A device includes at least one electrode unit for an electrostimulation or a data acquisition by diagnostic instruments. The device is formed from a textile material and has at least two layers. The at least one electrode unit is disposed in or on a first layer, and a second layer is disposed on the first layer in such a way that the first layer and the second layer form at least one pocket. At least one support-pad part is disposed exchangeably in the pocket.

A device includes at least one electrode unit for an electrostimulation or a data acquisition by diagnostic instruments. The device is formed from a textile material and has at least two layers. The at least one electrode unit is disposed in or on a first layer, and a second layer is disposed on the first layer in such a way that the first layer and the second layer form at least one pocket. At least one support-pad part is disposed exchangeably in the pocket.

A first layer (301) has an outer surface (302) facing away from the wearer and an inner surface (304) facing towards the wearer. The first layer (301) comprises a recess (303a, 303b). A sensing component (100a, 100b) is attached to he inner surface (304) and comprises fabric base component (101) and first and second conductive regions (109a, 109b, 111a, 111b). The base component (101) has an outer surface (105) facing the inner surface (304) and an inner surface (103) facing towards the wearer. The first conductive region (109a, 109b) is provided on the inner surface (103) and forms an electrode. The second conductive region (111a, 111b) is provided on the outer surface (105). The second conductive region (111a, 111b) is aligned with the recess (303a, 303b) in the first layer of material (301) and forms a connection terminal for connecting with an interface element of an electronics module (200).

A first layer (301) has an outer surface (302) facing away from the wearer and an inner surface (304) facing towards the wearer. The first layer (301) comprises a recess (303a, 303b). A sensing component (100a, 100b) is attached to he inner surface (304) and comprises fabric base component (101) and first and second conductive regions (109a, 109b, 111a, 111b). The base component (101) has an outer surface (105) facing the inner surface (304) and an inner surface (103) facing towards the wearer. The first conductive region (109a, 109b) is provided on the inner surface (103) and forms an electrode. The second conductive region (111a, 111b) is provided on the outer surface (105). The second conductive region (111a, 111b) is aligned with the recess (303a, 303b) in the first layer of material (301) and forms a connection terminal for connecting with an interface element of an electronics module (200).

A garment for measuring biological information equipped with an electrode and wiring, with which noise can be prevented from being mixed in to the biological electric signals to be read, and with which a wearer feels less discomfort, even under dry condition while the garment is worn. Static electrical charge generated while the garment is worn is suppressed to decrease the noise in the biological electric signals to be read by selecting a combination of electrically insulating materials constituting the garment that have smaller gap of frictional electrostatic voltage, as well as using the electrode and wiring that are stretchy and have high conductivity even when being stretched to reduce discomfort while the garment is worn.

A device and method for detecting control-point activation conditions corresponding to a portion of a glove body coming in contact with or being within a threshold distance from at least one of another portion of the glove body or a control surface separate from the glove body. The glove may include a conductive path attached to the glove body and an expanded conductive area conductively coupled to the conductive path and attached to the glove body. The expanded conductive area may be wider than individual portions of the conductive path.

The present disclosure provides an apparatus and a processing unit configured for sensing electrical activity with improved temporal and spatial electrode configuration. The apparatus includes a first layer configured to collect pressure data and a second layer comprising a plurality of electrodes configured to sense electrical activity. The processing unit is communicatively coupled to the apparatus to select a subset of the plurality of electrodes of the second layer from which electrical activity is measured based on an orientation of a user determined by received pressure data from the first layer. In an example, a body map of an individual can be produced from pressure distribution information received from the apparatus. This body map can then be used to select specific electrodes to measure the individual's electrical activity based on the body map pressure distribution information.

An object is to provide a garment-type biological information measurement device having a biological contact-type electrode and having excellent durability against washing. A garment-type biological information measurement device comprising an electrode, wherein the electrode comprises a stretchable conductive layer containing a flexible resin and a conductive filler, a stretchable adhesion acceleration layer, a stretchable hot melt adhesive layer, and a garment fabric, in this order.

An object is to provide a garment-type biological information measurement device having a biological contact-type electrode and having excellent durability against washing. A garment-type biological information measurement device comprising an electrode, wherein the electrode comprises a stretchable conductive layer containing a flexible resin and a conductive filler, a stretchable adhesion acceleration layer, a stretchable hot melt adhesive layer, and a garment fabric, in this order.

The present invention will provide a measuring device embedded within an elastic garment that will provide detect bodily movement by deforming a conductive material and measuring the change in electrical quantities within the conductive material as it deforms. Furthermore, the present invention will provide a measuring device configured to incorporate machine learning algorithms to estimate physiological, kinematic, dynamic, psychological, physical, biological, or other health parameters based upon the variations in electrical quantities within the conductive material as it deforms. This is accomplished through an elastic textile, a conductive element embedded within the elastic textile, and an electronic device configured to measure electrical quantities of the conductive element. These elements work in conjunction to detect and monitor movement in the human body.