• 专利附录
  • 专利说明
  • 权利要求
  • 类似技术
  • 同族专利
  • 引用文献
  • 法律状态
  • 优先权
    • 专利摘要:
    PURPOSE: A six degree of freedom haptic joystick system by using a gimbal apparatus is provided to operate multiple degrees of freedom with a simple structure and to improve back drivability by fixing an actuator to a base. CONSTITUTION: A six degree of freedom haptic joystick system by using a gimbal apparatus comprises a knob(110a); two linking portions(120); two gimbal apparatus portions(130); three driving measuring portions(140) and a base(150). The knob is operated by contacting user's hand. The knob is connected to two linking portions with a spherical articulation on one end and a universal joint on the other end. Linking portions comprises links and rotating articulations. Upper ends of linking portions are connected to the end of the knob. Lower ends of linking portions are connected to gimbal apparatus. Each gimbal apparatus comprises four links and five rotating articulations. Gimbal apparatus portions make spatial 5 bar linkage including the base. Therein, a movement of two degree of freedom is possible. One active shaft of each gimbal apparatus portion corresponds and the other active shaft is arranged in parallel. Therein, three degree of freedom is made with two gimbal apparatus. Each driving measuring portion comprises a sensor and an actuator. The driving measuring portion is stuck to each active articulation of the gimbal apparatus portion. Therein, the driving measuring portion measures an angular displacement of the active articulation. The base supports gimbal apparatus portions and driving measuring portions.
    公开号:KR20030043023A
    申请号:KR1020010073980
    申请日:2001-11-26
    公开日:2003-06-02
    发明作者:송재복;류동석
    申请人:송재복;
    IPC主号:
    专利说明:

    6 degree of freedom haptic joystick system using gimbal mechanism {6 DEGREE-OF-FREEDOM HAPTIC JOYSTICK SYSTEM USING GIMBAL MECHANISM}
    [20] The present invention relates to a new six degree of freedom haptic joystick system designed to be simple in construction, easy to interpret, and to improve the efficiency and back drivability of force reflection while implementing multiple degrees of freedom.
    [21] Generally, a haptic device is an input device that transmits a user's body movement to a computer, unlike a general computer interface such as a keyboard, a mouse, a joystick, a monitor, or a printer acting only in one direction of input or output. A bidirectional computer interface that acts as an output device that delivers the appropriate force or sensation to the user's body in response to a command of a computer and a command of the computer. In addition to facilitating interaction with the virtual environment being implemented, it is emerging as a new paradigm that replaces existing computer interfaces by enabling intuitive input and output of computer users.
    [22] The haptic joystick is a haptic device applied to the hand among various body parts. The haptic joystick can input the position and posture information of the user's hand to the computer in three-dimensional space, and output the appropriate force and torque to the user's hand according to the computer's command. It is one of the most popular devices among various types of haptic devices due to its wide application range.
    [23] In general, the haptic joystick has a structure using an end-effector of a universal robot as a handle, and has many commonalities with a universal robot in this respect. The common point is that the sensor is attached to each joint of the link and the kinematics is analyzed to obtain the position and posture of the end effector (hereinafter referred to as the knob). The actuator is mounted on each joint of the link and driven. The force and torque of the desired direction and magnitude is presented to the handle.
    [24] However, haptic joysticks differ from conventional robots in designing reverse drive. The above difference is that, in general robots, the end effector is designed to increase the inertia of the device so that it does not move easily due to the disturbance of the surrounding disturbance, and the reverse driving ability is low, whereas the haptic joystick is used when the force is not applied to the user's hand. It is designed to minimize inertia and improve reverse driving so that the user can move the handle freely.
    [25] In general, the haptic joystick causes the actuator to move together with the mechanism of the device according to the movement of the device, and the movement of the actuator increases the inertia of the device, resulting in a disadvantage of lowering the backward driveability of the joystick. Has a problem of increasing fatigue by making it difficult to move the handle freely. In addition, in outputting a force through the actuator, the actuator has to bear the power for moving itself, which causes a problem of lowering the efficiency of driving and lowering the overall performance. In the haptic joystick, the above-mentioned problem becomes more serious because the ratio of the weight occupied by the actuator and the greater the degree of freedom to implement requires a plurality of actuators.
