KR19990030150A - Automatic voltage level control circuit - Google Patents

Abstract

Automatic voltage level control circuit 1 comprising an automatic voltage level control input 2 and a comparator 3, the comparator 3 comprising an output 4, a reference input 5, a feedback input 6. ) Is disclosed. Also disclosed is an amplifier (7), which has a control input and a feedback output (9) coupled to the output (4), the feedback output (9) of which power is supplied by the amplifier (7). Provide a signal associated with the level, coupled to a feedback input (6).

In the circuit of the invention, at least two selectable time constant networks are coupled to the reference input 5 and the automatic voltage level control input 2, which at least two time constants are electrically connected to the reference input 5. To be relevant.

In addition, an automatic switch 10 is electrically associated with the time constant network, which causes the automatic switch 10 to automatically switch from one time constant to another when it detects a voltage level higher than the threshold level. To do this.

Description

Automatic voltage level control circuit

The present invention relates to an automatic level control circuit, which is particularly useful for, but not limited to, the use of a radio frequency power amplifier used in conjunction with a voltage controlled oscillator.

In general, radio frequency power amplifiers are designed to operate at different power levels and are controllable by control voltages having different rates of change when used. For example, when a low power or high power response is selected, the rate of change of the reference voltage in the high power response is larger than the low power response. Therefore, when the steady state condition of the control voltage occurs in the high power response may be different compared to the low power response. As a result, when high power is required, sudden frequency pulling may occur in the voltage controlled oscillator (VCO) driving the radio frequency power amplifier by reaching the steady state too early. This can result in transient frequency shifts that violate industry standards such as the test specification ETS3000. However, if the rate of change is lowered to prevent sudden changes, the timing requirements of the MPT1327 system specification may not be met when the low power mode is selected.

In addition to the above, when operating at high power, other radio frequency power amplifiers may have a calibrated control voltage to provide the desired power output. In this case, the steady state conditions of the control voltage may occur at different times according to the initial application of the ramp reference voltage. Therefore, this may cause problems similar to those described above.

The present invention seeks to solve or alleviate at least one of the problems associated with the control of a radio frequency power amplifier.

1 is an embodiment of an automatic voltage level control circuit in accordance with the present invention.

2 shows a high lamp reference voltage and a low lamp reference voltage applied to the automatic voltage level control circuit of FIG.

3 illustrates a problem associated with a control voltage of a conventional automatic voltage level control circuit when using the lamp reference voltage of FIG.

4 shows a modified lamp reference voltage provided by the automatic voltage level control circuit of FIG.

5 shows a modified control voltage provided by the automatic voltage level control circuit of FIG.

FIG. 6 shows an example of lamp reference voltages of different magnitudes applied to the automatic voltage level control circuit of FIG.

FIG. 7 illustrates a problem associated with control voltages when the different ramp reference voltages of FIG. 6 are applied to a conventional automatic voltage level control circuit. FIG.

8 shows a modified lamp reference voltage provided by the automatic voltage level control circuit of FIG.

9 illustrates a modified control voltage provided by the automatic voltage level control circuit of FIG.

Explanation of symbols for the main parts of the drawings

1: automatic voltage level control circuit

2: automatic voltage level control input

3: comparator

7: amplifier

10: auto switch

19: rate of change detector

20: voltage controlled oscillator

The automatic voltage level control circuit according to the invention comprises an automatic voltage level control input, a comparator, an amplifier, at least two selectable time constant networks, and automatic switching means. The comparator includes a comparator output, a reference input, and a feedback input. The amplifier includes a control input and a feedback output coupled to the comparator output, the feedback output providing a signal associated with the power level supplied by the amplifier and coupled to the feedback input. The at least two selectable time constant networks are coupled to the reference input and the automatic voltage level control input such that at least two time constants can be associated with the reference input. The automatic switching means is electrically associated with the time constant network, allowing the automatic switching means to automatically switch from one time constant to another when it detects a voltage level above a threshold level.

The automatic switching means will preferably have one or more diodes. Such diodes may be Schottky diodes, traditional diodes, zener diodes, or other suitable types of diodes.

The time constant network may suitably include a resistor-capacitor network, an inductor-capacitor network, or a combination thereof.

One of the time constant networks is a series connection of a first capacitor and a resistor, and the other time constant network may be such that a second capacitor can be connected in parallel with the first capacitor by the switching means.

