Abstract: An actuator is configured to include a first substrate that has a first conductive surface, which may be or include a first conductive electrode layer. The actuator also includes a second substrate that has a second conductive surface, which may be or include a second conductive electrode layer. The first and second conductive surfaces face toward each other across a compression space between the first and second substrates. A group of elastic support nodules span the compression space and separate the first and second conductive surfaces. The compression space is less than fully filled with solid elastic material and is configured to be compressed by relative movement of the first and second conductive surfaces toward each other in response to a voltage difference between the first and second conductive surfaces.

Abstract: An actuator is configured to include a first substrate that has a first conductive surface, which maybe or include a first conductive electrode layer. The actuator also includes a second substrate that has a second conductive surface, which may be or include a second conductive electrode layer. The first and second conductive surfaces face toward each other across a compression space between the first and second substrates. A group of elastic support nodules span the compression space and separate the first and second conductive surfaces. The compression space is less than fully filled with solid elastic material and is configured to be compressed by relative movement of the first and second conductive surfaces toward each other in response to a voltage difference between the first and second conductive surfaces.

Abstract: An actuator is configured to include a first substrate that has a first conductive surface, which may be or include a first conductive electrode layer. The actuator also includes a second substrate that has a second conductive surface, which may be or include a second conductive electrode layer. The first and second conductive surfaces face toward each other across a compression space between the first and second substrates. A group of elastic support nodules span the compression space and separate the first and second conductive surfaces. The compression space is less than fully filled with solid elastic material and is configured to be compressed by relative movement of the first and second conductive surfaces toward each other in response to a voltage difference between the first and second conductive surfaces.

Abstract: An actuator is configured to include a first substrate that has a first conductive surface, which may be or include a first conductive electrode layer. The actuator also includes a second substrate that has a second conductive surface, which may be or include a second conductive electrode layer. The first and second conductive surfaces face toward each other across a compression space between the first and second substrates. A group of elastic support nodules span the compression space and separate the first and second conductive surfaces. The compression space is less than fully filled with solid elastic material and is configured to be compressed by relative movement of the first and second conductive surfaces toward each other in response to a voltage difference between the first and second conductive surfaces.

Abstract: A computerized method for determining a test subject's (TS) hearing threshold (HT). An acoustic stimulus (AS, 102) is applied the test subject's (TS) ear. The stimulus intensity is increased during a ramp, with a predetermined dependency on time, such that the intensity begins below the hearing threshold and ends above it. The test subject's brain response (104), which includes a transient brain response (TR)1 is non-invasively recorded during the ramp section. The stimulus-response cycle is repeated several times. The recorded brain responses and stored a-priori information on transient brain response to the acoustic stimulus are used to determine a combined time interval between the acoustic stimulus and the transient brain response. The test subject's hearing threshold is determined based on the predetermined dependency on time of the intensity during the ramp and the combined time interval between the acoustic stimulus and the transient brain response.

Abstract: An interface apparatus (1600A) comprises a surface (1642) touchable by a finger (120). The surface has a touch-sensitive area with a predetermined position (1646), to which a function is assigned. The finger's presence at the predetermined position (1646) is detected. An electrosensory stimulus is generated to the finger by applying an alternating electrical drive to one or more electrodes (1662). Each electrode is provided with an insulator, which prevents DC flow from the electrode to the finger and a capacitive coupling over the insulator is formed between the electrode (1662) and the finger (120). The capacitive coupling and electrical drive are dimensioned to produce an electrosensory sensation, independently of mechanical vibration of the electrode. The electrosensory stimulus is varied temporally based on the detected presence or absence of the of the finger (120) near the at least one touch-sensitive area having the predetermined position (1646).

Abstract: A computerized method for determining a test subject's (TS) hearing threshold (HT). An acoustic stimulus (AS, 102) is applied the test subject's (TS) ear. The stimulus intensity is increased during a ramp, with a predetermined dependency on time, such that the intensity begins below the hearing threshold and ends above it. The test subject's brain response (104), which includes a transient brain response (TR)1 is non-invasively recorded during the ramp section. The stimulus-response cycle is repeated several times. The recorded brain responses and stored a-priori information on transient brain response to the acoustic stimulus are used to determine a combined time interval between the acoustic stimulus and the transient brain response. The test subject's hearing threshold is determined based on the predetermined dependency on time of the intensity during the ramp and the combined time interval between the acoustic stimulus and the transient brain response.