    [26] With reference to the embodiment of the similarly proposed similar haptic device as shown in Figs. 1, 2 and 3, the above-described problem and the existing technology for solving the problem will be described in more detail.
    [27] 1 is a structural diagram of a conventionally developed serial haptic joystick. As described above, the haptic joystick of FIG. 1 has the same structure as a general serial robot. The user's handle 11 is connected in series with several links, and a sensor and an actuator 12 are mounted at each joint. Therefore, when the user moves the handle, the displacement of each joint is measured by the sensor, the position and posture of the handle can be calculated through the kinematic analysis, and transmitted to the computer. In order to transmit the appropriate force and torque to the user's hand according to the command of the computer, the torque of each joint needed to generate the force and torque to reflect is calculated by dynamic analysis, and the actuator of each joint is calculated Control to generate torque.
    [28] However, in the case of the serial haptic joystick illustrated in FIG. 1, when the user moves the handle 11, the actuator 12 for driving the device moves with the link, so that the mass of the actuator interferes with the user's free movement. It has a problem of increasing fatigue and lowering the efficiency of force reflection.
    [29] In the haptic joystick, in order to solve this problem, there is a need for a structure capable of fixing all actuators to a base and a method for constructing a mechanism capable of improving reverse driving. As an example to compensate for this problem, MIT has developed a phantom, a haptic device using a four-section link, and a schematic diagram of the device is shown in FIG. 2. The device is the first commercially available in the world due to its simple structure, easy analysis and control. As shown in the structural diagram of FIG. 2, the four-section link 22 having two degrees of freedom is connected in series to the rotational joint 23 of one degree of freedom, thereby enabling three degrees of freedom of the handle 21. The device is equipped with actuators 24a and 24b for moving the four-way link close to the base 25, and the actuators 24b are arranged so that the weight of the four-way link 22 is in balance with the four-way link 22. To reduce inertia and improve reverse drive.
    [30] However, in the apparatus, some actuators 24a and 24b still move like a mechanism according to the movement of the rotational joint 23, and the inertia due to the movement burdens the user and lowers the force reflection efficiency. The problem with joysticks is not completely solved.
    [31] Recently, in order to fundamentally solve the above problems of the haptic joystick, the phantom shown in FIG. 2 is supplemented, and all the actuators are fixed to the base by replacing some rotational joints of the four-section link 22 of FIG. 2 with gimbal mechanisms. In order to improve the reverse drive, a method for constructing a device has been invented, and the invention has been registered in US Pat.
    [32] The present invention is to solve the above problems,
    [33] The object of the present invention is to implement a multiple degree of freedom, the configuration is simple and easy to interpret,
    [34] It is to provide a haptic joystick system that can improve the reverse driving performance by fixing all the actuators driving the device to the base.
    [1] 1 is a perspective view showing the structure of a serial haptic device.
    [2] Figure 2 is a perspective view showing the structure of the haptic device Phantom developed at MIT.
    [3] Figure 3 is a perspective view showing the structure of a three degree of freedom haptic joystick according to the present invention.
    [4] Figure 4 is an exploded perspective view showing the structure of the gimbal mechanism portion according to the present invention.
    [5] Figure 5 is a perspective view showing the structure of the six degree of freedom haptic joystick according to the present invention.
    [6] Figure 6 is an exploded perspective view of the handle of the six degree of freedom haptic joystick according to the present invention.
    [7] Figure 7 is a block diagram showing the configuration of a haptic joystick system according to the present invention.
    [8] 8 is a flow chart showing the operational flow of the haptic joystick system according to the present invention.
