Abstract: A transferring apparatus is composed of a first arm swingably provided around a first axis of a pedestal, a second arm whose length is different to the first arm is swingably provided around a second axis, a hand attached to the front end of the second arm, and a first motor to reciprocatingly swings the first arm provided in the pedestal. A first pinion is fixed to the pedestal concentrically to the first shaft, and a second pinion is fixed to the base end of the second arm concentrically with the second axis. Further, racks are provided in the both of left and right side of the first pinion and the second pinion. A large transferring apparatus is composed so that two transferring apparatus are arranged in one pair, the hand are mutually coupled by a transfer beam.

Abstract: An arm part of a manipulator of an industrial robot has at each end thereof a connector for connecting the arm part to a gear and a stiffener for stiffening the end region of the arm part. At least one aperture is arranged in a hollow structure of the stiffener for providing access to connecting members.

Abstract: A method of marking an article includes, in a control system, selecting one of a number of containers. The method further includes each container having a fluid containing respective unique marking elements therein. The method further includes generating control signals in accordance with the selected container. The method further includes transferring the control signals to a manipulator, the manipulator being responsive to the control signals to apply at least part of the fluid to the article to thereby marking the article with at least one marking element.

Abstract: A method and a system for controlling a plurality of manipulators with a large number of control units associated with the manipulators in such a way that each control unit controls at least one manipulator, are characterized in that an operating device accesses several control units for controlling the manipulators. Thus, it is possible according to the invention to operate even very closely juxtaposed manipulators without any crossing and interlacing of the connecting channels between the operating devices and control units which would prevent a reliable association in operation. The invention also makes it possible for only one operator to operate cooperating robots.

Abstract: A system and method for sensing and compensating for unintended joint movement of a robotic arm caused by application of a load. The system may have a plurality of external encoders each in intimate contact with an external edge portion of one of a plurality of robotic arm joints to sense joint movement caused by application of the load, and a computing device configured for calculating a compensation amount based on the sensed joint movement and sending the calculated compensation amount to a corresponding robot motor encoder to correct the position of the joint by the compensation amount. The method may comprise applying the load one portion at a time, such that a portion of the load is applied, the compensation amount is calculated, the position of the joint is corrected, and then the process repeats, with another portion of the load applied to the robotic arm.

Abstract: A robotic treatment delivery system including a linear accelerator (LINAC), and a robotic arm coupled to the LINAC. The robotic arm is configured to move the LINAC along at least four rotational degrees of freedom and one substantially linear degree of freedom.

Abstract: An industrial robot having: an arm, a wrist element rotatably interconnected to the arm, a work tool mounted on a distal end of the wrist element, and a motor mounted on the wrist element; wherein an umbilical-member connected to the work tool and a flat cable connected to the motor are disposed to run along the wrist element from the arm side to aid work tool or to the motor, characterized in that a pipe member extending in a direction of a rotation axis of the wrist element is provided inside the arm, the umbilical-member connected to the work tool being passed inside the pipe member, the flat cable connected to the motor being wound around outside of the pipe member, with the flat cable slacked in a rotating direction of the wrist element.

Abstract: A robotic manipulator device includes a robotic linkage to rotate an insertion axis about a remote center of motion with two degrees of freedom. A driven link supports the insertion axis. Rigid links in a parallelogram arrangement constrain the driven link to move in parallel to a drive link and the insertion axis to rotate about the remote center of motion. A drive unit has an output shaft coupled to the drive link. Rotation of an input shaft causes the output shaft to rotate. The input and output shafts are at a substantial angle. A housing supports the output shaft. A first motor causes the input shaft to rotate the output shaft. A second motor causes the housing to rotate, rotating the output shaft about an axis that is substantially parallel to the input shaft and passes through the remote center of motion.

Abstract: In a robot, a support member is supported to an arm to be reciprocable with respect to one of first and second sides of the arm in a predetermined direction. A rotary member of a converter is coupled to a motor, and a liner movable member of the converter is contacted to the rotary member and lined to the support member. The converter works to transfer rotary motion received y the rotary member from the motor as linear motion to the liner movable member rough a transfer contact portion between the rotary member and the liner movable member to thereby move the liner movable member together with the support member in the predetermined direction. The transfer contact portion between the rotary member and the liner movable member is located offset to the one of the fast and second sides of the arm relative to the other thereof.

