Gas sensor, including a membrane and a heating element arranged on the membrane between a first discontinuation area of the membrane and a second discontinuation area of the membrane. The first discontinuation area of the membrane includes at least one discontinuation of the membrane and the second discontinuation area of the membrane includes at least one discontinuation of the membrane. The gas sensor further includes a first temperature sensor structure arranged at least partially on the membrane on a side of the first discontinuation area of the membrane opposite to the heating element, and a second temperature sensor structure arranged at least partially on the membrane on a side of the second discontinuation area of the membrane opposite to the heating element.

Proposed is a thermal mass flowmeter including: a heating unit configured to heat at least a portion of a medium in a tube from the outside of the tube; a first thermometer disposed at a first position that is a downstream side from the heating unit in a flow direction of the medium; a second thermometer disposed at a second position that is a downstream side further than the first thermometer from the heating unit; and a controller configured to calculate the flow rate of the medium flowing through the tube using a phase difference due to flow of the medium between first measurement data measured by the first thermometer and second measurement data measured by the second thermometer.

Methods and apparatuses associated with an example flow sensing device are provided. In some examples, the flow sensing device may include a flow cap component and a sensor component. In some examples, the flow cap component may include a heating element disposed in a first layer of the flow cap component. In some examples, the sensor component may include at least one thermal sensing element disposed in a second layer of the sensor component. In some examples, the first layer and the second layer are noncoplanar. In some examples, the flow cap component may be bonded to a first surface of the sensor component to form a flow channel. In some examples, the first layer and the second layer may be noncoplanar and separated by the flow channel.

An apparatus (10) for detecting flow of a fluid (11) in a conduit (12) is disclosed. The apparatus comprises means (44) for inferring the flow of fluid based on a change in temperature of the conduit over time. The means for inferring the flow of fluid may comprise a neural network model. One or more other environmental parameters may be used in addition to temperature. The disclosed embodiments can allow an estimate of the flow of fluid in the conduit to be obtained using a low-cost, low-power and/or non-invasive device.

An apparatus (10) for detecting flow of a fluid (11) in a conduit (12) is disclosed. The apparatus comprises means (44) for inferring the flow of fluid based on a change in temperature of the conduit over time. The means for inferring the flow of fluid may comprise a neural network model. One or more other environmental parameters may be used in addition to temperature. The disclosed embodiments can allow an estimate of the flow of fluid in the conduit to be obtained using a low-cost, low-power and/or non-invasive device.

A microneedle probe for measuring a sap flow in a plant is disclosed, the microneedle probe including: a substrate; and a sensor unit which is installed on the substrate, generates heat, and measures a temperature that changes in accordance with a sap flow.

A microneedle probe for measuring a sap flow in a plant is disclosed, the microneedle probe including: a substrate; and a sensor unit which is installed on the substrate, generates heat, and measures a temperature that changes in accordance with a sap flow.

A microneedle probe for measuring a sap flow in a plant is disclosed, the microneedle probe including: a substrate; and a sensor unit which is installed on the substrate, generates heat, and measures a temperature that changes in accordance with a sap flow.

A microneedle probe for measuring a sap flow in a plant is disclosed, the microneedle probe including: a substrate; and a sensor unit which is installed on the substrate, generates heat, and measures a temperature that changes in accordance with a sap flow.

Proposed is an air velocity sensor (meter) for measuring the flow velocity of a fluid, particularly, the air velocity of gas. More specifically, proposed is a technical field related to an air velocity sensor which measures air velocity or temperature through the heat transfer of a fluid by using a hot wire, that is, a heating element, of a small cross-section, and which expands the surface areas of a temperature sensor, the heating element, and a soldering part in order to further improve the accuracy of a hot wire flow velocity sensor having higher accuracy, even with respect to a low flow velocity, than a general mechanical anemometer, so as to minimize resistance, and thus can easily measure very low flow rates by inducing a quick change in a current to quickly respond to minute changes in resistance and sensitively operate, that is, by improving reaction speed.