    [9] <Explanation of symbols for the main parts of the drawings>
    [10] 100: haptic joystick 110: handle
    [11] 111: screw 112: nut
    [12] 120: connection link portion 130: gimbal mechanism portion
    [13] 140: drive measurement unit 150: base
    [14] 200: controller 300: computer
    [15] 400: user
    [16] S141: Sensor M142: Actuator
    [17] axis 1, axis 2, axis 3, axis 4, axis 5, axis 6: active axis of haptic joystick
    [18] axis x, axis y: axis of rotation of the gimbal mechanism
    [19] axis x2, axis y2, axis z2: the axes of the handle
    [35] Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.
    [36] 3 to 8 show an embodiment of the present invention, Figure 3 is a perspective view showing the structure of the three degree of freedom haptic joystick according to the invention, Figure 4 is a structure of the gimbal mechanism of the haptic joystick according to the present invention 5 is a perspective view showing the structure of the six degree of freedom haptic joystick according to the present invention, Figure 6 is an exploded perspective view showing the structure of the handle of the six degree of freedom haptic joystick according to the present invention, Figure 7 Figure 8 is a block diagram of a haptic joystick system according to the invention, Figure 8 is a flow chart of a haptic joystick system according to the present invention.
    [37] First, an embodiment of a three degree of freedom haptic joystick according to the present invention will be described with reference to FIG. 3.
    [38] In the embodiment of the present invention as shown in Figure 3, the haptic joystick (100a) is a handle (110a), two connecting link portion 120, two gimbal mechanism portion 130, three drive measurement unit 140, the base It consists of 150, and implements three degrees of freedom in inputting the position of the user's hand and reflecting the force. The construction method and the principle of operation will be described in detail below in parts.
    [39] First, the handle 110a moves in contact with the user's hand, so that the end of the handle has an arbitrary position of three degrees of freedom according to the user's input. Since the handle is rotatably connected to the two connection links 120 through the spherical joint, the movement of the user's hand is transmitted to the connection link.
    [40] In the two connecting link unit 120, each connecting link unit is configured by connecting a plurality of links and a plurality of rotary joints in series as shown, one end is relatively rotatable through the handle and the spherical joints The opposite ends are connected to the two gimbal mechanism parts 130, and the opposite ends of the link connecting parts are bifurcated so as to be connected to the two gimbal mechanism parts one by one. Therefore, the movement of the handle is transmitted through the connecting link portion to rotate the two gimbal mechanism portion.
    [41] In the two gimbal mechanism unit 130, an exploded perspective view of each gimbal mechanism unit is shown in Figure 4, each gimbal mechanism unit 130 has four links (L131, L132, L133, L134) and five Rotating joints (J135, J136, J137, J138, J139), and each rotation joint is arranged in the order of the number of axes x, axis y, axis z, axis x, axis y sequentially at an angle interval of 90 degrees The four links and the five rotary joints together with the base 150 form a closed loop spatial 5 bar linkage. Therefore, the gimbal mechanism as described above is capable of performing two degrees of freedom by using the axis of rotation axis x and axis y of the rotational joints J135 and J139 which allow the links L131 and L134 to be relatively rotatable relative to the base. Will be implemented. Further, in arranging the two gimbal mechanism parts 130 as described above, as shown in Fig. 3, one active axis (axis y in Fig. 4) of each gimbal mechanism part coincides with axis 1a, and the remaining active When the axes (axis x in FIG. 4) are disposed in parallel with each other on the axis 2a and the axis 3a, the haptic joystick 100a realizes three degrees of freedom in a three-dimensional space. At this time, the axis 1a, axis 2a, axis 3a shown in Figure 3 is an active axis for analyzing the three degrees of freedom, the link of the gimbal mechanism connected thereto becomes an active link, the rotary joint of the gimbal mechanism connected thereto Becomes an active joint. By using such a gimbal mechanism, all actuators and sensors can be mounted on the base independently of the movement of the mechanism, so that even if the entire mechanism is moved by the input of the handle, the actuators and sensors are still not fixed to the base. .