Abstract: A robot arm 3 includes a base-side arm component 11, an intermediate arm component 12, and a tip-side arm component 13. The intermediate arm component 12 is divided at an axially intermediate position into a base-side part 20 and a tip-side part 21, which are connected so as not to be separated from each other in the arm axis direction but rotatable around the arm axis. The base-side part 20 fixedly contains a moving device 31 for axially moving a drive shaft. The tip-side part 21 fixedly contains a threaded member 32 meshed with a thread groove formed in the outer surface of the drive shaft. The drive shaft is axially moved while being meshed with the threaded member 32 so that the threaded member 32 rotates around the drive shaft. As a result, the tip-side part 21 rotates in the arm axis direction.

Abstract: A method and system for performing invasive procedures includes a surgical robot which is controlled by a guidance system that uses time of flight calculations from RF transmitters embedded in the robot, surgical instrument, and patient anatomy. Sensors around the room detect RF transmissions emitted by the RF transmitters and drive the robot according to a preprogrammed trajectory entered into the guidance system.

Abstract: In an apparatus for resistance-based muscular force evaluation and training, elasticity at the distal end of a robot arm is made to follow changes caused in the force exerted by the muscles of praxis as a result of changes in angle at the first and second joints. Even when the trainee changes his or her position, he or she may be indicated of and may positively comprehend the direction in which he or she is to exert the force. The robot arm have its distal end secured to the distal end of the link mechanism has elasticity variable with directions. The elasticity is varied to follow changes caused in the force exerted on the distal end of the link mechanism by a set of antagonistic mono-articular muscles and a set of antagonistic bi-articular muscles, as a result of changes in angle at the first and second joints.

Abstract: A method for calibration of an industrial robot including a plurality of movable links and a plurality of actuators effecting movement of the links and thereby of the robot. The method includes mounting a measuring tip on or in the vicinity of the robot, moving the robot such that the measuring tip is in contact with a plurality of measuring points on the surface of at least one geometrical structure on or in the vicinity of the robot, reading and storing the positions of the actuators for each measuring point, and estimating a plurality of kinematic parameters for the robot based on a geometrical model of the geometrical structure, a kinematic model of the robot, and the stored positions of the actuators for the measuring points.

Abstract: A robotic arm-end gripping device having a belt-driven drive train is provided. The gripping device includes a set of opposing gripping arms, a variable speed motor, a motor controller adapted to control the operation of the variable speed motor, a drive train driven by the variable speed motor, the drive train comprising a drive belt, a plurality of sheaves, and a plurality of belt clamps mounted to the drive belt and operatively connected to the opposing gripping arms, and a robot arm-end interface. The gripping device may include a fail-safe method and apparatus for prevent the dropping of the gripped article. The belt drive and associated controls provide smooth and rapid operation. The gripping device may be adapted to any arm-end tooling.

Abstract: A robotic instrument system and method, comprising at least two instrument drive assemblies each detachably coupled to a respective instrument assembly. Each instrument assembly comprising an elongate, flexible guide instrument configured to be inserted into a patient's body. The instrument drive assemblies comprise one or more motors configure to operate a respective instrument assembly. One or more controllers are operatively coupled to the instrument drive assemblies. The method comprises maneuvering a distal end of each of the respective guide instruments into a patient's heart by actuating the respective drive assembly performing a procedure controlled by the one or more controllers.

Abstract: A method and system for performing invasive procedures includes a surgical robot which is controlled by a guidance system that uses time of flight calculations from RF transmitters embedded in the robot, surgical instrument, and patient anatomy. Sensors around the room detect RF transmissions emitted by the RF transmitters and drive the robot according to a preprogrammed trajectory entered into the guidance system.

Abstract: A substrate handling robot having a robot body and a robot arm with an end effector is configured to exhibit angular (?), radial (R) and Z motion. A pair of coaxial shafts link the robot arm to respective motors dedicated to angular (?) and radial (R) motions. The motors are stationarily mounted with respect to the robot body. The shafts are rotatably supported by a floating platform which is motivated in the Z direction by a third motor also stationarily mounted with respect to the robot body. The third motor is coupled to the platform by a Z motion linkage. The first and second motors are coupled to the coaxial shafts by angular and radial motion linkages each of which includes primary and secondary timing belts whose relative motions are synchronized with the Z motion linkage to achieve controllable independent angular (?), radial (R) and Z motions in a simple, light-weight package.

