DE4114363A1 - CIRCUIT ARRANGEMENT FOR POWER CONTROLLING A MOSFET WITH SOURCE-SIDED LOAD - Google Patents

Abstract

A circuit (4) including a bootstrap circuit purse width modulates the gate voltage of the MOSFET (1). An oscillator (5) with variable frequency produces a pulse sequence as output, and this is fed to the modulation circuit (4). The pulse frequency of the controllable oscillator is controlled in dependence on the pulsse width. The pulse frequency may be reduced with rise of pulse width. The pulse frequency may be hold constant until a set pulse width rise has taken place, and then be reduced. ADVANTAGE - Enables operation of MOSFET via bootstrap circuit up to virtually 100 per cent switch on time.

Description

The invention relates to a circuit arrangement for Power control of a MOSFET with source-side load with Means for pulse width control of the gate voltage of the MOSFET, that contain a bootstrap circuit.

Such a circuit arrangement is, for example, from Elrad (1989) Issue 11, p.48 known. To measure the performance of a load, e.g. B. To regulate a light bulb, the Me is suitable in many cases method of pulse width modulation. As a circuit breaker in the never The voltage range is mostly MOS field-effect transistors preferred because of its low forward resistance. Will such circuits applied in automotive engineering, so occurs the difficulty that the load is unilaterally grounded must be closed. The switch is then on plus pots tial. Since only n-channel MOSFET field effect tran for cost reasons sistors are used, must be used to control the gate Voltage is applied around the threshold voltage of the MOSFET must be greater than the operating voltage.

Two methods have proven to solve this problem. The first method is the charge pump. With this procedure a capacitor is connected to the operating voltage via a diode charged and z. B. by a square wave signal of high frequency the voltage across the capacitor is then increased by the amplitude value of the Square wave signal increased. The resulting tension on the condensate sator can now discharge into the gate capacitance of the MOSFET and control it. However, difficulties arise when periodic shutdown is required because always fully discharged the gate and then quickly again afterwards  must be charged. Furthermore, it can be proportionate high pump frequency may be the cause of radio interference problems.

The second procedure is the bootstrap procedure, in which a so-called bootstrap capacitor is used. Is the Load is switched off, the bootstrap capacitor is connected via a Diode charged to the operating voltage. When you turn on the MOSFET field effect transistor now shifts the load operating voltage applied to the bootstrap capacitor de voltage around this value. For a periodic shutdown the load, as is the case with pulse width modulation of the If so, the bootstrap arrangement offers a good solution. Even if the load is only switched off briefly, the Recharge the bootstrap capacitor. The switching frequency must however, be chosen so high that the load by clocking the operating voltage no disturbing effects occur, but only the effective value of the current can be varied. With incandescent lamps are z. B. about 100 Hz necessary so that no flickering is noticeable.

Now if 100% control of the MOSFET is required, that is, the MOSFET should always be turned on, so this is not possible with the bootstrap procedure. Should be here from the bootstrap process to the charge pump process be switched. This means a correspondingly high one Circuitry.

The object of the invention is to provide a circuit arrangement for Lei control of a MOSFET with source-side load, which enables a MOSFET to be bootstraped up to control almost 100% duty cycle.

The task is solved by the characteristic features of the Claim 1. Further training is characteristic of the dependent claims che.  

The circuit according to the invention makes it possible after Errei Chen the highest possible duty cycle, which is in the before only set pulse frequency results in the pulse frequency continuously lower and lower so that the very short Timely load disconnection now occurs very rarely and almost permanent, almost 100% switch-on state reached becomes. For the control of an incandescent lamp, the Tatsa che exploited that with such narrow pulses switching off the Incandescent lamp no longer perceptible to the human eye is cash, d. H. also a lower repetition frequency than 100 Hz now is possible. Furthermore, the use of a MOSFET provides Circuit breakers have the advantage that the gate capacitance even at longer refreshment breaks remains sufficiently loaded.

The invention is explained in more detail with reference to two figures.

Fig. 1 shows an inventive circuit arrangement for Lei power control of a MOSFET with source-side load.

Fig. 2 shows the time course of the gate voltage of the MOSFET for three power values.

In Fig. 1, the drain terminal of the MOSFET 1 is connected via an input terminal 2 to the operating voltage U _B. At the source circuit of the MOSFET 1 is a load 3 with a fixed loading potential, z. B. ground connected. Furthermore, a circuit arrangement 4 is provided which generates a first output signal which is supplied to the gate terminal of the MOSFET 1 . Finally, a controllable oscillator 5 is provided, the output frequency of which is supplied to the circuit arrangement 4 and which is controlled by a second output signal generated by the circuit arrangement 4 . The circuit arrangement 4 includes both a bootstrap arrangement and a circuit arrangement for pulse width modulation. The circuit arrangement 4 is also supplied with a signal 6 which controls the pulse duty factor of the first output signal.

Furthermore, it contains means that a signal for controlling the Generate oscillator.

If the load is to be switched off, the first output signal of the circuit arrangement 4 is below the threshold voltage of the MOSFET 1 . If the power of the load is now to be increased continuously, the controllable oscillator generates a pulse sequence of fixed frequency, which is determined by the second output signal of the circuit arrangement 4 . The pulse width of the pulses is now regulated by the circuit arrangement 4 in accordance with the power value set by the signal 6 and fed to the gate terminal of the MOSFET 1 via the bootstrap arrangement. The width of the on-pulses is set by the circuit arrangement 4 depending on the desired power up to a maximum value for the bootstrap arrangement. For a medium power, the time profile of the gate voltage in FIG. 2 is designated A and for the same pulse frequency the maximum possible gate voltage profile for the bootstrap arrangement is designated B. If the power consumption of the load 3 is to be increased further, the circuit arrangement 4 now generates a control signal which lowers the frequency of the controllable oscillator 5 . In this way, almost 100% pulse width modulation can be generated. The gate voltage curve corresponding to this case is designated C in FIG. 2. Depending on the application, the pulse frequency of the oscillator could also be reduced as the pulse width increases. This mainly depends on the type of consumer and the application. If the load 3 has a non-linear performance characteristic, it can e.g. B. by ent speaking control of the pulse frequency of the oscillator 5, a linearization of the power curve.

Claims (4)

1. Circuit arrangement for power control of a MOSFET ( 1 ) with source-side load ( 3 )

• a) means ( 4 ) for pulse width control of the gate voltage of the MOSFET ( 1 ), which contain a bootstrap circuit,

characterized in that

• b) an adjustable in frequency oscillator ( 5 ) for generating a pulse train is provided, which generates an output signal,
• c) the output signal of the controllable oscillator ( 5 ) is fed to the means ( 4 ) for pulse width control,
• d) means are provided which control the pulse frequency of the controllable ren oscillator ( 5 ) as a function of the pulse width.

2. Circuit arrangement for power control of a MOSFET ( 1 ) with source-side load ( 3 ) according to claim 1, characterized in that the pulse frequency is reduced as the pulse width increases. 3. Circuit arrangement for power control of a MOSFET with source-side load ( 3 ) according to claim 1, characterized in that the pulse frequency remains constant as the pulse width increases up to a predetermined pulse width and is reduced after reaching the predetermined pulse width at a constant pulse width.