Provided is a conversion circuit, including a switch signal input terminal; first and second input terminals; and first and second output terminals. The switch signal input terminal receives a switch control signal. The first and second input terminals receive first and second input signals, and polarities of first and second input signals are different and alternately switch. Depending on the switch control signal, the first input terminal is in communication with the first output terminal and the second input terminal is in communication with the second output terminal, or the second input terminal is in communication with the first output terminal and the first input terminal is in communication with the second output terminal, so that a first output signal outputted from first output terminal has a consistent polarity at any time and a second output signal outputted from the second output terminal has a consistent polarity at any time.

A switching circuit includes a first switching element that has a first control terminal, a connection state between a power generation element and an electric storage device being controlled in accordance with a voltage applied to the first control terminal, and a control circuit configured to output a first voltage to the first control terminal until a voltage difference between both ends of the electric storage device becomes a first predetermined value larger than an initial state when the voltage difference increases from the initial state with time, and output a second voltage to the first control terminal until the voltage difference becomes lower than a second predetermined value smaller than the first predetermined value when the voltage difference exceeds the first predetermined value, the first voltage being a voltage that keeps the first switching element on, the second voltage being a voltage that keeps the first switching element off.

A switching circuit includes a first switching element that has a first control terminal, a connection state between a power generation element and an electric storage device being controlled in accordance with a voltage applied to the first control terminal, and a control circuit configured to output a first voltage to the first control terminal until a voltage difference between both ends of the electric storage device becomes a first predetermined value larger than an initial state when the voltage difference increases from the initial state with time, and output a second voltage to the first control terminal until the voltage difference becomes lower than a second predetermined value smaller than the first predetermined value when the voltage difference exceeds the first predetermined value, the first voltage being a voltage that keeps the first switching element on, the second voltage being a voltage that keeps the first switching element off.

Oscillator circuit uses a comparator, and controls charge-discharge of Miller capacitance between gate and drain of a MOSFET serving as an amplifier of the comparator gain unit and gate capacitance of the MOSFET, and enables comparator output to follow a high-frequency control signal that is input externally. An oscillator circuit uses a comparator CMP having differential and gain units. This oscillator circuit includes: a charge-discharge controller to control charge-discharge of Miller capacitance between gate and drain of a MOSFET and gate capacitance of the MOSFET; and an output controller to control output of the gain unit. Output controller includes: an inverter to connect to an input of the differential unit and receive a control signal input; a logic circuit to receive output of the inverter and output of the gain unit as an input; a transistor; and a capacitor to connect to input and output of the logic circuit.

The present invention discloses a CSAMT transmitter, including: a first transmitter, where the first transmitter includes a first generator, a first rectifier module, a first transmission module, and a second transmission module, the first generator is connected to the first transmission module and the second transmission module by using the first rectifier module; and a second transmitter, where the second transmitter includes a second generator, a second rectifier module, a third transmission module, and a fourth transmission module, the second generator is connected to the third transmission module and the fourth transmission module by using the second rectifier module, where the first transmission module is connected to the third transmission module, and the second transmission module is connected to the fourth transmission module; the first transmission module has the same voltage as the third transmission module, and the second transmission module has the same voltage as the fourth transmission module.

The present invention discloses a CSAMT transmitter, including: a first transmitter, where the first transmitter includes a first generator, a first rectifier module, a first transmission module, and a second transmission module, the first generator is connected to the first transmission module and the second transmission module by using the first rectifier module; and a second transmitter, where the second transmitter includes a second generator, a second rectifier module, a third transmission module, and a fourth transmission module, the second generator is connected to the third transmission module and the fourth transmission module by using the second rectifier module, where the first transmission module is connected to the third transmission module, and the second transmission module is connected to the fourth transmission module; the first transmission module has the same voltage as the third transmission module, and the second transmission module has the same voltage as the fourth transmission module.

A system includes an input voltage supply. The system also includes a switching converter coupled to the input voltage supply and configured to provide an output voltage based on a switch on-time. The system also includes a switch on-time controller for the switching converter. The switch on-time controller includes an analog-to-digital converter (ADC) and a delay line coupled to the ADC. The switch on-time controller also includes a delay line modulator coupled to the delay line and configured to determine an amount of times the delay line is used to determine the switch on-time.

A system includes an input voltage supply. The system also includes a switching converter coupled to the input voltage supply and configured to provide an output voltage based on a switch on-time. The system also includes a switch on-time controller for the switching converter. The switch on-time controller includes an analog-to-digital converter (ADC) and a delay line coupled to the ADC. The switch on-time controller also includes a delay line modulator coupled to the delay line and configured to determine an amount of times the delay line is used to determine the switch on-time.

In an embodiment, a clock generator has a variable-modulus frequency divider that receives a high-frequency clock signal and outputs a divided clock signal having a frequency controlled by a modulus-control signal generated by a temperature-compensation circuit. A jitter filter is coupled to the output of the variable-modulus frequency divider and to the temperature-compensation circuit and generates a compensated clock signal having switching edges that are delayed, with respect to the divided clock signal, by a time correlated to a quantization-error signal.

In an embodiment, a clock generator has a variable-modulus frequency divider that receives a high-frequency clock signal and outputs a divided clock signal having a frequency controlled by a modulus-control signal generated by a temperature-compensation circuit. A jitter filter is coupled to the output of the variable-modulus frequency divider and to the temperature-compensation circuit and generates a compensated clock signal having switching edges that are delayed, with respect to the divided clock signal, by a time correlated to a quantization-error signal.