JP2005027327A - Power communication method and its apparatus - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a method and apparatus for inputting complicated power displacement information from a manipulator for transmission to the other power communication apparatus. <P>SOLUTION: The power communication apparatus includes a manipulator 1 of which the position or shape is changed by external power, a power displacement detecting means 3 for detecting power or displacement that the manipulator 1 receives, or the both, a communication means 7 for transmitting the power displacement information for operating the manipulator 8 to a communication means 14, a conversion table 4 for storing a reference value of the power displacement information for operating the manipulator 1 or video or audio storage data pointer or the both, motive mechanism information generating means 5 for generating the power displacement information for operating the manipulator 1 from the power displacement information and the reference value inputted from the communication means 14, and an operating mechanism 2 for converting the power displacement information for operating the manipulator 1 into an action and transmitting it to the manipulator 1. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

  The present invention relates to force communication. More particularly, the present invention relates to communication of force by tactile sensation in a portable terminal including amusement such as a game, a communication device for a handicapped person, a robot operation device, a mobile phone, a portable information terminal and the like.

Communication of mobile terminals is centered on voice, and images are also targeted for next-generation mobile terminals. However, vibration and force communication cannot be performed with a mobile terminal. In patent document 1, the example in the aircraft control device is published as a control method for transmitting a simple force. A simple force can be transmitted, but a twisting and rubbing force cannot be transmitted, and the transmission partner is mechanically fixed. Furthermore, it was impossible to output sound and images linked to the transmitted vibrations and forces.
Japanese National Patent Publication No. 9-501371

  It is an object of the present invention to provide a method and an apparatus for inputting complicated force displacement information such as a pressing force, a gripping pressure, a twisting pressure, and a rubbing pressure from an operator and transmitting them to another force communication device. In addition, the present invention inputs force displacement information from an operator, combines it with information from other force communication devices, and controls it to transmit various forces to a plurality of force communication devices. An object of the present invention is to provide a method and apparatus for communicating force displacement by combining and reflecting it on an operator. Furthermore, an object of the present invention is to provide an apparatus and a method for outputting an audio image corresponding to a force displacement.

  In order to achieve the above object, the present invention provides a first operating element whose position and shape are changed by an external force, and a force displacement detecting means for detecting the force and / or displacement received by the first operating element. A force displacement information generating means for encoding force displacement information relating to the force and / or displacement from the force displacement detecting means and outputting the information to the communication means; and for moving the second operator input from the force displacement information generating means. A first communication means for transmitting the force displacement information to the second communication means, a conversion table for storing a reference value of force displacement information for moving the first operation element, a stored data pointer for video and audio, or both First power mechanism information generating means for generating force displacement information for moving the first operating element from the force displacement information input from the second communication means via the first communication means and the reference value, and first power Providing a force communication device including an operating mechanism for transmitting the first operator converts a force displacement information for moving the first operation input from the configuration information generating means to the operation.

  As a preferred embodiment, the present invention provides a force communication device further including an image / sound generation unit that generates image / sound information corresponding to the force displacement information based on data stored in a conversion table. Further, as a more preferable aspect, the present invention is such that the force communication device is connected to a plurality of other force communication devices via communication means, and either one or both of the force communication device and the plurality of other force communication devices. Provided is a force communication device characterized in that a plurality of force displacement information is received and combined, and the result is transmitted to the first operator. As a preferred aspect, in the present invention, the force displacement detecting means is applied to the first operating element, and the pressing force detecting means for detecting the pressing force applied to the first operating element. Gripping pressure detecting means for detecting grip pressure, twisting pressure detecting means for detecting torsion pressure applied to the first operating element, and rubbing for detecting rubbing pressure applied to the first operating element The force communication device is selected from a group including pressure detection means.