    [42] In the configuration and arrangement of the three drive measurement unit 140, each drive measurement unit is composed of a sensor (S141) and the actuator (M142), and the arrangement method of the three drive measurement unit is the gimbal It is attached to the active link of the sphere to measure the angular displacement of each active joint and simultaneously drive the active link. Therefore, by measuring the amount of rotation of the active link and interpret the kinematics through the sensor (S141) of the three drive measurement unit, it is possible to calculate the position 3 degree of freedom of the handle 110, the actuator (M142) of the three drive measurement unit By driving to the appropriate torque through the dynamic analysis, the handle can reflect the force of the desired direction and size of three degrees of freedom, that is, any force in the three-dimensional space. On the other hand, the base 150 is the two gimbal mechanism portion Support 130 and three drive measurement unit 140.
    [43] By configuring the three degree of freedom haptic joystick through the above configuration method, all sensors and actuators can be fixed to the base, thereby improving the efficiency and the reverse driving force of the force reflection.
    [44] An embodiment of a six degree of freedom haptic joystick according to the present invention will be described with reference to FIG. 5.
    [45] In one embodiment of the present invention as shown in Figure 5, the haptic joystick (100b) is a handle (110b), four connecting link portion 120, four gimbal mechanism portion 130, six drive measurement unit 140, It is composed of a base 150, it can implement the six degrees of freedom in inputting the position of the user's hand, reflecting the force, three position degrees of freedom in three-dimensional space (linear motion in the x, y, z direction) And three posture degrees of freedom (rotational motion in the x, y, and z directions) can be implemented.
    [46] The construction method and the principle of operation will be described in detail below in parts.
    [47] First, when the handle 110b is composed of a screw 111 and a nut 112, the axial rotation of the screw and the axial position movement of the nut are mutually converted, and the axial force of the screw / nut The rotational torque of the nut in the axial direction can be mutually converted. The six degrees of freedom movement of any position and posture of the handle according to the user's input is converted into each position three degrees of freedom movement at both ends of the handle. Looking at this in detail, as shown in Figures 6a, 6b and 6c, if the handle in a linear motion in the x, y, x direction to perform the linear movement of the same size in both ends of the handle in the same direction to input information of the position 3 degree of freedom You can get it. On the other hand, if the force of F1, F2, F3 is applied to both ends of the handle in the x, y, and x directions, respectively, the handle generates the force of Fx = 2xF1, Fy = 2xF2, and Fz = 2xF3 in the corresponding direction. This force can be reflected to the user's hand through the handle. 6D, 6E, and 6F, when the handle is rotated about the x, y, and x axes, both ends of the handle are rotated in opposite directions to obtain input information having three degrees of freedom. On the other hand, when the force of F4, F5, F6 is applied to both ends of the handle in the x, y, and x directions, respectively, the handle generates torques of Tx, Ty, and Tz in the x, y, and x-axis directions. The torque can be reflected on the handle. Overall, if the user grabs the nut by hand and moves it in any position and posture six degrees of freedom in three-dimensional space, both ends of the handle each perform a corresponding motion, and the two ends of the handle constitute a combination of these motions. The complex motion is transmitted to the driving measurement unit 140 through the connection link unit and the gimbal mechanism unit, respectively, so that the six degree of freedom position and posture information of the handle can be accurately calculated through the kinematic analysis. In addition, if the six actuators of the drive measurement unit generate the appropriate torque through dynamic analysis, the torque is applied to both ends of the handle through the gimbal mechanism and the linking link, and the handle is applied to the arbitrary force and torque in the three-dimensional space. Through it can be reflected in the hands of the user. Through this, the haptic joystick transmits six degrees of freedom motion according to a user input, and at the same time, the six degrees of freedom can be reflected on the handle to function as a bidirectional input / output device.
    [48] The configuration and arrangement of the four connection link units, the four gimbal mechanism units, the six drive measurement units, and the bases described below are similar to those of the three degree of freedom haptic joystick described above. I will explain.
