Abstract: In electrosensory vibration technology, a potential difference is formed between a touched surface of a device and a body member of a user, creating an attractive force between the two. To meet industry safety standards, the capability of a corresponding voltage source to drive electrical current may be kept low, and the maximum slew rate with such a voltage source would be accordingly limited. However, such a limit on the slew rate may result in softer haptic effects or lower repetition rates of haptic effects, and the ability of such a device to express a wide range of haptic effects may be reduced compared to a device capable of driving the external load with the maximum current allowed by applicable standards. As a technical means to solve this technical problem, it may be helpful to use a powerful voltage source with a controller to control the outgoing current.

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: Embodiments of tactile stimulation apparatuses and components of such apparatuses are generally described herein. For example, in one embodiment, a tactile stimulation apparatus is provided. This tactile stimulation apparatus has a composite section comprising an insulation region and a semiconducting region that is proximate to the insulation region. This insulation region is touchable by a body member. Additionally included is a voltage source proximate to the semiconducting region. Here, the voltage source is configured to charge the semiconducting region to an electric potential, which produces an electrosensory sensation on the body member.

Abstract: A high-resistance laminate includes a transparent substrate and a high-resistance layer formed upon the transparent substrate. The high-resistance layer contains an oxide that includes tin and titanium as main components. The atomic ratio of the tin to the titanium (Sn/Ti) is 80/20 to 95/5, and the surface resistivity value of the high-resistance layer is 1 to 100 megaohms per square. A barrier layer can be interposed between the transparent substrate and the high-resistance layer. This high-resistance laminate may form all or part of a high-resistance layer within a front panel for a tactile sensor. Such a tactile sensor may include the high resistance layer and an insulating layer.

Abstract: In an embodiment, a voltage amplifier is provided. In this voltage amplifier, a DC/DC boost converter converts an input DC voltage to an output DC voltage, which is higher than the input DC voltage. A DC/AC converter connected to the DC/DC boost converter converts the output DC voltage to an AC pulse-train. A voltage multiplier connected to the DC/AC converter converts the AC pulse-train to an amplified output DC voltage that is higher than the AC pulse-train. A discharger connected to the voltage multiplier can discharge the amplified output DC voltage.

Abstract: A haptic companion device may take the example form of a haptic cover that includes a housing and a transparent component. The housing may be shaped and dimensioned to receive a host device that includes a touch screen, and the touch screen may be configured to sense an input by a body member of a user of the host device. The transparent component overlays the touch screen of the host device when the haptic companion device is in use, and graphical objects displayed on the touch screen of the host device are visible through the transparent component. The haptic companion device includes a communication interface configured to communicatively couple the haptic companion device with the host device. The haptic companion device also includes electronic circuitry coupled to the transparent component. The electronic circuitry is configured to provide a haptic effect to the body member via the transparent component.

Abstract: Embodiments of tactile stimulation apparatuses and components of such apparatuses are generally described herein. For example, in one embodiment, a tactile stimulation apparatus is provided. This tactile stimulation apparatus has a composite section comprising an insulation region and a semiconducting region that is proximate to the insulation region. This insulation region is touchable by a body member. Additionally included is a voltage source proximate to the semiconducting region. Here, the voltage source is configured to charge the semiconducting region to an electric potential, which produces an electrosensory sensation on the body member.

Abstract: Embodiments of tactile stimulation apparatuses and components of such apparatuses are generally described herein. For example, in one embodiment, a tactile stimulation apparatus is provided. This tactile stimulation apparatus has a composite section comprising an insulation region and a semiconducting region that is proximate to the insulation region. This insulation region is touchable by a body member. Additionally included is a voltage source proximate to the semiconducting region. Here, the voltage source is configured to charge the semiconducting region to an electric potential, which produces an electrosensory sensation on the body member.

Abstract: An apparatus for presenting a time-variant information element in a vehicle, which has a steering wheel (1602), comprises one or more remotely and individually controllable tactile pads (1620), which produce a tactile sensation in response to a respective pad output signal, which is produced by a controller (CTRL). The tactile pads are positioned or adapted to be positioned on the steering wheel (1602) or proximate to it, such that they can be touched by at least one hand (1610,1612) of the vehicle driver while driving the vehicle. The apparatus further comprises means for determining the time-variant information element to be presented and for applying the determined time-variant information element to the controller and means for encoding the determined time-variant information element by the controller into temporal variations of the one or more pad output signals.

Abstract: An apparatus for presenting a time-variant information element in a vehicle, which has a steering wheel (1602), comprises one or more remotely and individually controllable tactile pads (1620), which produce a tactile sensation in response to a respective pad output signal, which is produced by a controller (CTRL). The tactile pads are positioned or adapted to be positioned on the steering wheel (1602) or proximate to it, such that they can be touched by at least one hand (1610,1612) of the vehicle driver while driving the vehicle. The apparatus further comprises means for determining the time-variant information element to be presented and for applying the determined time-variant information element to the controller and means for encoding the determined time-variant information element by the controller into temporal variations of the one or more pad output signals.

Abstract: An apparatus for producing an electrosensory sensation to a body member (120). The apparatus comprises one or more conducting electrodes (106), each of which is provided with an insulator (108). When the body member (120) is proximate to the conducting electrode, the insulator prevents flow of direct current from the conducting electrode to the body member. A capacitive coupling over the insulator (108) is formed between the conducting electrode (106) and the body member (120). The conducting electrodes are driven by an electrical input which comprises a low-frequency component (114) in a frequency range between 10 Hz and 500 Hz. The capacitive coupling and electrical input are dimensioned to produce an electrosensory sensation. The apparatus is capable of producing the electrosensory sensation independently of any mechanical vibration of the one or more conducting electrodes (106) or insulators (108).

Abstract: An apparatus for producing an electrosensory sensation to a body member (120). The apparatus comprises one or more conducting electrodes (106), each of which is provided with an insulator (108). When the body member (120) is proximate to the conducting electrode, the insulator prevents flow of direct current from the conducting electrode to the body member. A capacitive coupling over the insulator (108) is formed between the conducting electrode (106) and the body member (120). The conducting electrodes are driven by an electrical input which comprises a low-frequency component (114) in a frequency range between 10 Hz and 500 Hz. The capacitive coupling and electrical input are dimensioned to produce an electrosensory sensation. The apparatus is capable of producing the electrosensory sensation independently of any mechanical vibration of the one or more conducting electrodes (106) or insulators (108).