  The external force refers to a force generated by a user such as a human or a force that an operation mechanism such as a machine acts on the force communication device according to the present invention from the outside. The operator is a unit that applies a force to be communicated when the user operates the force communication device according to the present invention. For example, a bellows balloon or the like may be used as long as it can transmit an applied force such as pushing, grasping, twisting, and rubbing to a transmission device such as a gear. The change of the position and shape means that the position and shape of the operation element with respect to the force communication device are changed by the force of pushing, grasping, twisting, and rubbing. The first is a number given for convenience in order to distinguish it from other force communication devices. It was attached to each part of the force communication device mainly composed of the first, and the second was attached to the other parts of the force communication device. The first and second force communication devices are not distinguished and are exactly the same. Encoding force displacement information means that the force displacement information is converted from analog data to digital data so that the force displacement information can be transmitted from the communication means to the communication means of another force communication device via the telecommunication line. Is to convert. The video / audio storage data pointer is an indicator of various video / audio data. Here, video / audio data such as games and movies is stored, and the video / audio data is output by the AV main unit or the like in relation to the force displacement information. The conversion table is for converting force information, displacement information, and an image / audio pointer transmitted from another force communication device into the format of the force communication device.

  As another aspect according to the present invention, a first operating element, a force displacement detecting means connected to the first operating element, a force displacement information generating means connected to the force displacement detecting means, and the force displacement information generating means In the force communication device including the first communication means connected to the first communication means, a step in which the position or shape of the first operating element is changed by an external force, and the force displacement detecting means is a force received by the first operating element or A step of detecting displacement or both, a step of force displacement information generation means encoding force displacement information from the force displacement detection means and outputting to the communication means, and a first communication means from the force displacement information generation means Transmitting the input force displacement information to the second communication means.

  As an aspect according to the present invention, in a force communication device including a conversion table, a first power mechanism information generating unit connected to the conversion table, and an operating mechanism connected to the first power mechanism information generating unit, the conversion table includes: , A step of storing a reference value of force displacement information for moving the first manipulator and / or a stored data pointer of video and audio, or both, and a first power mechanism information generating means from the second communication means to the first communication means. Generating the force displacement information for moving the first operating element from the force displacement information input through the reference value, and the operating mechanism using the first operating element input from the first power mechanism information generating means. Converting force displacement information for movement into motion and transmitting it to a first operator. As a further preferred aspect, there is provided a force communication method further comprising a step of generating image / audio information corresponding to the force displacement information based on data of a stored data pointer of a conversion table. As a further preferred aspect, the force communication device is connected to another force communication device via communication means, and a plurality of force displacement information from either one or both of the force communication device and other force communication devices. Are received, combined, and transmitted to the first operator. As a further preferred aspect, the force displacement detection means detects a pressing force detection means for detecting a pressing force applied to the first operating element, and detects a grip pressure applied to the first operating element. Gripping pressure detecting means, torsion pressure detecting means for detecting torsion pressure applied to the first operating element, and rubbing pressure detecting means for detecting rubbing pressure applied to the first operating element A force communication method is provided that is selected from a group including.

  According to the present invention, set values corresponding to force data and displacement data from a given force communication device and other force communication devices are read from the conversion table, and the operator is deformed and moved via the operation mechanism. Will be able to. In other words, force and displacement distributions can be given in advance to the conversion table, and surface roughness can be realized in the case of a rubbing operation. Furthermore, since the conversion table has pointers for images and sounds corresponding to force displacement and can output image sounds corresponding to deformation and movement of the controls, the controls of multiple force communication devices cooperate with each other. A common screen can be operated by force displacement, and a realistic game or simulation becomes possible.