    [49] In the four connection link unit 120, each connection link unit is configured by connecting a plurality of links and a plurality of rotary joints in series. As a method of arranging the four connection links, as shown in FIG. 5, two connection link portions are spherically connected to one side of the handle 110b, and the other two connection link portions are connected to the other side of the handle. Each two connecting links are separated into two links, one to four gimbal mechanisms. Therefore, the movement of the handle is transmitted through the connecting link portion to rotate the four gimbal mechanism portion.
    [50] In the configuration and arrangement of the four gimbal mechanism unit 130, the configuration method of each gimbal mechanism portion is as described with reference to Figure 4 in the embodiment of the three degree of freedom haptic joystick, four gimbal mechanism portion As shown in FIG. 5, the two gimbal mechanisms have one active axis (axis y in FIG. 4) aligned with axis 1b and the other active axis (axis x in FIG. 4) in parallel with each other. 3b, align one active axis (axis y in FIG. 4) of the other two gimbal mechanisms to axis 4b and the other active axes (axis x in FIG. 4) parallel to each other on axis 5b, axis 6b, When the axis 1b and the axis 4b are disposed in parallel, the haptic joystick 100b realizes six degrees of freedom. At this time, the axis 1b, axis 2b, axis 3b, axis 4b, axis 5b, axis 6b shown in FIG. 4 becomes an active axis for implementing the six degrees of freedom, and the link of the gimbal mechanism connected thereto becomes an active link. The rotary joint of the gimbal mechanism connected thereto becomes an active joint.
    [51] In the configuration and arrangement of the six drive measurement units 140, each drive measurement unit is composed of a sensor (S141) and the actuator (M142), and the arrangement method of the six drive measurement unit is the gimbal It is attached to the active link of the sphere to measure and drive the angular displacement of each active joint. Therefore, by measuring the rotational amount of the active link and interpreting the kinematics through the sensors (S141) of the six drive measurement unit, it is possible to calculate the position and posture six degrees of freedom of the handle (110b), the actuator of the six drive measurement unit ( By driving M142) to the appropriate torque through dynamic analysis, it is possible to reflect the force and torque in the desired direction of six degrees of freedom at the end of the handle. The base 150 supports the four gimbal mechanism 130 and the six drive measurement unit 140.
    [52] By constructing the 6-degree of freedom haptic joystick using the above configuration method, all sensors and actuators can be fixed to the base, thereby improving the efficiency and the reverse driving efficiency of force reflection.
    [53] Through the present invention, it is possible to configure the haptic joystick described above, input the position of the user's hand into the computer in conjunction with the controller and the PC, and configure the haptic joystick system to output the force to the user's hand according to the computer's command. have.
    [54] 7 is an embodiment of configuring a haptic joystick system using the three degrees of freedom and six degrees of freedom haptic joystick 100.
    [55] As shown in FIG. 7, an embodiment of the present invention includes the three or six degrees of freedom haptic joystick 100;
    [56] A controller that receives a signal from a sensor of the driving measuring unit, calculates a position of a user's hand, calculates a torque required for each actuator of the driving measuring unit, and outputs a corresponding driving signal in order to apply an appropriate force to the handle ( 200);
    [57] A computer (300) interoperating with the controller;
    [58] A user 400 in contact with the hand with the haptic joystick and interacting with the computer;
    [59] It consists of.
    [60] Looking at the operation principle of inputting the position and posture of the user 400 hand to the computer 300 through the embodiment through FIG. 7, the driving measurement unit 140 of the haptic joystick according to the movement of the user 400. Displacement of each active joint measured from the sensor (S141) of the) is transmitted to the controller 200, the controller 200 collects the signals to interpret the kinematics and calculate the position information of the user's hand to calculate the computer 300 To pass).
