Abstract: A grip detection device comprises an electrostatic capacity sensor mounted on a rim of a steering wheel; and a determination unit that detects gripping of the steering wheel based on a detection result of the electrostatic capacity sensor, a plurality of electrode units of elongated shape configuring the electrostatic capacity sensor extending along a direction in which the rim extends and being provided in parallel along a circumferential direction of the rim, of the plurality of electrode units, at least two electrode units are commonly connected, and at least one electrode unit not commonly connected to the commonly connected two electrode units is disposed between the commonly connected two electrode units, the determination unit determining that a driver has gripped the steering wheel when proximity of a human body has been detected by each of at least two electrode units not commonly connected to each other.

Abstract: A grip detection device comprises an electrostatic capacity sensor mounted on a rim of a steering wheel; and a determination unit that detects gripping of the steering wheel based on a detection result of the electrostatic capacity sensor, a plurality of electrode units of elongated shape configuring the electrostatic capacity sensor extending along a direction in which the rim extends and being provided in parallel along a circumferential direction of the rim, of the plurality of electrode units, at least two electrode units are commonly connected, and at least one electrode unit not commonly connected to the commonly connected two electrode units is disposed between the commonly connected two electrode units, the determination unit determining that a driver has gripped the steering wheel when proximity of a human body has been detected by each of at least two electrode units not commonly connected to each other.

Abstract: An occupant position detection device is an occupant position detection device disposed inside a vehicle to detect a position of an occupant, and includes: a detector comprising two or more sensor electrodes disposed forward of a seat and at least one sensor electrode disposed at a position more rearward and higher than these sensor electrodes, the detector respectively outputting a detection signal based on a distance between each of the sensor electrodes and the occupant; and a computation unit inputted with the detection signal to compute an occupant position. The computation unit selects from the detection signals outputted from the detector three or more types of combinations configured from two of the detection signals, calculates a ratio or difference for each of these combinations of detection signals, and computes the occupant position based on the three or more calculated ratios or differences of the detection signals.

Abstract: A loop antenna in accordance with the present invention has an antenna element having a shape that traces a closed curve, the antenna element including (i) a first projection section which projects from one of two end sections of the antenna element toward an inside of the closed curve and (ii) a second projection section which projects from the other of the two end sections of the antenna element toward the inside of the closed curve, each of the first projection section and the second projection section including a feed point.

Abstract: A dipole antenna in accordance with the present invention includes a first antenna element provided in a two-dimensional surface and having a linear shape and a second antenna element provided in the two-dimensional surface and having a spiral shape that circles around the first antenna element.

Abstract: The disclosure has: a detection electrode (2) that detects an electrostatic capacitance; a shield electrode (3); a shield drive circuit (31) that switches between a first electric potential and a second electric potential to apply the first or second electric potential to the shield electrode; a detection circuit (21) that outputs a detection signal depending on the electrostatic capacitance detected; and a determination circuit (6) that obtains a first detection signal and a second detection signal as the basis to determine whether an abnormality of the detection electrode (2) or the shield electrode is present or absent. The first detection signal depends on the electrostatic capacitance detected when the shield drive means (31) applies the first electric potential to the shield electrode (3). The second detection signal depends on the electrostatic capacitance detected when the shield drive means (31) applies the second electric potential to the shield electrode.

Abstract: An occupant position detection device is an occupant position detection device disposed inside a vehicle to detect a position of an occupant, and includes: a detector comprising two or more sensor electrodes disposed forward of a seat and at least one sensor electrode disposed at a position more rearward and higher than these sensor electrodes, the detector respectively outputting a detection signal based on a distance between each of the sensor electrodes and the occupant; and a computation unit inputted with the detection signal to compute an occupant position. The computation unit selects from the detection signals outputted from the detector three or more types of combinations configured from two of the detection signals, calculates a ratio or difference for each of these combinations of detection signals, and computes the occupant position based on the three or more calculated ratios or differences of the detection signals.