Abstract: A belt tension adjustment apparatus and a robot arm having the belt tension adjustment apparatus are disclosed. The belt tension adjustment apparatus includes a tension measurement part for measuring tension of a belt running on an endless track, a tension adjustment part for pressing the belt in a direction inclined with respect to a surface of the belt to apply a pressing force to the belt, and a controller for controlling the tension adjustment part depending on the measured tension. The belt tension adjustment apparatus prevents variation of a running speed of the belt and maintains tension of the belt.

Abstract: A system for performing the method of this invention includes a leader having a robot arm able to articulate about first axes and supporting an end effector. A follower includes a robot arm able to articulate about respective second axes. Servo motors articulate the leader arm about the first axes and the follower arm about the second axes. A user interface allows a user to jog the arm of the leader and to program movement of the arms for automatic execution such that the end effector reaches predetermined positions. A controller, operatively connected to the servo motors and the user interface, controls operation of the servo motors, moves the arm of the leader in accordance with the programmed movement, and moves the arm of the follower such that it tracks or mirrors movement of the leader.

Abstract: In a feed drive apparatus wherein a moving element 27 is driven by drive legs 21, 22 having extension/contraction deforming parts 23 and shear deforming parts 24, sine wave drive voltages are respectively applied to the extension/contraction deforming parts 23 and shear deforming parts 24 of the drive legs 21, 22 in order to permit high speed operation, and make the average voltage effectively zero.

Abstract: A loadlock chamber assembly includes a loadlock chamber, a sub-chamber removably attached to the loadlock chamber and a first robot arm having a primary pivot axis within the sub-chamber, wherein the first robot arm can move a substrate from a position approximately in a center of the loadlock chamber to a position outside the loadlock chamber.

Abstract: A toy robot system includes a toy robot and a surface over which the robot can move. The surface is constructed from a number of modules of various types that may be joined together. Each module (except for spacer modules) includes at least one track segment along which the robot may move. Each module is square and each track segment extends from the center of the module to one side. A code readable by the robot is provided at the beginning of each segment so that the robot knows what type of module it is entering, and a code is provided at the center of each module so that the robot can calculate its position.

Abstract: A conveying arm of the invention includes a first pivotable shaft connected to a first arm which is also pivotably connected to a third arm having an intermediate pivotable portion. The third arm is also pivotably connected to a fifth arm which is also pivotably connected to a seventh arm which has a holding portion for an object to be conveyed. The conveying arm also includes a second pivotable shaft connected to a second arm which is also pivotably connected to a fourth arm having an intermediate pivotable portion. The fourth arm is also pivotably connected to a sixth arm which is also pivotably connected to the seventh arm. With respect to both the third and fourth arms, a line linking one-side end portion to an intermediate pivotable portion is substantially perpendicular to a line linking the other-side end portion to the intermediate pivotable portion.

Abstract: Surgical robots and other telepresence systems have enhanced grip actuation for manipulating tissues and objects with small sizes. A master/slave system is used in which an error signal or gain is artificially altered when grip members are near a closed configuration.

Abstract: A medical master/slave manipulator is excellent in operability and capable of reducing burden on the operator. The medical master/slave manipulator includes a master unit provided with an operation control portion, a slave unit provided with a working device, an interlocking mechanism interlocking the slave unit with the master unit, an orientation difference measuring mechanism for measuring the orientation difference between the orientation of the master unit and that of the slave unit, and a control mechanism for controlling the slave unit to adjust the orientation of the slave unit to that of the master unit so that the orientation difference is reduced to zero in a transient master/slave operation mode in which an operation mode changes from an unrestricted operation mode to a master/slave operation mode.

Abstract: The invention concerns a kinematic device for supporting and programmably moving a terminal element. The platform (11) bearing the terminal element (12) is linked by four swivel joints (9) and (10) with two legs each consisting of two support rods (7) or (8) forming deformable parallelograms mounted each on slides (3) or (4) mobile in the x direction. The pivot plate (29) articulated on the platform (11) about the hinge pin (30) is controlled by the control rods (27), controlling pivoting (14) and lateral displacement (18) connected respectively by the swivel joints (26, 13 and 17) to the slides (3, 12 and 26). It consists in a parallel kinematics with four degrees of freedom, namely three translational and one rotational whereof the angle can be greater than 120°.

