System and method for providing precision a self calibrating resistance circuit is described that provides for matching a reference resistor using dynamically configurable resistance networks. The resistor network is coupled to the connection, wherein the resistor network provides a configurable resistance across the connection. In addition, the resistor network comprises a digital resistor network and an analog resistor network. Also, the circuit includes control circuitry for configuring the configurable resistance based on a reference resistance of the reference resistor. The configurable resistance is configured by coarsely tuning the resistor network through the digital resistor network and fine tuning the resistor network through the analog resistor network.

System and method for providing precision a self calibrating resistance circuit is described that provides for matching a reference resistor using dynamically configurable resistance networks. The resistor network is coupled to the connection, wherein the resistor network provides a configurable resistance across the connection. In addition, the resistor network comprises a digital resistor network and an analog resistor network. Also, the circuit includes control circuitry for configuring the configurable resistance based on a reference resistance of the reference resistor. The configurable resistance is configured by coarsely tuning the resistor network through the digital resistor network and fine tuning the resistor network through the analog resistor network.

A chip resistor has a substrate, a first connection electrode and a second connection electrode that are formed on the substrate, and a resistor network that is formed on the substrate and that has ends one of which is connected to the first connection electrode and the other one of which is connected to the second connection electrode. The resistor network is provided with a resistive circuit. The resistive circuit has a resistive element film line that is provided along inner wall surfaces of trenches. The resistive element film line extending along the inner wall surfaces of the trenches is long and has a high resistivity as a unit resistive element.

A chip resistor has a substrate, a first connection electrode and a second connection electrode that are formed on the substrate, and a resistor network that is formed on the substrate and that has ends one of which is connected to the first connection electrode and the other one of which is connected to the second connection electrode. The resistor network is provided with a resistive circuit. The resistive circuit has a resistive element film line that is provided along inner wall surfaces of trenches. The resistive element film line extending along the inner wall surfaces of the trenches is long and has a high resistivity as a unit resistive element.

A method of manufacturing a resistor device includes forming a stepped trench in a substrate, and forming an etch stop material within the stepped trench. An electrically resistive material is disposed within the stepped trench, and an electrically insulating material is disposed on the electrically resistive material. The method further includes repeating the disposing the electrically resistive material and the disposing the electrically insulating material operations a predetermined number of times.

A chip component includes a substrate, an element circuit network including a plurality of element parts formed on the substrate, an external connection electrode provided on a surface of the substrate to provide external connection for the element circuit network, a plurality of fuses formed on the substrate and disconnectably connecting each of the plurality of element parts to the external connection electrode, a solder layer formed on an external connection terminal of the external connection electrode and a resin film which covers the surface of the substrate and other surface which intersects the surface of the substrate.

A chip component includes a substrate, an element circuit network including a plurality of element parts formed on the substrate, an external connection electrode provided on a surface of the substrate to provide external connection for the element circuit network, a plurality of fuses formed on the substrate and disconnectably connecting each of the plurality of element parts to the external connection electrode, a solder layer formed on an external connection terminal of the external connection electrode and a resin film which covers the surface of the substrate and other surface which intersects the surface of the substrate.

[Problem] There is demand for chip resistors that are compact and that have high resistivity. [Solution] A chip resistor (100) has a substrate (11), a first connection electrode (12) and a second connection electrode (13) that are formed on the substrate (11), and a resistor network that is formed on the substrate (11) and that has ends one of which is connected to the first connection electrode (12) and the other one of which is connected to the second connection electrode (13). The resistor network is provided with a resistive circuit. The resistive circuit has a resistive element film line (103) that is provided along inner wall surfaces of trenches (101). The resistive element film line (103) extending along the inner wall surfaces of the trenches (101) is long and has a high resistivity as a unit resistive element. [Effect] The resistivity of the chip resistor (100) as a whole can be increased.

[Problem] There is demand for chip resistors that are compact and that have high resistivity. [Solution] A chip resistor (100) has a substrate (11), a first connection electrode (12) and a second connection electrode (13) that are formed on the substrate (11), and a resistor network that is formed on the substrate (11) and that has ends one of which is connected to the first connection electrode (12) and the other one of which is connected to the second connection electrode (13). The resistor network is provided with a resistive circuit. The resistive circuit has a resistive element film line (103) that is provided along inner wall surfaces of trenches (101). The resistive element film line (103) extending along the inner wall surfaces of the trenches (101) is long and has a high resistivity as a unit resistive element. [Effect] The resistivity of the chip resistor (100) as a whole can be increased.

A tub comprising a body for holding a volume of water. A tub system is coupled to the body to perform a function on the volume of water. At least a first circuit has a first circuit portion comprising at least one resistive switch mounted to a visible surface of the body and comprising at least a first resistive element adapted to be contacted by a bather, second circuit portion comprising a water detection sensor mounted to the body for containing liquid in the body above a given level, the first circuit being open between the first resistive element and the water detection sensor, an actuating closed circuit condition by which a bather in liquid above the given level closes the first circuit between the first circuit portion and the second circuit portion when touching the first resistive element. A controller is operationally coupled to first circuit portion and the second circuit portion of the first circuit, and to the tub system, the controller adapted to detect the actuating closed circuit condition to trigger an action of the tub system.