Abstract: A loop antenna in accordance with the present invention has an antenna element having a shape that traces a closed curve, the antenna element including (i) a first projection section which projects from one of two end sections of the antenna element toward an inside of the closed curve and (ii) a second projection section which projects from the other of the two end sections of the antenna element toward the inside of the closed curve, each of the first projection section and the second projection section including a feed point.

Abstract: A dipole antenna in accordance with the present invention includes a first antenna element provided in a two-dimensional surface and having a linear shape and a second antenna element provided in the two-dimensional surface and having a spiral shape that circles around the first antenna element.

Abstract: A capacitive proximity sensor (100) comprises a sensor unit (10) and a sense circuit unit (20). The sensor unit (10) includes a sensor electrode (11), a shield electrode (12) and an auxiliary electrode (13). The sensor electrode (11) is connected to a C-V conversion circuit (21) and the shield electrode (12) is connected to a shield drive circuit (24). The auxiliary electrode (13) is connected via a change-over switch (30) to the C-V conversion circuit (21) or the shield drive circuit (24). The capacitance values (C1, C2) switched by the change-over switch (30) and detected at the C-V conversion circuit (21) are compared to arbitrarily set a range of a sense region on the sensor electrode (11).

Abstract: To be configured inexpensively to enable cost reduction and sense sitting posture of an occupant highly accurately, occupant posture sensing apparatus 100 includes capacitance sensor unit 10 and circuit unit 20. Capacitance sensor unit 10 includes first and second sensing electrodes 11 and 12 provided at portions of vehicle interior ceiling 2 ahead of and right above a seat 40 and connected to capacitance sensing circuit 21 of circuit unit 20 and shield-driving circuit 23 through selector switches SW1 and SW2. CPU 29 of circuit unit 20 determines sitting posture of occupant (human body) 48 sitting on the seat 40 based on information regarding position of head 49 of the occupant 48 by using capacitance values detected by capacitance sensing circuit 21 based on capacitances from sensing electrodes 11 and 12. Posture information regarding the determined sitting posture is output to ECU mounted on a vehicle 1 and used for controlling air bag deployment, etc.

Abstract: To perform highly precise position adjustment for head restraint in short time regardless of distance between head restraint and human body and head shape. Head restraint position adjusting device 100 includes capacitance sensor unit 10 and drive motor unit 30. Capacitance sensor unit 10 includes first and third sensing electrodes 11 and 13 and detection circuit 20. First sensing electrode 11 is arranged in an upper portion of front portion of head restraint 43 and senses capacitance between itself and vicinity of parietal region 49a of head 49 of human body 48. Third sensing electrode 13 is arranged in lower portion of front portion and senses capacitance between itself and any portion of human body 48 other than vicinity of parietal region 49a.

Abstract: To enable position or distance of sensing target making approach, etc. to the range of sensing area to be detected securely with simple configuration at low cost and improve latitude of designing, position detector includes capacitance sensor unit and detecting circuit unit. Capacitance sensor unit includes first and second sensing electrodes and dielectric material therebetween. Dielectric material has range L of sensing area defined on its sensing surface. Detecting circuit unit includes selector switches SWA and SWB, capacitance sensing circuits, A/D converters, and arithmetic processing circuit. Arithmetic processing circuit judges and detects the position of sensing target in range L of sensing area based on detected values of capacitances C1 and C2 sensed by first and second sensing electrodes under switching control on selector switches SWA and SWB.

Abstract: An antenna integrated harness in accordance with an embodiment of the present invention includes: a wire harness formed by bundling a plurality of electric cables; an antenna element which is two-dimensional planar and is provided on, while conforming to, a surface of the wire harness; and a feed line connected with the antenna element and bundled with the plurality of electric cables.

