Embodiments of the present invention relate to freshness indication. In some embodiments, a freshness indicating device is provided. The freshness indicating device comprises a collector and an indicator. The collector is adapted to collect water from an object. The object includes at least one of fruits and vegetables. The indicator is adapted to indicate the freshness of the object based on the amount of the collected water. A corresponding method and a container comprising the freshness indicating device are disclosed as well.

A method for homogenizing the height of a plurality of wires from the plurality of wires erected on a face of a substrate, the method including a first step of coating the face of the substrate including the plurality of wires with a first film, the first film embedding the plurality of wires over a first height; a second step of coating the first film with a second film, the second film embedding at least one part of the plurality of wires over a second height; a step of removing the second film, the part of the wires of the plurality of wires embedded in the second film being removed at the same time as the second film, a mechanical stress between the first film and the second film being exerted during the removal step.

A method for homogenizing the height of a plurality of wires from the plurality of wires erected on a face of a substrate, the method including a first step of coating the face of the substrate including the plurality of wires with a first film, the first film embedding the plurality of wires over a first height; a second step of coating the first film with a second film, the second film embedding at least one part of the plurality of wires over a second height; a step of removing the second film, the part of the wires of the plurality of wires embedded in the second film being removed at the same time as the second film, a mechanical stress between the first film and the second film being exerted during the removal step.

An ultrasonic sensor which includes a substrate where an opening section is formed, a vibration plate that is provided on the substrate so as to close the opening section, and a piezoelectric element that is layered on a surface of the vibration plate on an opposite side to the opening section and includes a first electrode, a piezoelectric element, and a second electrode, includes a reflection layer that is provided in a space around the piezoelectric element on the surface of the vibration plate on an opposite side to the opening section, to reflect other ultrasonic waves which are transmitted in a different direction from a transmitted ultrasonic wave transmitted to a measuring target side on an interface between the piezoelectric element and the reflection layer, and has a thickness so as to superimpose other ultrasonic waves on the transmitted ultrasonic wave.

An ultrasonic sensor which includes a substrate where an opening section is formed, a vibration plate that is provided on the substrate so as to close the opening section, and a piezoelectric element that is layered on a surface of the vibration plate on an opposite side to the opening section and includes a first electrode, a piezoelectric element, and a second electrode, includes a reflection layer that is provided in a space around the piezoelectric element on the surface of the vibration plate on an opposite side to the opening section, to reflect other ultrasonic waves which are transmitted in a different direction from a transmitted ultrasonic wave transmitted to a measuring target side on an interface between the piezoelectric element and the reflection layer, and has a thickness so as to superimpose other ultrasonic waves on the transmitted ultrasonic wave.

A deformation detection sensor that includes a conductive member, a plurality of thermoplastic resin layers, and a piezoelectric film. At least one of the thermoplastic resin layers has a main surface, and the conductive member is formed on the main surface thereof. The plurality of thermoplastic resin layers are laminated and integrally formed by hot pressing into a laminated body. A transmission line is formed form a first portion of the conductive member and the thermoplastic resin in the laminated body. The piezoelectric film is attached to the laminated body to form a piezoelectric element made of a second portion of the conductive member, the thermoplastic resin in the laminated body, and the piezoelectric film.

A deformation detection sensor that includes a conductive member, a plurality of thermoplastic resin layers, and a piezoelectric film. At least one of the thermoplastic resin layers has a main surface, and the conductive member is formed on the main surface thereof. The plurality of thermoplastic resin layers are laminated and integrally formed by hot pressing into a laminated body. A transmission line is formed form a first portion of the conductive member and the thermoplastic resin in the laminated body. The piezoelectric film is attached to the laminated body to form a piezoelectric element made of a second portion of the conductive member, the thermoplastic resin in the laminated body, and the piezoelectric film.

The invention relates to pressure sensors having a membrane having sensor chips having measuring bridges having sensor elements, wherein the membrane is fastened in a housing, with a carrier or as part of a housing, to which membrane a working medium can be applied. The pressure sensors are characterised in particular in that the mechanical stresses resulting from a fastening and/or an installation of the pressure sensors do not influence the measurement result and/or the measurement signal. To this end, at least two sensor chips, which are spaced apart from one another and are offset at an angle to one another, are located at least on a side of the membrane that bends on application of pressure. The measuring bridges are designed and/or connected to a controller in such a manner that at least one force resulting from the fastening of the membrane and thus acting on the membrane is or will be compensated.

The invention relates to pressure sensors having a membrane having sensor chips having measuring bridges having sensor elements, wherein the membrane is fastened in a housing, with a carrier or as part of a housing, to which membrane a working medium can be applied. The pressure sensors are characterised in particular in that the mechanical stresses resulting from a fastening and/or an installation of the pressure sensors do not influence the measurement result and/or the measurement signal. To this end, at least two sensor chips, which are spaced apart from one another and are offset at an angle to one another, are located at least on a side of the membrane that bends on application of pressure. The measuring bridges are designed and/or connected to a controller in such a manner that at least one force resulting from the fastening of the membrane and thus acting on the membrane is or will be compensated.

A method of manufacturing a porous pressure sensor, comprising: providing a substrate; forming a piezoelectric film on an upper surface of the substrate; performing a porosification process on the piezoelectric film, such as performing a wet etching process or a heat treatment process to form a porous pressure sensing layer; and forming a first electrode and a second electrode on two opposite sides of the upper surface of the porous pressure sensing layer, respectively. The present application is also directed to a pressure sensors manufactured by the method of manufacturing the porous pressure sensor.