Abstract: A method for controlling movement of an automated machine. The movement is defined by a plurality of steps. First, a buffer of a predetermined size is defined. The buffer stores a current step and one or more previous steps in the movement of the automated machine. Then a current step in the movement of the automated machine is executed. Next, the buffer is checked to see if the current step executed in the movement of the automated machine movement is the same as a predetermined step of interest. If the current step is a predetermined step of interest, the buffer is checked to determine what at least one previous step was. If the current step was the step of interest, a new step is executed in the movement of the automated machine, the new step executed depending on what the at least one previous step was.

Abstract: A compliance mechanism for manipulating a control object by an end effector supported by a robotic arm. The robotic arm is supported by a combination of linear slides for two-axis freedom of movement. A locking arm is attached to the robotic arm and the locking arm is moveable between a locked and an unlocked position. The locking arm is biased in the locked position to restrict movement of the robotic arm along the two axes. A plunger extends adjacent the end effector. Upon engagement with an alignment feature associated with the control object, the plunger moves the locking arm from the locked to the unlocked position, thereby introducing compliance along the two axes manipulation of the control object.

Abstract: A method and a device for controlling a robot on the basis of data from sensors with their own sensor data structures. For solving the problem of adapting to different sensors and their data structures and consequently permitting in simple manner the use of different sensors without intervening in the actual robot control program, according to the system the sensor data are processed to robot control data with a control data structure usable by a system control program and a processing device suitable for the same is provided.

Abstract: A positioning device is provided. The positioning device includes a movable platform and a monolithic base. Struts are attached to both the movable platform and the monolithic base. The monolithic base moves each of the attached struts to cause the movable platform to move.

Abstract: A transfer arm is formed of a first short link, a first parallel link pivotally connected to the first short link, a second short link pivotally connected to the other ends of the first parallel link, a second parallel link pivotally connected to the second short link, and a third short link pivotally connected to the second parallel link. A linear guide is integrally formed with the first short element to extend in a direction perpendicular to the first short link. One link element of the second parallel link extends and is linearly slidably attached to the linear guide. A holding plate is connected to the third short link to be moved linearly according to a rotation of a drive shaft connected to the first parallel link while deforming parallelograms formed by the first and second parallel lines.

Abstract: A positional control system, comprising a robotically controlled arm, for varying the position of a robotic surgical tool, is provided. The robotic surgical tool can be in the form of an image capture device, such as an endoscope, for example. The positional control system comprises a base and a mounting formation arranged to support the robotic surgical tool. The positional control system further comprises an articulated arm extending between the base and the mounting formation. The articulated arm has an upper arm portion, a forearm portion, a forearm link member and an upper arm link member. The portions and the link members are pivotally secured relative to one another to effect displacement of the mounting formation relative to the base. The forearm link member is positioned at least partially within the forearm portion and the upper arm link member is positioned at least partially within the upper arm portion.

Abstract: A SCARA type robot with counterbalanced arms and tilting base. This apparatus enables accurate planar movement of a probe. Weak or flexible foundations or footings do not affect positioning accuracy of the probe. Positioning accuracy, relative to the movement plane, of a probe is unaffected by positions of the arms. At any angle of the probe movement plane the counterbalanced arms allow the same size drive motors, torque transmission devices, and drive electronics. These features make the invention very useful for on-site or portable near-field testing of antennas. A manipulator may be used in place of the probe. Most of the benefits will be retained if load variations on the manipulator are kept small.

Abstract: A coordinate positioning machine comprises a fixed structure including a table and a supporting frame, rigidly connected together. A movable arm is suspended from the frame by means of three powered telescopic struts, each of which is universally pivotally connected to both the arm and the frame. As a consequence, the movable arm is able to move with three rotational degrees of freedom. Movement of the arm with each of these degrees of freedom is constrained by a passive device, connected to the arm and the fixed structure, and which eliminates all rotational movement of the arm, while simultaneously permitting translation thereof.

Abstract: A linear guide comprises a support element and a carriage sliding on the support element. The carriage has two hollow cylinders sliding on an air bearing on the support element and a body arranged between them. The support element and the two hollow cylinders of the carriage are separated by a gap to which compressed air can be applied. A linear motor formed from a u-shaped stator and an armature is foreseen as drive mechanism for the carriage. During operation, heat dissipation occurs in the armature which heats the carriage. In order to maintain changes in the thickness of the gap within predetermined limits, the support element and/or those parts of the carriage whose temperature influence the thickness of the gap are heated to a predetermined temperature.