Abstract: An antenna device includes: a plate-like antenna having an electrically conductive path arranged in a two-dimensional manner, the electrically conductive path having a meander shape which is made up of at least one return pattern; and a base member, while causing the antenna to be spaced away from an outer surface of a body containing an electrically conductive material layer of a movable body, holding the antenna in such a manner as to conform to the outer surface, the base member being made from a dielectric material.

Abstract: The disclosure has: a detection electrode (2) that detects an electrostatic capacitance; a shield electrode (3); a shield drive circuit (31) that switches between a first electric potential and a second electric potential to apply the first or second electric potential to the shield electrode; a detection circuit (21) that outputs a detection signal depending on the electrostatic capacitance detected; and a determination circuit (6) that obtains a first detection signal and a second detection signal as the basis to determine whether an abnormality of the detection electrode (2) or the shield electrode is present or absent. The first detection signal depends on the electrostatic capacitance detected when the shield drive means (31) applies the first electric potential to the shield electrode (3). The second detection signal depends on the electrostatic capacitance detected when the shield drive means (31) applies the second electric potential to the shield electrode.

Abstract: To be configured inexpensively to enable cost reduction and sense sitting posture of an occupant highly accurately, occupant posture sensing apparatus 100 includes capacitance sensor unit 10 and circuit unit 20. Capacitance sensor unit 10 includes first and second sensing electrodes 11 and 12 provided at portions of vehicle interior ceiling 2 ahead of and right above a seat 40 and connected to capacitance sensing circuit 21 of circuit unit 20 and shield-driving circuit 23 through selector switches SW1 and SW2. CPU 29 of circuit unit 20 determines sitting posture of occupant (human body) 48 sitting on the seat 40 based on information regarding position of head 49 of the occupant 48 by using capacitance values detected by capacitance sensing circuit 21 based on capacitances from sensing electrodes 11 and 12. Posture information regarding the determined sitting posture is output to ECU mounted on a vehicle 1 and used for controlling air bag deployment, etc.

Abstract: To enable position or distance of sensing target making approach, etc. to the range of sensing area to be detected securely with simple configuration at low cost and improve latitude of designing, position detector includes capacitance sensor unit and detecting circuit unit. Capacitance sensor unit includes first and second sensing electrodes and dielectric material therebetween. Dielectric material has range L of sensing area defined on its sensing surface. Detecting circuit unit includes selector switches SWA and SWB, capacitance sensing circuits, A/D converters, and arithmetic processing circuit. Arithmetic processing circuit judges and detects the position of sensing target in range L of sensing area based on detected values of capacitances C1 and C2 sensed by first and second sensing electrodes under switching control on selector switches SWA and SWB.

Abstract: A capacitive proximity sensor (100) comprises a sensor unit (10) and a sense circuit unit (20). The sensor unit (10) includes a sensor electrode (11), a shield electrode (12) and an auxiliary electrode (13). The sensor electrode (11) is connected to a C-V conversion circuit (21) and the shield electrode (12) is connected to a shield drive circuit (24). The auxiliary electrode (13) is connected via a change-over switch (30) to the C-V conversion circuit (21) or the shield drive circuit (24). The capacitance values (C1, C2) switched by the change-over switch (30) and detected at the C-V conversion circuit (21) are compared to arbitrarily set a range of a sense region on the sensor electrode (11).

Abstract: To perform highly precise position adjustment for head restraint in short time regardless of distance between head restraint and human body and head shape. Head restraint position adjusting device 100 includes capacitance sensor unit 10 and drive motor unit 30. Capacitance sensor unit 10 includes first and third sensing electrodes 11 and 13 and detection circuit 20. First sensing electrode 11 is arranged in an upper portion of front portion of head restraint 43 and senses capacitance between itself and vicinity of parietal region 49a of head 49 of human body 48. Third sensing electrode 13 is arranged in lower portion of front portion and senses capacitance between itself and any portion of human body 48 other than vicinity of parietal region 49a.