A configuration circuit for obtaining a digital code includes a controller circuit that generates a plurality of multibit control words. A digitally controlled current source circuit receives a multibit control word generated by the controller circuit. The digitally controlled current source circuit generates an output current that corresponds to the multibit control word in accordance with a predetermined output curve. A test voltage node receives the output current, and a test voltage develops in response to the output current. A reference voltage node develops a reference voltage, the level of which is independent of the multibit control word. A voltage comparison circuit (i) receives the test voltage and the reference voltage, (ii) compares the two voltages to produce a comparison result and (iii) sends the comparison result to the controller circuit. The digital code is obtained by the configuration circuit using the comparison result and the multibit control word.

A configuration circuit for obtaining a digital code includes a controller circuit that generates a plurality of multibit control words. A digitally controlled current source circuit receives a multibit control word generated by the controller circuit. The digitally controlled current source circuit generates an output current that corresponds to the multibit control word in accordance with a predetermined output curve. A test voltage node receives the output current, and a test voltage develops in response to the output current. A reference voltage node develops a reference voltage, the level of which is independent of the multibit control word. A voltage comparison circuit (i) receives the test voltage and the reference voltage, (ii) compares the two voltages to produce a comparison result and (iii) sends the comparison result to the controller circuit. The digital code is obtained by the configuration circuit using the comparison result and the multibit control word.

Press-button circuit and a driving method thereof are provided. A press-button circuit includes a first sampling port; a second sampling port; a common terminal; a first control device, coupled to the first sampling port and the second sampling port; at least one first press-button sub-circuit, coupled to the first sampling port and the common terminal; and at least one second press-button sub-circuit, coupled to the second sampling port and the common terminal.

Press-button circuit and a driving method thereof are provided. A press-button circuit includes a first sampling port; a second sampling port; a common terminal; a first control device, coupled to the first sampling port and the second sampling port; at least one first press-button sub-circuit, coupled to the first sampling port and the common terminal; and at least one second press-button sub-circuit, coupled to the second sampling port and the common terminal.

A semiconductor device includes a first contact receiving a first voltage, a second contact receiving a second voltage, one or more comparing elements comparing the first and second voltages, and one or more setting elements setting one or more parameters of the device in response to a comparison of the first and second voltages. When the first voltage is greater than the second voltage the setting element selects the first voltage as a high voltage, the second voltage as a low voltage, and sets a mode signal to a first value. When the second voltage is greater than the first voltage the setting element selects the first voltage as the low voltage, the second voltage as the high voltage, and sets the mode signal to a second value. The first and second values alter a condition of an electronic component coupled with the device between a first and second state.

A sensing circuit configured to activate a controller is disclosed. The circuit comprises a first transistor configured to output an activation signal to the controller and a plurality of switches in connection with a base of the transistor. Each of the switches is connected to an identifying resistor. A first output node and a second output node are in communication with the base of the transistor and each of the switches. The first output node and the second output node are separated across an additional identifying resistor. The first output node and the second output node are configured to output a characteristic voltage corresponding a ratio of each of the identifying resistors in response to an input received by one or more of the plurality of switches.

A method for recognizing a press of a key by a small force on a slim portable keyboard for use with a smart phone, a tablet PC, a general PC, or a notebook computer. A special-key press processing unit processes a press of a plurality of special keys. A plurality of general-key press processing units process a press of a plurality of general keys. A set number of general keys are configured to be one block. The keyboard is slim and can be conveniently carried. The keyboard includes a plurality of special key resistances and a plurality of general key resistances, each of which is proportional to a pressure caused by a press, to recognize a press of a key even when the key is pressed by a small force.

A semiconductor device includes a first contact receiving a first voltage, a second contact receiving a second voltage, one or more comparing elements comparing the first and second voltages, and one or more setting elements setting one or more parameters of the device in response to a comparison of the first and second voltages. When the first voltage is greater than the second voltage the setting element selects the first voltage as a high voltage, the second voltage as a low voltage, and sets a mode signal to a first value. When the second voltage is greater than the first voltage the setting element selects the first voltage as the low voltage, the second voltage as the high voltage, and sets the mode signal to a second value. The first and second values alter a condition of an electronic component coupled with the device between a first and second state.

An operation instruction generating circuit and a consumable chip. The operation instruction generating circuit includes: a power-on initialization module, connected to a signal wire and used for generating an initialization signal according to a signal transmitted by the signal wire; a middle signal generating module, connected to the power-on initialization module and the signal wire and used for combining, according to the initialization signal, the signal transmitted by the signal wire to generate a middle signal; and an instruction generating module, connected to the power-on initialization module and the middle signal generating module and used for generating an operation instruction according to the initialization signal and the middle signal or according to the initialization signal, the middle signal, and the signal transmitted by the signal wire. By the operation instruction generating circuit, the consumable chip is enabled to accurately respond to actions of a printing imaging device in time.

An operation instruction generating circuit and a consumable chip. The operation instruction generating circuit includes: a power-on initialization module, connected to a signal wire and used for generating an initialization signal according to a signal transmitted by the signal wire; a middle signal generating module, connected to the power-on initialization module and the signal wire and used for combining, according to the initialization signal, the signal transmitted by the signal wire to generate a middle signal; and an instruction generating module, connected to the power-on initialization module and the middle signal generating module and used for generating an operation instruction according to the initialization signal and the middle signal or according to the initialization signal, the middle signal,and the signal transmitted by the signal wire. By the operation instruction generating circuit, the consumable chip is enabled to accurately respond to actions of a printing imaging device in time.