventional transceiver 3 ′ used for performing data communication via a human body (living body 100).
FIG. 9 is a configuration diagram showing a detailed configuration of an electric field detection optical unit 110 in a conventional transceiver 3 ′.
[Explanation of symbols]
1 Wearable computer
3 ₁ Transceiver (according to first embodiment)
3 ₂ Transceiver (according to second embodiment)
3 ₃ Transceiver (according to a third embodiment)
3 ₄ Transceiver (according to a fourth embodiment)
3 '(conventional) transceiver
10. Electric field detection optical unit [an example of electric field detection means]
11 Receiving-side connection unit (according to first embodiment) [Example of receiving-side connection unit]
13 Ground side connection part (according to the first embodiment) [an example of ground side connection means]
20 signal processing circuit [an example of signal processing means]
21 Amplitude measurement unit [Example of amplitude measurement means]
23 control unit [an example of connection control means]
31 (Receiving-side connection unit)
33 Ground-side connection part (according to the second embodiment) [an example of ground-side connection means]
41 Receiving-side connection unit (according to the third embodiment) [Example of receiving-side connection unit]
51 Receiving-side connection unit (according to the fourth embodiment) [an example of receiving-side connection means]
53 Ground Side Connection Portion (According to Fourth Embodiment) [Example of Ground Side Connection Means]
123 ₁ Electro-optical element (according to first embodiment) [Example of electro-optical means]
123 ₂ Electro-optical element (an example of electro-optical means) (according to the second embodiment)
123 ₃ Electro-optical element (according to the third embodiment) [an example of electro-optical means]
123 ₄ Electro-optical element (an example of electro-optical means) (according to the fourth embodiment)

Claims (3)

A transceiver capable of receiving information via the electric field transmission medium by receiving information based on an electric field induced in the electric field transmission medium,
A first electrode group consisting of a plurality of electrodes that can be connected to a receiving electrode that is in contact with the electric field transmission medium via an insulator, and a plurality of electrodes that function as ground electrodes for the first electrode group. A second electrode group is provided, and an electric field is induced and transmitted to the electric field transmission medium to change the polarization of laser light incident between the first and second electrode groups. Electro-optical means capable of
Receiving-side connecting means for connecting a part or all of the first electrode group and the receiving electrode,
Ground-side connection means for connecting some or all of the electrodes of the second electrode group and the ground electrode;
An electric field detection unit that detects an electric field based on the polarization of the laser light changed by the electro-optic unit, and converts the electric field into an electric signal as received information;
Signal processing means for processing and outputting the electric signal converted by the electric field detection means,
Amplitude measuring means for measuring the amplitude of the electric signal signal processed by the signal processing means,
Connection control means for controlling connection between the reception-side connection means and the ground-side connection means, based on the measurement result by the amplitude measurement means,
A transceiver comprising: A transceiver capable of receiving information via the electric field transmission medium by receiving information based on an electric field induced in the electric field transmission medium,
A second electrode comprising a single first electrode connectable to a receiving electrode in contact with the electric field transmission medium via an insulator, and a plurality of electrodes functioning as ground electrodes with respect to the first electrode; An electrode group is provided, and an electric field is induced and transmitted to the electric field transmission medium, thereby changing the polarization of laser light incident between the first electrode and the second electrode group. Possible electro-optical means;
Ground-side connection means for connecting some or all of the electrodes of the second electrode group and the ground electrode;
An electric field detection unit that detects an electric field based on the polarization of the laser light changed by the electro-optic unit, and converts the electric field into an electric signal as received information;
Signal processing means for processing and outputting the electric signal converted by the electric field detection means,
Amplitude measuring means for measuring the amplitude of the electric signal signal processed by the signal processing means,
Connection control means for controlling connection of the ground-side connection means, based on a measurement result by the amplitude measurement means,
A transceiver comprising: A transceiver capable of receiving information via the electric field transmission medium by receiving information based on an electric field induced in the electric field transmission medium,
A first electrode group including a plurality of electrodes that can be connected to a reception electrode that is in contact with the electric field transmission medium via an insulator, and a single first electrode group that functions as a ground electrode with respect to the first electrode group. And the second electrode is provided, and an electric field is induced and transmitted to the electric field transmission medium to change the polarization of the laser light incident between the first electrode group and the second electrode. Electro-optical means capable of
Receiving-side connecting means for connecting a part or all of the first electrode group and the receiving electrode,
An electric field detection unit that detects an electric field based on the polarization of the laser light changed by the electro-optic unit, and converts the electric field into an electric signal as received information;
Signal processing means for processing and outputting the electric signal converted by the electric field detection means,
Amplitude measuring means for measuring the amplitude of the electric signal signal processed by the signal processing means,
Connection control means for controlling connection of the reception-side connection means, based on the measurement result by the amplitude measurement means,
A transceiver comprising:

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