Hereinafter, embodiments of the force communication device according to the present invention will be described in more detail.
[Basic configuration of force communication device]
FIG. 1 is a basic configuration diagram of an embodiment of a force communication device according to the present invention. In FIG. 1, two force communication devices are shown, and the mutual relationship is schematically shown. Force communication is transmitting force displacement from the operation element 1 to the operation element 2 in another force communication device. Conversely, the force displacement is transmitted from the operating element 2 in the other force communication device to the operating element 1. This force may be converted by the conversion table while being transmitted by the communication means. The user applies a force such as pushing, grasping, twisting or rubbing against the operation element 1 with a hand or the like. Next, the force displacement detecting means 3 detects the force applied to the operation element 1 and the displacement of the operation element 1 due to the force. The force displacement information generation means 5 encodes the force displacement data by digitizing it and outputs it to the communication means 7 so that it can be transmitted to another force communication device via the telecommunication line. The communication unit 7 transmits the encoded force displacement information to the communication unit 14 in another force communication device.

  Next, using the conversion table 11 that stores the reference value of the force displacement information for moving the operation element 8 and the stored data pointer of the video and audio, the power mechanism information generating means 12 receives the force displacement information input from the communication means 14. And force displacement information for moving the operating element 8 from the reference value. The operating mechanism 9 converts force displacement information for moving the operating element 8 from the power mechanism information generating means 12 into an operation and transmits it to the operating element.

[Force displacement information generation means (transmission processing)]
FIG. 2 is one embodiment of the force displacement information generating method by the force displacement information generating means 5 at the time of transmission, relating to the force communication device according to the present invention. The force displacement information generating means 5 receives and reads the force displacement information from the analog / digital port (A / D port) in the force displacement detecting means 3 (step 21). Next, data is accumulated and encoded (step 22). The encoded force displacement information data is transmitted to the communication unit 14 of another force communication device using the communication unit 7.

[Power mechanism information generation means (reception processing)]
FIG. 3 shows an embodiment of the power mechanism information generation method by the power mechanism information generation means 12 at the time of reception related to the force communication device according to the present invention. The communication unit 14 receives the force displacement information data from the communication unit 7, decodes it, and stores it (step 31). The power mechanism information generation means 12 refers to the conversion table 11 and calculates displacement control information (step 32). The calculation result is output to the D / A port as force displacement information (step 33).

[Communication data format]
FIG. 4 shows an embodiment of a communication data format performed between the communication means 7 and 14 of a plurality of force communication devices according to the present invention. This communication data format includes device type 40, force data type 41, force data 42, and displacement data 43. Here, the device type 40 is a symbol given to the type of force communication device. This symbol may be an arithmetic number or a product number. The force data type 41 is a symbol such as an arithmetic numeral or alphabet for distinguishing forces such as pushing, gripping, twisting, and rubbing applied to the operators 1 and 8. The force data 42 is an amount indicating the magnitude of the force applied to the operation elements 1 and 8. The magnitude of this force may be either a scalar quantity or a vector quantity. The displacement data 43 indicates a vector amount in which the operating elements 1 and 8 are displaced by the force applied to the operating elements 1 and 8. Note that the data included in the communication data format is not limited to these four types of data 40 to 41, and any data may be used as long as it indicates the type, direction, and magnitude of the force applied to the operation element.

[Calculation of resultant force and / or position]
FIG. 5 shows an embodiment of the resultant position calculation process according to the present invention. The resultant force position calculation process includes a resultant force control calculation 50 and a displacement control calculation 51. First, the resultant force control calculation 50 will be described. As the resultant force control calculation 50, there are three types of calculation methods: simple calculation, processing calculation, and function calculation. In the simple calculation C = D + R (C: force information, D: force information of the force communication device of the own terminal, R: force information of the force communication device of the other terminal), as is apparent from the equation, when calculating the resultant force It simply calculates the sum of forces. Further, in the processing calculation C = αD + βR + γC ′ (C ′: previous force information), α, β, and γ coefficients are used to weight each force information and calculate the sum of forces. . In the function calculation C = f (D, R) (f (variable): a certain function), force information from a plurality of force communication devices is synthesized using an arbitrary function. As the displacement control calculation 51, there are three possible calculation methods: simple calculation, processing calculation, and function calculation. In the simple calculation ΔX = ΔD + ΔR (ΔX: Displacement information, D: Displacement information of the force communication device of the own terminal, R: Displacement information of the force communication device of the other terminal), as is apparent from the equation, the displacement Is simply calculated as the sum of the displacements of the force communication device. Further, in the processing calculation ΔX = αΔD + βΔR + γΔX ′ (ΔX ′: previous force information), the coefficients of α, β, and γ are used to weight each force information, The sum of forces is calculated. In function calculation ΔX = f (ΔD, ΔR, ΔX) (f (variable): a function), force information from a plurality of force communication devices is synthesized using an arbitrary function.

