Abstract: An endoscope system includes an insertion section, a first active bending section, a second active bending section, a position-information acquiring section, a first control section, a second control section, and a third control section. The first control section controls, based on a detection result of the position-information acquiring section, a first driving section of the first active bending section such that a first end portion of a first tubular section of the first active bending section moves away from a center point. The first control section controls a second driving section of the second active bending section such that a second end portion of a second tubular section of the second active bending section approaches the center point. The third control section controls the first driving section such that force in a direction of bending the first tubular section in a first bending operation acts on the first end portion.

Abstract: A variable stiffness actuator includes a shape-memory member, and a heater configured to receive power to heat the shape-memory member so as to cause the shape-memory member to change from a first phase as a low stiffness state to a second phase as a high stiffness state showing a higher stiffness than the low stiffness state. The actuator also includes a first conductive wire having one end connected to the heater and constituting a part of a power supply line for the heater, and a second conductive wire having one end connected to the other end of the first conductive wire, thicker than the first conductive wire, and having an electrical resistance per unit length lower than that of the first conductive wire.

Abstract: A variable-stiffness actuator system includes a shape-memory member in which a stiffness increases by being heated and decreases by radiating heat, a heating member configured to generate heat, a channel arranged along the longitudinal axis of the shape-memory member, a transfer section configured to selectively supply and stop first and second heat transmission fluids into the channel, and a controller configured to control the transfer section. The controller causes the transfer section to supply the first heat transmission fluid and then supply the second heat transmission fluid into the channel, and further to stop the supply of the second heat transmission fluid so that retention of the first and second heat transmission fluids simultaneously occurs in the channel.

Abstract: A shape measuring apparatus includes a cylindrical flexible body and a bend detection sensor. The sensor includes an optical fiber extending along the flexible body, a detection target to vary characteristics of detection light guided through the optical fiber in accordance with a curvature of the optical fiber, and a light detection unit to detect the detection light. The shape measuring apparatus also includes a shape calculating device to calculate a bend shape of the flexible body, based on the variation of the characteristics of the detection light, a cylindrical sheathing member sheathing a part of the optical fiber in the flexible body, and a hard distal member provided at a distal end of the flexible body and holding a distal end of the sheathing member.

Abstract: An insertion system includes an insertion section and a rigidity variable portion provided in the insertion section. The rigidity variable portion includes a superelastic alloy member whose rigidity starts changing from a high-rigidity state to a low-rigidity state at a temperature, which varies with a degree of bending of the superelastic alloy member, and a heating member capable of switching between presence and absence of heating of the superelastic alloy member. The insertion system also includes a bending state detection sensor that detects a bending state of the rigidity variable portion, and a rigidity variable controller that controls switching between presence and absence of heating of the superelastic alloy member by the heating member to control the temperature of the superelastic alloy member.

Abstract: An endoscope system includes an insertion section, a first active bending section, a second active bending section, a position-information acquiring section, a first control section, a second control section, and a third control section. The first control section controls, based on a detection result of the position-information acquiring section, a first driving section of the first active bending section such that a first end portion of a first tubular section of the first active bending section moves away from a center point. The first control section controls a second driving section of the second active bending section such that a second end portion of a second tubular section of the second active bending section approaches the center point. The third control section controls the first driving section such that force in a direction of bending the first tubular section in a first bending operation acts on the first end portion.

Abstract: A variable stiffness actuator includes a shape-memory member capable of transitioning in phase between a first phase and a second phase. The shape-memory member takes a low-stiffness state when in the first phase, and takes a high-stiffness state. The variable stiffness actuator also includes an inducing member configured to cause the shape-memory member to transition in phase between the first phase and the second phase and a connecting member elastically connecting the shape-memory member and inducing member. All of the shape-memory member, the inducing member, and the connecting member are conductive, and the shape-memory member, the inducing member, and the connecting member are electrically connected to each other.

Abstract: A variable-stiffness actuator, installed in a flexible member and capable of providing different stiffnesses for the flexible member, includes a shape-memory member that can transit in phase between first and second phases and an inducing member that causes phase transition between the first and second phases into the shape-memory member. The shape-memory member takes, in the first stare, a flexible state in which it is easily deformable by an external force, so as to provide lower stiffness for the flexible member, and, in the second stare, a rigid state in which it tends to take a memorized shape against an external force, so as to provide higher stiffness for the flexible member. The actuator further includes a stiffness calculator that calculates the stiffness of the actuator.

Abstract: A variable stiffness actuator includes a shape-memory member, and a heater configured to receive power to heat the shape-memory member so as to cause the shape-memory member to change from a first phase as a low stiffness state to a second phase as a high stiffness state showing a higher stiffness than the low stiffness state. The actuator also includes a first conductive wire having one end connected to the heater and constituting a part of a power supply line for the heater, and a second conductive wire having one end connected to the other end of the first conductive wire, thicker than the first conductive wire, and having an electrical resistance per unit length lower than that of the first conductive wire.

Abstract: A variable stiffness actuator includes a shape-memory member capable of transitioning in phase between a first phase and a second phase. The shape-memory member takes a low-stiffness state when in the first phase, and takes a high-stiffness state. The variable stiffness actuator also includes an inducing member configured to cause the shape-memory member to transition in phase between the first phase and the second phase and a connecting member elastically connecting the shape-memory member and inducing member. All of the shape-memory member, the inducing member, and the connecting member are conductive, and the shape-memory member, the inducing member, and the connecting member are electrically connected to each other.