    [61] Looking at the operation principle reflecting the output of the computer 300 in the form of force and torque in the hands of the user 400 through the above embodiment through FIG. 7, the computer 300 to reflect in the hand of the user 400 A force feedback command indicating a magnitude and direction of a force and torque to be output to the controller 200, and the controller 200 performs an angle calculation of the driving measurement unit 140 of the haptic joystick through dynamic calculation to correspond to the output command. The magnitude and direction of the torque that should be generated in the actuator M142 are calculated, and the actuator control signals of the corresponding active joints are transmitted to the actuator M142.
    [62] The operation principle of the haptic joystick system according to the present invention will be described in detail below with reference to the flowchart of FIG. 8.
    [63] Referring to the operation principle of the user 400 inputs the computer 300 in the present embodiment through FIG. 8, the user 400 initializes the controller 200 (F201), and cooperates with the computer 300. The predetermined program is initialized (F301). When the user 400 holds the handle 110 of the haptic joystick 100 by hand (F101) and moves the handle, the angular displacement of each active joint is measured through the sensor S141 (F102) and transmitted to the controller. . The controller 200 receives the signal (F202), interprets the kinematics to calculate the position and posture of the handle 110 (F203), and transmits it to the computer 300 (F204). The computer 300 receives the signal (F302), and a predetermined program performs a corresponding operation using the input position and posture of the handle 110 (F303). The predetermined program executed in the computer 300 outputs a command to the controller 200 to present an appropriate force and torque to the user 400 according to a situation (F304). The controller 200 receives the force feedback command from the computer 300 (F205), and calculates the torque required for the actuators M142 of the active joints of the haptic joystick 100 through dynamic calculation (F206). This is outputted as a predetermined control signal (F207). The actuator is driven according to the control signal, and the force and torque corresponding to the force feedback output by the program executed in the computer 200 are transmitted to the user's hand (F103). The flow of the work is repeated until a predetermined program executed in the computer 300 ends, and when the user 400 finishes the desired work, the program ends (F305), and the contact with the handle of the haptic joystick is made. Release (F104).
    [64] The haptic joystick has high utility because it interacts with the user's hand among various haptic devices.
    [65] Haptic joysticks offer intuitive input and output, presenting a new paradigm as a next-generation computer interface. Combined with virtual reality technology, haptic joysticks can be used for games, education, rehabilitation, industrial and military use, and master using remote control technology. -Slave system can be used for remote surgery and industrial robot control.
    [66] Through the present invention, by constructing a new multi-degree of freedom haptic joystick system having high efficiency and reverse driving force, it is possible to increase productivity and efficiency in performing the above-described application.
    权利要求:
    Claims (4)
    [1" claim-type="Currently amended] In the haptic joystick that inputs the position information of the hand to the computer and outputs the appropriate force to the user's hand according to the command of the computer,
    The handle 110a, two connection links 120, two gimbal mechanism 130, three drive measurement unit 140 and the base 150,
    In the configuration, arrangement and features of each part,
    The handle (110a) moves in contact with the user's hand, one end is connected to the two connecting links 120 through the spherical joint, the other end through the universal joint,
    The two connecting link portion 120 is composed of a plurality of links and a plurality of rotary joints, respectively, so that the upper part is connected in common to the end of the handle and the lower part is divided into two branches so as to be connected to the two gimbal mechanisms respectively. The gimbal mechanism moves according to the movement of the handle,
    The two gimbal mechanism unit 130 is composed of four links and five rotary joints and each of the gimbal mechanisms, including a base to form a five-section link to enable two degrees of freedom of movement, two gimbal In the arrangement method of the bend, two gimbal mechanisms implement three degrees of freedom by matching one active axis of each gimbal mechanism part and arranging the other active axes in parallel,
    The three drive measurement unit 140 is composed of a sensor and an actuator, respectively, attached to each active joint of the gimbal mechanism 130 to measure and drive the angular displacement of each active joint,
    The base 150 supports the gimbal mechanism portion and the drive measurement portion,
    The haptic joystick, characterized in that the drive measurement unit can measure the degree of freedom of position of the handle while being fixed to the base independently of the movement of the handle, and can reflect the force of the three degrees of freedom on the handle.