[Conversion table configuration]
FIG. 6 shows an embodiment of the conversion table according to the present invention. The force information, displacement information, and image / audio information received from the force communication device of the other terminal are converted into the force information, displacement information, and image / audio information as described above. It is converted by performing displacement information, image / sound information pointer, etc. For example, it may be converted into a force type by converting to a pressing force and a twisting pressure, or when another operating element is turned to the right, the operating element is bent to the left and the displacement information is It may be converted. The image data may be converted in the same manner. The magnitude of the force may be set when the output is doubled or tripled from the input information. Various information of the force communication device of the own terminal is combined with various information of the force communication device of the other terminal and the resultant position calculation processing (force information, displacement information, video / audio information pointer), etc. The operator of the force communication device may be moved.

[Example 1: Force communication device]
FIG. 7 is a view showing an embodiment of the force communication device according to the present invention. In FIG. 7, two force communication devices are shown, showing the mutual relationship. The force communication in this embodiment is to transmit a force displacement from the first operator 70 to the second operator 83 in another force communication device. Conversely, the force displacement is transmitted from the second operation element 83 in the other force communication device to the first operation element 70. This force displacement may be converted by a conversion table while being transmitted by communication means (not shown). The user applies force such as pushing, grasping, twisting, rubbing, etc. against the first operating element 70 with a hand or the like. As the first force displacement detecting means 71, there are a first strain sensor 74 and a first sensor circuit 77. The first strain sensor 74 senses the force applied to the first manipulator 70 and the displacement of the manipulator 70 due to the force, transmits the sensed force displacement to the first sensor circuit 77, and the first sensor circuit 77 detects it. To do. The first sensor circuit 77 that also serves as the force displacement information generation means encodes the force displacement data by digitizing it and transmits it to another force communication device via the telecommunication line. 81 is output as the first force transmission signal 79. The first communication means 81 transmits the encoded force displacement information to the second communication means 82 in another force communication device.

  Next, by using a conversion table that stores a reference value of force displacement information for moving the second manipulator 83 and a stored data pointer of video and audio, the second actuator control means 86 that is a power mechanism information generation means performs the first operation. The second operator 83 is moved from the force displacement information sent from the communication means 81, the second self-force signal 92 which is the force displacement information from the strain sensor 87 of the second operator 83, and the reference value. Force displacement information is generated. The second operating element displacement imparting means 85, which is an operating mechanism, converts the force displacement information for moving the second operating element 83 from the second actuator control means 86, which is a power mechanism information generating means, into an operation and converts it to an operation. The second operating element 83 is actually moved.

  On the other hand, the user applies a force such as pushing, grasping, twisting, rubbing, etc. to the second operation element 83 with his / her hand. As the second force displacement detection means 84, there are a second strain sensor 87 and a second sensor circuit 90. The second strain sensor 87 senses the force applied to the second manipulator 83 and the displacement of the second manipulator 83 due to the force, and transmits the sensed force displacement to the second sensor circuit 90 to transmit the second sensor circuit 90. Will detect. In the second sensor circuit 90 also serving as the force displacement information generating means, the force displacement data can be encoded, for example, digitized and transmitted to another force communication device via an electric communication line. 82 is output as a second force transmission signal 93. The second communication means 82 transmits this encoded force displacement information to the first communication means 81 in another force communication device.