Abstract: A variable-stiffness actuator system includes a shape-memory member in which a stiffness increases by being heated and decreases by radiating heat, a heating member configured to generate heat, a channel arranged along the longitudinal axis of the shape-memory member, a transfer section configured to selectively supply and stop first and second heat transmission fluids into the channel, and a controller configured to control the transfer section. The controller causes the transfer section to supply the first heat transmission fluid and then supply the second heat transmission fluid into the channel, and further to stop the supply of the second heat transmission fluid so that retention of the first and second heat transmission fluids simultaneously occurs in the channel.

Abstract: An insertion system includes an insertion section and a rigidity variable portion provided in the insertion section. The rigidity variable portion includes a superelastic alloy member whose rigidity starts changing from a high-rigidity state to a low-rigidity state at a temperature, which varies with a degree of bending of the superelastic alloy member, and a heating member capable of switching between presence and absence of heating of the superelastic alloy member. The insertion system also includes a bending state detection sensor that detects a bending state of the rigidity variable portion, and a rigidity variable controller that controls switching between presence and absence of heating of the superelastic alloy member by the heating member to control the temperature of the superelastic alloy member.

Abstract: A shape measuring apparatus includes a cylindrical flexible body and a bend detection sensor. The sensor includes an optical fiber extending along the flexible body, a detection target to vary characteristics of detection light guided through the optical fiber in accordance with a curvature of the optical fiber, and a light detection unit to detect the detection light. The shape measuring apparatus also includes a shape calculating device to calculate a bend shape of the flexible body, based on the variation of the characteristics of the detection light, a cylindrical sheathing member sheathing a part of the optical fiber in the flexible body, and a hard distal member provided at a distal end of the flexible body and holding a distal end of the sheathing member.

Abstract: A variable-stiffness actuator includes a shape-memory member that has an end and another end and increases in stiffness on heating, and a heating member that is arranged along a longitudinal axis of the shape-memory member so as to surround an outside of the shape-memory member and receives a current to heat the shape-memory member. The variable-stiffness actuator also includes a conductive member arranged around an outer periphery of the heating member, so as to physically protect the heating member. The conductive member is electrically connected to the heating member.

Abstract: A variable-stiffness actuator, installed in a flexible member and capable of providing different stiffnesses for the flexible member, includes a shape-memory member that can transit in phase between first and second phases and an inducing member that causes phase transition between the first and second phases into the shape-memory member. The shape-memory member takes, in the first stare, a flexible state in which it is easily deformable by an external force, so as to provide lower stiffness for the flexible member, and, in the second stare, a rigid state in which it tends to take a memorized shape against an external force, so as to provide higher stiffness for the flexible member. The actuator further includes a stiffness calculator that calculates the stiffness of the actuator.

Abstract: A variable-stiffness actuator capable of providing different stiffnesses for a flexible member includes a shape-memory member that can transit in phase between a first phase and a second phase and an inducing member that causes phase transition between the first phase and the second phase into the shape-memory member. The shape-memory member is arranged in the flexible member with at least one free end. The shape-memory member takes a flexible state in which it is easily deformable by an external force when it is in the first stare, so as to provide lower stiffness for the flexible member. The shape-memory member takes a rigid state in which it tends to take a memorized shape memorized beforehand against an external force when it is in the second stare, so as to provide higher stiffness for the flexible member.

Abstract: The task of the present invention is to provide an inertial drive actuator having a small-size arrangement, without using a vibration substrate. The inertial drive actuator includes a coil, a movable body which is disposed in a direction in which, a magnetic flux of the coil is generated, and which is formed of a magnetic material having a surface facing the coil, and a displacement generator (piezoelectric element) which displaces the coil in a direction different from the direction in which the magnetic flux is generated. Moreover, the movable body is displaced relatively with respect to the displacement generator (piezoelectric element), along a direction of displacement of the displacement generator (piezoelectric element).

Abstract: An electromagnetic actuator includes an optical element L which is movable with respect to an optical axial direction, an optical-element holder which holds the optical element, a coil which is installed to enclose the optical element L and the optical-element holder, and a coil holder which holds the coil, wherein at least one of the optical-element holder and the coil holder comprises magnetic material which generates a magnetic flux in a radial direction and the optical element L is disposed at an inner side of the magnetic material.

Abstract: The task of the present invention is to provide an inertial drive actuator having a small-size arrangement, without using a vibration substrate. The inertial drive actuator includes a coil, a movable body which is disposed in a direction in which, a magnetic flux of the coil is generated, and which is formed of a magnetic material having a surface facing the coil, and a displacement generator (piezoelectric element) which displaces the coil in a direction different from the direction in which the magnetic flux is generated. Moreover, the movable body is displaced relatively with respect to the displacement generator (piezoelectric element), along a direction of displacement of the displacement generator (piezoelectric element).

Abstract: A calibration method for an inertial drive actuator of detecting a position of a moving body based on an electrostatic capacitance is proposed. The calibration method includes driving the moving body; outputting a first signal for detecting the electrostatic capacitance of opposing parts of a moving body side electrode provided on the moving body and a detecting electrode provided opposing the moving body side electrode; receiving a second signal obtained after the first signal output at the outputting has passed through the moving body side electrode and the detecting electrode; and calculating an optimum first signal based on the second signal received at the receiving.