Abstract: An upper arm 4 and a lower arm 6 of a parallel link system that perform extension and retraction action in the same direction without mutual interference are arranged within a vacuum enclosure 1. Three magnetic couplings are arranged coaxially at three levels, through which extension/retraction action and swivel action of upper and lower arms are effected. Using a cam box having three output shafts driven by a single input shaft to which an arm drive motor is connected, extension/retraction drive and Z axis drive of upper and lower arms are performed, while swiveling action of upper and lower arms is driven by a swivel motor.

Abstract: A burden loading robot includes a loading portion installed in a robot main body and a balancer for offsetting off-center loading of weight of the loading portion. The loading portion includes a loading plate which can be moved away from a fixing portion to a loading position outwards from the robot main body. When the loading plate is moved to the loading position, the balancer moves to the direction reverse to that of the loading plate at the same time. Thus, off-center loading of weight generated when a burden is loaded on the loading plate is offset by the balancer, to accordingly avoid the robot from falling down.

Abstract: A gimbal drive module comprising an elbow (24) formed of composite material and having two legs. On one leg, elbow (24) includes an azimuth drive module (26). On the other leg, elbow (24) includes an elevation drive module (30). Azimuth drive module (26) and elevation drive module (30) include motors which when energized enable displacement of the respective legs in order to control the azimuth and elevation of elbow (24) to enable pointing of a structure, such as an antenna (18), as may be located on a second elbow outboard end (20).

Abstract: A coordinate positioning machine comprises a fixed structure including a table and a supporting frame (314), rigidly connected together. A moveable arm (310) is suspended from the frame by means of three powered telescopic struts (316), each of which is universally pivotally connected to both the arm and the frame. As a consequence the moveable arm is able to move with three rotational degrees of freedom. Movement of the arm with each of these degrees of freedom is constrained by a passive device (340), connected to the arm and the fixed structure, and which eliminates all rotational movement of the arm, while simultaneously permitting translation thereof.

Abstract: A controller is provided for a multi-axis robot having at least first and second axis assemblies, the first and second axis assemblies each having an arm, a servomotor driven by a control input and a coupling in the form of a decelerator, which includes a spring element, coupling the servomotor and the arm, the second axis assembly being disposed at an end of the arm of the first axis assembly. The controller includes the first and second axis assemblies each including torsional angle detector for detecting a torsional angle of a respective one of the couplings. A dynamic coupling calculator calculates coupling parameters of the couplings. The first and second axis assemblies each include a semi-closed loop.

Abstract: An apparatus for mutual conversion between circular motion and reciprocal motion includes a lever member which is rotatably mounted on a line connecting a rotational center and a circumference of a rotary disk, the lever member having a fulcrum, an action point and a force point, and being provided with a first regulator serving as an action point regulator and a second regulator serving as a movable fulcrum regulator. The first regulator is coupled to a reciprocating body. The movable fulcrum regulator has support members for supporting the fulcrum point and the first regulator has support members for supporting the action point in a longitudinal direction of the lever member.

Abstract: A vacuum transfer device for engaging a vacuum chuck to introduce a vacuum thereto includes an upper fixed plate fixed, a lower plate slidingly coupled with the upper plate so as to be capable of sliding toward and away from the vacuum chuck, and a pushing unit mounted to the upper plate for forcing the lower plate into position against the vacuum chuck. The pushing unit has a lever urged by a coil spring to press a roller into engagement with a curved surface of the lower plate, and gap control elements by which the position of the roller relative to the inclined surface can be adjusted to in turn adjust the force exerted by the roller on the lower plate. The gap control elements along with the curved surface of the lower plate make it quite easy to set the precise force by which the roller positions the lower plate of the device against the vacuum chuck.

Abstract: An apparatus and method for direct physical interaction between a person and a general purpose manipulator controlled by a computer. The apparatus, known as a collaborative robot or "cobot," may take a number of configurations common to conventional robots. In place of the actuators that move conventional robots, however, cobots use variable transmission elements whose transmission ratio is adjustable under computer control via small servomotors. Cobots thus need few if any powerful, and potentially dangerous, actuators. Instead, cobots guide, redirect, or steer motions that originate with the person. A method is also disclosed for using the cobot's ability to redirect and steer motion in order to provide physical guidance for the person, and for any payload being moved by the person and the cobot. Virtual surfaces, virtual potential fields, and other guidance schemes may be defined in software and brought into physical effect by the cobot.

