TH9356B - Low voltage oscillator frequency generation circuit, less power. - Google Patents

Abstract

Frequency generation circuit (30, 40) oscillators For starting the circuit and working Yes, with a small voltage has been created. This oscillator circuit combines an inverter circuit (31,41) across the first and second terminals of the resonant circuit (14). Drive push-pull with p-channel transistors (18) and n-channel transistors (20). Each transistor's common drain pin is attached to the end. The second side of the resodant circuit The pins of the transistor P and N are connected to Power supply terminals one and two respectively. The gate pin of the first transistor is attached to the end. The first terminal, resonant circuit. The inverter circuit is further composed of a circuit (32, 42) for adjusting the voltage applied to the gate pin of the second transistor. In relation to the pressure at To the gate of the first transistor with a predetermined voltage For this reason it results in The required working voltage range in the inverter circuit has been reduced while maintaining the Keep both transistors working

Claims (4)

1. Frequency generation cycle (Oscillator) is intended for supplying the output signal which is the frequency generated at the specified frequency. Frequency generation cycle (Oscillator) will include an inverter circuit. The inverter circuit combines the first and second transistors with drain electrode (drain electrode) connected to the first and second resonant circuits. The output of the frequency-producing circuit The second end of the resonant circuit, the source electrodes of the first and second transistors, are connected to the first and second power supply terminals, respectively, the gate electrode of the transistor. One is connected to the first terminal of the resonant circuit. Improvements include The part of the circuit is connected between the first terminal of the resonant circuit and the gate pin of the Another transistor In order to shift the voltage applied to the gate of the other transistor by Due to the voltage applied to the gate pin of a transistor to maintain the working state of First and second transistors And make the cycle produce frequency (Oscillator) can start the circuit and work with a low voltage power supply. 2. The circuit produces a frequency. (Oscillator) according to claim 1, where the difference is minimal between The voltage applied to the first and second power supply terminals to maintain the operating conditions of the first and second transistors is the maximum threshold voltage of the first and second transistors, at least the threshold voltage is applied to the first and second transistors. Part of the circuit 3. Frequency generating cycle (Oscillator) according to claim 1, where the part of the circuit will The N-channel transistor) with the drain pin, the sauce pin and the gate pin, and the said pin of the N-channel transistor is connected to the first power supply terminal. And second, by sequence the aforementioned pin of the N type transistor is connected to the gate of the First transistor The gate pin of the N-type transistor is connected to the terminal one of the request. The resonant circuit 4. Frequency generation circuit (Oscillator) according to claim 1, where that portion of the circuit is included. To the P transistor with drain pin, sauce pin and gate pin, sauce pin, and such drain pin. P transistor It is connected between the first and second power supply terminals, respectively. The pin of the transistor P is connected to the gate pin of the second transistor. The said gate of Such a transistor It is connected to the terminal at one end of the resonant circuit. 5. Frequency generation circuit (Oscillator) according to claim 1 also includes a section for Work in a shuffle-frequency production circuit in the closed-open state. 6. Frequency generating cycle includes inverter circuits. And a resonant circuit for starting the circuit and operating with a small voltage. The inverter circuit is connected across the first and second terminals. Of resonant circuit The inverter circuit consists of The push-pull output driver sector (PUSH-PULL) includes a transistor. One and two places, each with a drain leg. Sauce Leg and Gate The aforementioned sauce leg of the first sister Jaw And two such They are connected to the first and second power supply terminals respectively. The aforementioned drains The first and second transistors are connected to the second terminal of the resonant circuit. The said gate of The second transcoder is connected to the first terminal of the resonant circuit, and the voltage shift is connected between the first terminal of the resonant circuit. And the aforementioned gate of the first transistor is used to shift the voltage applied to the gate of the First transistor Which is related to the voltage applied to the gate pin of the second transistor. 7. Frequency generating circuit According to claim 6, where the minimum difference between the applied pressure First and second power supply terminals In order to maintain the operating conditions of the first and second transistors, it is at least the initial threshold voltage of the first and second transistors. Change of the part for the promotion of the first level of the pressure. 8. Frequency generation cycle. According to claim 6, where the section for the said pressure promotion included To the transistor N type tracking source 9. Frequency generating circuit According to claim 6, where the section for the said pressure promotion will Including P-type transistor, tracking supply, 1 0. Frequency generation circuit According to claim 6, which will include further sections for working in The switching condition of the frequency generating circuit in the closed-open form 1. 1. Push-pull inverter circuits have low-voltage operating inputs and outputs consisting of first- and second-component transistors. The first transistor had a current carrying electrodes connected between the inverter circuit output and the source terminal. The first light, the second such a transistor There is a connecting pin between the output of the inverter circuit and the second power supply terminal, the control electrode of the first transistor. With the input of the inverter circuit Resonant circuits across the output of the inverter circuit. And the control leg of the transistor The first and second, and the voltage-escalator portion is connected between the inputs of the inverter circuit and the control pins of the transistor. The second is for the voltage drop that provides the control pin of the second transistor, relative to the voltage on the control pin of the first transistor. Thus allowing both transistors Two, it works at lower voltage. In order to start producing the frequency of powering the inverter circuit 1 2. Inverter circuit According to claim 11, where the slightest difference between the applied pressure and the One and two power supply terminals In order to maintain the operating conditions of the first and second transistors, it is the maximum threshold voltage of the first and second transistors. At least the threshold voltage changed Of part of the pressure level shift circuit 1 3. Inverter circuit According to claim 11, where the section for pressure promotion These include tracer n-type transistors intended for shifting the leading voltage. To the control pin of the second transistor as follows by the threshold voltage of the transistor N 1. 4. Inverter circuit According to claim 11, where the section for pressure promotion It includes a P-type transistor. The trace source is used to shift the leading voltage. To the control pin of the second transistor by the threshold voltage of the transistor P (P).