    [2" claim-type="Currently amended] In the haptic joystick that inputs the position information of the hand to the computer and outputs the appropriate force to the user's hand according to the situation of the computer,
    The handle 110b, four connection links 120, four gimbal mechanism 130, six drive measurement unit 140 and the base 150,
    In the configuration, arrangement and features of each part,
    The handle 110b is composed of a screw 111 and a nut 112 and the user converts the axial rotation of the screw into the positional movement in the axial direction by moving the user by holding the nut by hand, Transfers the user's hand movement to the connection link by converting the force into the rotational torque in the axial direction,
    Each of the four link links 120 is configured by connecting a plurality of links and a plurality of rotary joints in series, and at each end of the handle 110b in order to arrange the four link links. Connecting the two link links with spherical joints, and connecting the remaining two link links with universal joints at opposite ends of the handle, and each of the two link links is divided into two branches and connected to one of four gimbal mechanisms. The movement of the handle is transmitted through the connecting link to move the four gimbal mechanism,
    The four gimbal mechanism unit 130 is composed of four links and five rotary joints each of the gimbal mechanism portion, including a base to form a five-section link to enable two degrees of freedom of movement, four gimbal mechanism portion Arrangement method of the two gimbal mechanisms to match one active axis and the other active axis parallel to each other, one active axis of the other two gimbal mechanisms and the other active axis parallel to each other and the matching active axis is parallel Four gimbal mechanism to realize the six degrees of freedom,
    The six driving measurement units 140 are each composed of a sensor and an actuator and attached to each active joint of the gimbal mechanism unit 130 to measure and drive the angular displacement of each active joint.
    The base 150 supports the gimbal mechanism portion and the drive measurement portion,
    The haptic joystick, which is capable of measuring the position and posture of six degrees of freedom of the handle while being fixed to the base independently of the movement of the handle, and reflecting the force and torque of six degrees of freedom on the handle.
    [3" claim-type="Currently amended] In the haptic joystick system for inputting the position information of the hand to the computer and outputting the appropriate force to the user's hand according to the command of the computer,
    Haptic joystick 100 manufactured by the method of claim 1;
    Receives a predetermined signal from the sensor of the drive measurement unit of the haptic joystick to calculate the position of the user's hand and transmits it to the computer, and receives the force feedback command from the computer to calculate the torque required for each drive shaft of the haptic joystick A controller 200 for driving an actuator of each drive shaft;
    A computer (300) interoperating with the controller;
    A user 400 in contact with the hand with the haptic joystick and interacting with the computer;
    Haptic joystick system, characterized in that consisting of.
    [4" claim-type="Currently amended] In the haptic joystick system for inputting the position information of the hand to the computer and outputting the appropriate force to the user's hand according to the command of the computer,
    Haptic joystick (100) manufactured by the method of claim 2;
    Torque required for each drive shaft of the haptic joystick by receiving a signal from the sensor of the driving measurement unit of the haptic joystick, calculating the position and posture of the user's hand and transmitting it to the computer, and receiving a force feedback command of the computer as a predetermined signal. A controller 200 having a characteristic of calculating and driving an actuator of each drive shaft;
    A computer (300) interoperating with the controller;
    A user 400 in contact with the hand with the haptic joystick and interacting with the computer;
    Haptic joystick system, characterized in that consisting of.
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    同族专利:
    公开号 | 公开日
    KR100482000B1|2005-04-13|
    引用文献:
    公开号 | 申请日 | 公开日 | 申请人 | 专利标题
    法律状态:
    2001-11-26|Application filed by 송재복
    2001-11-26|Priority to KR20010073980A
    2003-06-02|Publication of KR20030043023A
    2005-04-13|Application granted
    2005-04-13|Publication of KR100482000B1
    优先权:
    申请号 | 申请日 | 专利标题
    KR20010073980A|KR100482000B1|2001-11-26|2001-11-26|6 degree-of-freedom haptic joystick system using gimbal mechanism|
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