Abstract: An arm mechanism includes a drive control mechanism that uses an end effector coordinate system and has an end effector drive control mechanism. The drive control mechanism includes an end effector rotational drive control mechanism and an end effector coordinate system translational drive control mechanism. The rotational drive control mechanism has three rotational actuators for driving end effector rotation about each axis separately. The end effector coordinate system translational drive control mechanism has an end effector coordinate system translational actuator to drive translational motion of the object. The drive control mechanism further includes an orientation maintenance mechanism that maintains the orientation of the target object on the absolute coordinate system and two absolute coordinate system translational actuators supported on the orientation maintenance mechanism for providing translational motion of the object along two orthogonal axes on the absolute coordinate system.

Abstract: A method and apparatus involving the application of an algorithm used for finding the time optimal trajectory for torque limited Industrial Robots, to achieve the operation of Cluster Tool Robots in an improved manner by modifying the applied algorithm through adding two additional constraints, i.e., jerk (the rate of change of acceleration) and the acceleration seen by the load. This modification renders it possible to create a robot arm trajectory that minimizes travel time by minimizing the excitation of uncontrolled resonances and avoiding command of an acceleration that would exceed the force of friction between a substrate holder on the end of the arm and a substrate held thereon by friction.

Abstract: A mechanism for movement of an object along a prefixed path, substantially of elliptical shape, including a support base provided with a single motor and at least two arms linked to each other at one end, with the free end of the outer arm carrying a supporting means for articles to be moved, thus forming a handling device. The arms, are rotated about parallel axes by a drive system located inside of the arms. The drive system has a transmission ratio associated with the connection between each arm. The paths along which the arms successive to the first one move are defined by the transmission ratios. The transmission ratio in the outermost arm determines the translation and possible contemporaneous rotation of the supporting means.

Abstract: A robot apparatus includes a robot arm, a robot hand, an electrical/electronic device mounted on the robot hand for operating the robot hand, and a hand attaching/detaching device, arranged between the robot arm and the robot hand, for detachably mounting the robot hand on the robot arm. A signal transmission path, is connected to an external robot controller at one end thereof and to the electrical/electronic device at the other end thereof, extends through the hand attaching/detaching device, and is able to be disconnected between the robot hand side and the robot arm side in the hand attaching/detaching device.

Abstract: An arm robot apparatus for removing workpieces such as injected molded articles includes a gripping device mounted on an arm and a race member mounted on the arm for circulating balls. The race member includes an inner part and an outer part. A ball race spindle is located inside the race member and extends along a longitudinal axis of the race member. A mounting block which is mounted on a supporting plate is attached to a first end of the ball race spindle. A second end of the ball race spindle has at least two semicircular ball races formed therein. The inner part and the outer part of the race members are interconnected in such a way that ball races of a circular cross-section are formed. The ball races are designed in such a manner that the balls arranged in the races contact the inner part and the outer part of the race member. The inner part of the race member also includes pre-tensioning channels in which balls are received for displacement and movement.

Abstract: The invention concerns a multiaxial industrial robot (1), including of a mount (2), a rotatable and swingable rocker (3), a swingable extension arm (6) and a multi-member rotatable and swingable robot hand (8), whose members are driven by motors (10, 11, 12) arranged on extension arm (6). Extension arm (6) is mounted (27) on one side on a one-arm formed rocker (4), whereby at least two motors (10, 11, 12) are arranged next to each other on the extension arm in the direction of extension of its swinging axis (7). With a triangular arrangement, motors (10, 11, 12) are arranged with their motor axes (13) in an isosceles triangle, whose base is oriented to bearing (27) of extension arm (6).

Abstract: A Six-Degree-of-Freedom Parallel-Manipulator having three inextensible limbs for manipulating a platform is described in which the three inextensible limbs are attached via universal joints to the platform at non-collinear points. Each of the inextensible limbs is also attached via universal joints to a two-degree-of-freedom parallel driver such as a five-bar lineage, a pantograph, or a bidirectional linear stepper motor. The drivers move the lower ends of the limbs parallel to a fixed base and thereby provide manipulation of the platform. The actuators are mounted on the fixed base without using any power transmission devices such as gears or belts.