  Next, by using a conversion table that stores a reference value of force displacement information for moving the first manipulator 70 and a stored data pointer for video and audio, the first actuator control means 73 as power mechanism information generation means The first operator 70 is moved from the force displacement information sent from the communication means 82, the first self-force signal 80 which is the force displacement information from the strain sensor 74 of the first operator 70, and the reference value. Force displacement information is generated. The first operating element displacement imparting means 72, which is an operating mechanism, converts force displacement information for moving the first operating element 70 from the first actuator control means 73, which is a power mechanism information generating means, into an operation, and converts the first operating element 70 The first operating element 70 is actually moved.

[Example 2: Force communication device (pressing sliding type)]
FIG. 8 shows an embodiment of a pressing and sliding type operation element according to the present invention. The operation mechanism of this pressing and sliding type includes a worm gear 101 and an actuator (motor) 100, and the force displacement detection means includes a pressure sensor 102 and a sensor circuit 103. As shown in FIG. 8, when pressure is applied from an operator (not shown), the pressure sensor 102 is sensed by displacement, and the force displacement information is sent to the sensor circuit 103 and detected. Conversely, the actuator (motor) 100 moves according to the transmitted power mechanism information, the force displacement is transmitted to the worm gear 101, and the force displacement is transmitted to an operator (not shown).

[Example 3: Force communication device (twist type)]
FIG. 9 shows an embodiment of a twist type operation element according to the present invention. This torsion type operation mechanism includes a worm gear 111 and an actuator (motor) 110, and the force displacement detection means includes a strain sensor 112 and a sensor circuit 113. As shown in FIG. 9, when a strain is applied from an operator (not shown), the strain sensor 112 senses the displacement, and the force displacement information is sent to the sensor circuit 113 and detected. On the other hand, the actuator (motor) 110 moves according to the transmitted power mechanism information, the force displacement is transmitted to the worm gear 111, and the force displacement is transmitted to an operator (not shown).

[Example 4: Force communication device (grip type)]
FIG. 10 shows an embodiment of a grip-type operation element according to the present invention. This gripping type operation mechanism includes a worm gear 101 and an actuator (motor) 100, and the force displacement detection means includes a pressure sensor 123 and a sensor circuit 103. As shown in FIG. 10, when pressure is applied to the operator 124 of the bellows balloon, for example, pressure is transmitted to the air cylinder 123, the pressure sensor 122 senses the displacement, and the force displacement information is detected by the sensor circuit. 125 to be detected. Conversely, the actuator (motor) 120 moves according to the transmitted power mechanism information, the force displacement is transmitted to the worm gear 121, and the force displacement is transmitted to the operator 124.

[Example 5: Force communication device (bending type)]
FIG. 11 shows an embodiment of a bending type operation element according to the present invention. As shown in FIG. 11, when the user bends the bellows operator 131 including the strain gauge inside the bending mechanism 132, the sensor 122 senses the displacement, and the force displacement information is sent to the sensor circuit to be detected. The Conversely, the actuator (motor) moves according to the transmitted power mechanism information, and the force displacement is transmitted to the worm gear or the like, and the force displacement is transmitted to the operation element 131.

[Example 6: Force communication device (pressing sliding type)]
FIG. 12 shows an embodiment of a pressing and sliding type operation element according to the present invention. As shown in FIG. 12, when the user presses and slides on the pressing / sliding type operation element 141, the sensor senses displacement, and the force displacement information is sent to the sensor circuit and detected. Conversely, the actuator (motor) moves according to the transmitted power mechanism information, and the force displacement is transmitted to the worm gear or the like, and the force displacement is transmitted to the operation element 141.

[Example 7: Force communication device (twist type)]
FIG. 13 shows an embodiment of a twist type operation element according to the present invention. As shown in FIG. 13, when the user twists the torsion type operation element 151, the sensor senses displacement, and the force displacement information is sent to the sensor circuit and detected. Conversely, the actuator (motor) moves according to the transmitted power mechanism information, the force displacement is transmitted to a worm gear or the like, and the force displacement is transmitted to the operation element 151.

