Abstract: A micro-hotplate comprises a Si substrate having a cavity and a support layer over the cavity; at least an electrode; and a heater, both provided on the support layer. The electrode surrounds the heater and the heater is disposed inside the electrode. The power efficiency of the micro-hotplate is improved.

Abstract: A gas sensor is proposed, which can detect a gas by a novel configuration while reduction in size is achieved. The gas sensor (1) does not need a light absorption path as in a prior art so that the size can be reduced correspondingly. Further, in the gas sensor (1), a gas is absorbed in an ionic liquid (IL), and a dielectric constant of the ionic liquid (IL) that changes by absorbing the gas can be measured according to a change in light intensity that occurs by a surface plasmon resonance phenomenon in a metal layer (7). Thus, the gas sensor (1) including the novel configuration that can detect a gas based on the change in the light intensity can be realized.

Abstract: A gas sensor that can enhance gas detection sensitivity more than the conventional sensors with a simple configuration is proposed. An electric double layer including a gate insulating layer is formed in an ionic liquid (IL), a change of a state of the gate insulating layer in the ionic liquid (IL) that occurs by absorbing a gas is directly reflected in a source-drain current (Isd) that flows in a carbon nanotube (8). Therefore, the gas detection sensitivity can be enhanced more than in the conventional sensors. Further, since the ionic liquid (IL) can be simply provided on a substrate (2) to be in contact with the carbon nanotube (8) and a gate electrode (7), the configuration that chemically modifies a surface of the carbon nanotube with a plurality of polymers as in the conventional gas sensors is not needed, and the configuration can be simplified correspondingly.

Abstract: A wireless sensor module has a sensor that measures a measuring object to generate measured data, a wireless communication section that wirelessly transmits the measured data to an external device and receives a radio signal from the external device, a control section that controls the sensor and the wireless communication section, and an electric power storage device that serves as an electric power supply. The control section secures an idle period of time in a series of operations for processing the measured data so that the series of operations are not carried out consecutively. The series of operations includes an operation in which the sensor generates the measured data, and an operation in which the wireless communication section wirelessly transmits the measured data to the external device.

Abstract: To propose a gas sensor and a gas sensor structural body that can improve detection sensitivity of gas more than in the conventional gas sensors with a simple configuration. A graphene (8) between a source electrode (3) and a drain electrode (4) is provided in an ion liquid (L), whereby a state change of charges in the ion liquid (L) caused by absorption of gas is directly reflected on a source-drain current (Isd) that flows in the graphene (8). Therefore, it is possible to improve detection sensitivity of the gas more than in the conventional gas sensors. The graphene (8) only has to be provided to be disposed in the ion liquid (L). Therefore, unlike in the conventional gas sensors, a configuration in which carbon nanotubes are surface-chemically modified by a plurality of polymers is unnecessary. Therefore, it is possible to simplify a configuration.

Abstract: A gas sensor is proposed, which can detect a gas by a novel configuration while reduction in size is achieved. The gas sensor (1) does not need a light absorption path as in a prior art so that the size can be reduced correspondingly. Further, in the gas sensor (1), a gas is absorbed in an ionic liquid (IL), and a dielectric constant of the ionic liquid (IL) that changes by absorbing the gas can be measured according to a change in light intensity that occurs by a surface plasmon resonance phenomenon in a metal layer (7). Thus, the gas sensor (1) including the novel configuration that can detect a gas based on the change in the light intensity can be realized.

Abstract: A gas sensor that can enhance gas detection sensitivity more than the conventional sensors with a simple configuration is proposed. An electric double layer including a gate insulating layer is formed in an ionic liquid (IL), a change of a state of the gate insulating layer in the ionic liquid (IL) that occurs by absorbing a gas is directly reflected in a source-drain current (Isd) that flows in a carbon nanotube (8). Therefore, the gas detection sensitivity can be enhanced more than in the conventional sensors. Further, since the ionic liquid (IL) can be simply provided on a substrate (2) to be in contact with the carbon nanotube (8) and a gate electrode (7), the configuration that chemically modifies a surface of the carbon nanotube with a plurality of polymers as in the conventional gas sensors is not needed, and the configuration can be simplified correspondingly.

Abstract: A wireless sensor module has a sensor that measures a measuring object to generate measured data, a wireless communication section that wirelessly transmits the measured data to an external device and receives a radio signal from the external device, a control section that controls the sensor and the wireless communication section, and an electric power storage device that serves as an electric power supply. The control section secures an idle period of time in a series of operations for processing the measured data so that the series of operations are not carried out consecutively. The series of operations includes an operation in which the sensor generates the measured data, and an operation in which the wireless communication section wirelessly transmits the measured data to the external device.

Abstract: A multi-directional input key is capable of plural inputs through multi-directional operation, wherein the plural inputs are realized by a novel multi-directional operation, instead of the conventional operation in which force is applied to the operation surface so as to push it in deeply. There is provided a central key top equipped with an upper key top protruding from an insertion hole of an outer-ring key top and a lower key top having a pushing member protruding downwardly therefrom. This central key top is supported on a key sheet so as to be slidable in the direction of the hole inner surface of the insertion hole. And, when the central key top is caused to slide, an upper contact and a lower contact of a membrane switch are brought into contact with each other to effect input under the pressure from the pushing member.

Abstract: A multi-directional input key is capable of plural inputs through multi-directional operation, wherein the plural inputs are realized by a novel multi-directional operation, instead of the conventional operation in which force is applied to the operation surface so as to push it in deeply. There is provided a central key top equipped with an upper key top protruding from an insertion hole of an outer-ring key top and a lower key top having a pushing member protruding downwardly therefrom. This central key top is supported on a key sheet so as to be slidable in the direction of the hole inner surface of the insertion hole. And, when the central key top is caused to slide, an upper contact and a lower contact of a membrane switch are brought into contact with each other to effect input under the pressure from the pushing member.