Abstract: A wearable electronic device comprises a base for mounting a plurality of sensors, where the sensors acquiring physiological data of a user wearing the device. By providing multiple sensors on a single device, additional physiological data, such as pulse transit time, can be provided. To ensure quality data is collected, the device includes a spring mechanism for applying a compressive force on the sensor to force it into the skin of a user.

Abstract: An apparatus for communication, a system thereof, and methods of manufacture thereof are provided. The apparatus comprises a body and a printed circuit board (PCB) operatively coupled to the body. The PCB comprises a processing unit, a first communication module operatively coupled to the processing unit, and an array of assemblies. The first communication module is configured to communicate with a secondary communication module wirelessly. The array of assemblies comprises at least two rows and at least two columns. Each assembly comprises a switch and a light. The array of assemblies are operatively coupled to the processing unit. Each light is configured to change a state responsive to at least one of a change in state by the switch within the same assembly and a control signal from the first communication module.

Abstract: An apparatus for communication, a system thereof, and methods of manufacture thereof are provided. The apparatus comprises a body and a printed circuit board (PCB) operatively coupled to the body. The PCB comprises a processing unit, a first communication module operatively coupled to the processing unit, and an array of assemblies. The first communication module is configured to communicate with a secondary communication module wirelessly. The array of assemblies comprises at least two rows and at least two columns. Each assembly comprises a switch and a light. The array of assemblies are operatively coupled to the processing unit. Each light is configured to change a state responsive to at least one of a change in state by the switch within the same assembly and a control signal from the first communication module.

Abstract: According to one embodiment is a flexible circuit comprising a flexible base, a conductive polymer supported by the base, and an integrated circuit component having an elongated electrical contact, wherein the elongated electrical contact penetrates into the conductive polymer, thereby providing a robust electrical connection. According to methods of certain embodiments, the flexible circuit is manufactured using a molding process, where a conductive polymer is deposited into recesses in a mold, integrated circuit components are placed in contact with the conductive polymer, and a flexible polymer base is poured over the mold prior to curing. In an alternative embodiment, a multiple-layer flexible circuit is manufacturing using a plurality of molds.

Abstract: An apparatus for communication, a system thereof, and methods of manufacture thereof are provided. The apparatus comprises a body and a printed circuit board (PCB) operatively coupled to the body. The PCB comprises a processing unit, a first communication module operatively coupled to the processing unit, and an array of assemblies. The first communication module is configured to communicate with a secondary communication module wirelessly. The array of assemblies comprises at least two rows and at least two columns. Each assembly comprises a switch and a light. The array of assemblies are operatively coupled to the processing unit. Each light is configured to change a state responsive to at least one of a change in state by the switch within the same assembly and a control signal from the first communication module.

Abstract: A drug delivery device having an array of solid microneedles embedded with drugs and a light-to-heat-transducing (LTHT) element and a flexible printed circuit board containing a light source, such as a light emitting diode, which can be activated to release the drug embedded in the microneedles through localized melting. The device is worn in contact with the skin of a user, which enables the microneedles penetrate the upper layers of the user's skin. Although in contact with a user's skin, the drugs are not delivered until the device is activated. Activation can occur by an external signal received by the device or through a signal based on a physiological state of the user determined through a sensor in a closed-loop control system.

Abstract: A wearable electronic device comprises a base for mounting a plurality of sensors, where the sensors acquiring physiological data of a user wearing the device. By providing multiple sensors on a single device, additional physiological data, such as pulse transit time, can be provided. To ensure quality data is collected, the device includes a spring mechanism for applying a compressive force on the sensor to force it into the skin of a user.

Abstract: At least one tactile sensor includes an insulating layer and a conductive layer formed on the surface of the insulating layer. The conductive layer defines at least one group of flexible projections extending orthogonally from the surface of the insulating layer. The flexible projections include a major projection extending a distance orthogonally from the surface and at least one minor projection that is adjacent to and separate from the major projection wherein the major projection extends a distance orthogonally that is greater than the distance that the minor projection extends orthogonally. Upon a compressive force normal to, or a shear force parallel to, the surface, the major projection and the minor projection flex such that an electrical contact resistance is formed between the major projection and the minor projection. A capacitive tactile sensor is also disclosed that responds to the normal and shear forces.

Abstract: At least one tactile sensor includes an insulating layer and a conductive layer formed on the surface of the insulating layer. The conductive layer defines at least one group of flexible projections extending orthogonally from the surface of the insulating layer. The flexible projections include a major projection extending a distance orthogonally from the surface and at least one minor projection that is adjacent to and separate from the major projection wherein the major projection extends a distance orthogonally that is greater than the distance that the minor projection extends orthogonally. Upon a compressive force normal to, or a shear force parallel to, the surface, the major projection and the minor projection flex such that an electrical contact resistance is formed between the major projection and the minor projection. A capacitive tactile sensor is also disclosed that responds to the normal and shear forces.

Abstract: At least one tactile sensor includes an insulating layer and a conductive layer formed on the surface of the insulating layer. The conductive layer defines at least one group of flexible projections extending orthogonally from the surface of the insulating layer. The flexible projections include a major projection extending a distance orthogonally from the surface and at least one minor projection that is adjacent to and separate from the major projection wherein the major projection extends a distance orthogonally that is greater than the distance that the minor projection extends orthogonally. Upon a compressive force normal to, or a shear force parallel to, the surface, the major projection and the minor projection flex such that an electrical contact resistance is formed between the major projection and the minor projection. A capacitive tactile sensor is also disclosed that responds to the normal and shear forces.

Abstract: At least one tactile sensor includes an insulating layer and a conductive layer formed on the surface of the insulating layer. The conductive layer defines at least one group of flexible projections extending orthogonally from the surface of the insulating layer. The flexible projections include a major projection extending a distance orthogonally from the surface and at least one minor projection that is adjacent to and separate from the major projection wherein the major projection extends a distance orthogonally that is greater than the distance that the minor projection extends orthogonally. Upon a compressive force normal to, or a shear force parallel to, the surface, the major projection and the minor projection flex such that an electrical contact resistance is formed between the major projection and the minor projection. A capacitive tactile sensor is also disclosed that responds to the normal and shear forces.