[Example 8: Force communication device (grip type)]
FIG. 14 shows an embodiment of a grip-type operation element according to the present invention. As shown in FIG. 14, when the user twists the grip-type operation element 161, the sensor senses displacement, and the force displacement information is sent to the sensor circuit and detected. Conversely, the actuator (motor) moves according to the transmitted power mechanism information, the force displacement is transmitted to a worm gear or the like, and the force displacement is transmitted to the operation element 161.

[Example 9: Force communication device (pressing type)]
FIG. 15 shows an embodiment of a pressing type operating mechanism according to the present invention. FIG. 16 shows an embodiment of a pressing type operation element according to the present invention. As shown in FIG. 16, when the user presses the pressing type operation element 181, the movement is transmitted to the worm gears 171 and 172, the sensor senses the displacement, and the force displacement information is sent to the sensor circuit and detected. Conversely, the actuator (motor) moves according to the transmitted power mechanism information, and the force displacement is transmitted to the worm gear or the like, and the force displacement is transmitted to the operator 170.
Although the embodiments of the present invention have been described above, the present invention is not limited to the above-described embodiments, and various modifications, changes and combinations can be made based on the technical idea of the present invention. is there. For example,

1 is a basic configuration diagram of a force communication device according to an embodiment of the present invention. It is a flowchart of the force displacement information generation method at the time of transmission regarding the force communication apparatus of one Embodiment which concerns on this invention. It is a flowchart of the motive power mechanism information generation method at the time of reception regarding the force communication apparatus of one Embodiment which concerns on this invention. It is a schematic diagram of the communication data format performed between the communication means of the several force communication apparatus of one Embodiment which concerns on this invention. It is a schematic diagram of the resultant force position calculation process of one embodiment according to the present invention. It is a schematic diagram of the conversion table which is one Embodiment which concerns on this invention. It is the figure which showed the force communication apparatus of one Example which concerns on this invention. It is the figure which showed the press sliding type operation element of one Example which concerns on this invention. It is the figure which showed the twist type operation element of one Example which concerns on this invention. It is the figure which showed the grip type operation element of one Example which concerns on this invention. It is the figure which showed the bending type operation element of one Example which concerns on this invention. It is the figure which showed the press sliding type operation element of one Example which concerns on this invention. It is the figure which showed the twist type operation element of one Example which concerns on this invention. It is the figure which showed the grip type operation element of one Example which concerns on this invention. It is the figure which showed the press-type operation | movement mechanism of one Example which concerns on this invention. It is the figure which showed the press type operation element of one Example which concerns on this invention.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Operating element 2 Operating mechanism 3 Force displacement detection means 4 Conversion table 5 Force displacement information generation means (CPU)
6 AV device 7 Communication means 8 Operator 9 Operating mechanism 10 Force displacement detection means 11 Conversion table 12 Force displacement information generation means (CPU)
13 AV device 14 Communication means 70 Manipulator 71 Force displacement detection means 72 Manipulator displacement applying means (motion mechanism)
73 Actuator control means 74 Strain sensor 75 Worm gear 76 Actuator 77 Sensor circuit 78 Displacement control signal 79 Force transmission signal 80 Self force signal 81 Communication means 82 Communication means 83 Manipulator 84 Force displacement detection means 85 Manipulator displacement imparting means (motion mechanism)
86 Actuator control means 87 Strain sensor 88 Worm gear 89 Actuator 90 Sensor circuit 91 Displacement control signal 92 Self-force signal 93 Force transmission signal 100 Actuator (motor)
101 Worm gear 102 Pressure sensor 103 Sensor circuit 110 Actuator (motor)
111 Worm gear 112 Strain sensor 113 Sensor circuit 120 Actuator (motor)
121 Worm Gear 122 Pressure Sensor 123 Air Cylinder 124 Bellows Balloon 125 Sensor Circuit 130 Force-Communication Device for Bending Type Controller 131 Bellows with Strain Gauge Inside 132 Bending Mechanism 140 Force-Communication Device for Pressure-Sliding Type Operator 141 Pressing Slide Dynamic type operation element 150 Twist type operation element force communication device 151 Torsion type operation element 160 Grip type operation element force communication apparatus 161 Grip type operation element 170 Press type operation element 171 Worm gear 172 Worm gear 180 Press type Power communication device 181 Press type operation element

Claims (9)

  A first operating element whose position and shape are changed by an external force, a force displacement detecting means for detecting the force and / or displacement received by the first operating element, and a force or displacement from the force displacement detecting means Force displacement information generating means for encoding force displacement information for both of them and outputting it to the communication means, and force displacement information for moving the second operating element input from the force displacement information generating means are transmitted to the second communication means. A first communication means, a conversion table for storing a reference value of force displacement information for moving the first operator and / or a stored data pointer for video and audio, or both; and a second communication means through the first communication means. The first power mechanism information generating means for generating force displacement information for moving the first operator from the force displacement information and the reference value, and the first operation input from the first power mechanism information generating means. Force communications apparatus that includes an operation mechanism for transmitting the first operator converts a force displacement information for moving the child in operation.   The force communication device according to claim 1, further comprising an image sound generation unit that generates image sound information corresponding to the force displacement information based on data stored in a data pointer stored in a conversion table.   The force communication device is connected to a plurality of other force communication devices via communication means, and receives and synthesizes a plurality of force displacement information from either one or both of the force communication device and the other force communication devices. The force communication device according to claim 1, wherein the result is transmitted to the first operator.   The force displacement detection means detects a pressing force applied to the first operating element, and a gripping pressure detecting means detects a gripping pressure applied to the first operating element. And a torsion pressure detecting means for detecting a torsion pressure applied to the first operating element, and a rubbing pressure detecting means for detecting a rubbing pressure applied to the first operating element. The force communication device according to claim 1, wherein the force communication device is a power communication device.   A first manipulator, force displacement detecting means connected to the first manipulator, force displacement information generating means connected to the force displacement detecting means, and first communication means connected to the force displacement information generating means. A force communication device including: a step in which the position and shape of the first operator are changed by an external force; and a step in which the force displacement detector detects the force and / or displacement received by the first operator. A step in which the force displacement information generation means encodes the force displacement information from the force displacement detection means and outputs it to the communication means; and a first communication means outputs the force displacement information input from the force displacement information generation means to the second Transmitting to the communication means.   In a force communication device including a conversion table, a first power mechanism information generating unit connected to the conversion table, and an operation mechanism connected to the first power mechanism information generating unit, the conversion table moves the first operator. For storing a reference value of force displacement information and / or a stored data pointer for video and audio, or both, and a force displacement input by the first power mechanism information generating means from the second communication means via the first communication means A step of generating force displacement information for moving the first operating element from the information and the reference value; and a force displacement information for moving the first operating element input from the first power mechanism information generating means by the operating mechanism. A force communication method comprising: converting the motion into a motion and transmitting the motion to the first operator.   The force communication method according to claim 6, further comprising a step of generating image / audio information corresponding to the force displacement information based on data stored in a data pointer of the conversion table.   The force communication device is connected to a plurality of other force communication devices via communication means, and receives and synthesizes a plurality of force displacement information from either one or both of the force communication device and the other force communication devices. The force communication method according to claim 6, further comprising a step of transmitting the result to the first operator.   The force displacement detection means detects a pressing force applied to the first operating element, and a gripping pressure detecting means detects a gripping pressure applied to the first operating element. And a torsion pressure detecting means for detecting a torsion pressure applied to the first operating element, and a rubbing pressure detecting means for detecting a rubbing pressure applied to the first operating element. The force communication method according to claim 5.

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