The amplifier is preferably a radio frequency amplifier. It would be desirable to have a voltage controlled oscillator coupled to drive the radio frequency amplifier.

With a rate of change detector electrically associated with the comparator output and the reference input, it would be appropriate to temporarily change the rate of change of the signal of the reference input when the signal at the comparator output crosses a threshold level and a rate of change of threshold.

The rate of change detector preferably includes a pull-down switch for temporarily coupling the reference input to ground.

The rate of change detector will suitably include a resistor-capacitor circuit coupled to the pull-down switch.

The pull-down switch may be a transistor having a base or gate input coupled to the resistor-capacitor circuit.

The automatic voltage level control circuit can be suitably coupled to a signal source for supplying at least two lamp voltages having different magnitudes and rates of change.

1 shows an automatic voltage level control circuit 1 comprising an automatic voltage level control input 2 and a comparator 3. The comparator includes a comparator output 4, a reference input Vref 5, and a feedback input 6. The automatic voltage level control circuit 1 also comprises an automatic switching means in the form of a radio frequency power amplifier 7, two selectable mapping networks T1, T2, and a diode network 10. The time constant network T1, T2 is coupled to the reference input 5 and the automatic voltage level control input 2.

The amplifier 7 comprises a control input Vctrl 8 coupled to the comparator output 4. The amplifier 7 also includes a feedback output Vfb, 9 which provides a signal associated with the power level supplied at OUT which is the output of the amplifier 7, which feedback output 9 is a feedback input of the comparator 3. Coupled to (6). Since the time constant network T1 consists of a series connection of the first capacitor C1 and the resistor R1, the associated time constant Tc1 becomes R1 * C1. Since the second time constant network T2 is formed by connecting the resistor R1 in series with the parallel connection of the capacitors C1 and C2, the associated time constant Tc2 becomes R1 * (C1 + C2).

A change rate detector 19 is coupled to the comparator output 4, which includes a pull-down transistor Q1 coupling base B to a resistor-capacitor circuit consisting of resistors R2, R3 and capacitor C3. Collector C of transistor Q1 is coupled to reference input Vref, 5, and emitter E of transistor Q1 is grounded. One terminal of resistor R3 is also grounded, the other terminal of resistor R3 is coupled to base B, and also to one terminal of the parallel network of resistor R2 and capacitor C3. The other terminal of the parallel network of resistor R2 and capacitor C3 is coupled to the comparator output (Vctrl, 4). A voltage controlled oscillator 20 is coupled to the amplifier 7 to drive the amplifier 7. In addition, the automatic voltage level control input 2 can be suitably coupled to a digital-analog transducer (DAC) 21 for providing two or more lamp voltages of different magnitudes and rates of change.

In operation, as shown in FIG. 2, the digital-to-analog converter 21 can supply a ramp voltage to the reference input Vref 5, which is a low or high power supply to the amplifier 7. Corresponding to the control signal Vctrl, these ramp voltages have different magnitudes and different inherent rates of change. As shown in Fig. 3, the conventional automatic voltage level control circuit has the disadvantage of reaching a steady state too early when the high power control signal is supplied to the control input 8 as compared with the low power control signal. This can cause sudden frequency pulling for the voltage controlled oscillator 20, which can cause undesirable transient frequency shifts that are inconsistent with industry standards. For this reason, the present invention modifies the rate of change of the reference input voltage during operation as shown in FIG. This operation is achieved by automatically switching from the time constant network T1 to the time constant network T2 when the diode network 10 detects a voltage level above the threshold voltage level. In the embodiment implemented in FIG. 1, this threshold level is approximately 1.44 Volts (forward breakdown voltage of four traditional series-connected Schottky diodes). If the low power ramp voltage is supplied to the input 2, the voltage across the diode network 10 will be below the threshold voltage level so that the time constant network T1 with the time constant Tc1 will be coupled to the input 2. However, if a high power ramp voltage is supplied to the input 2, the voltage across the diode network 10 will exceed the threshold voltage level so that forward bias will be applied to the diode network 10, with the capacitor C2 parallel to the capacitor C1. Will be inserted into the. Thus, time constant network T2 with time constant Tc2 will be coupled to the input 2. As a result, as shown in Fig. 5, the control voltage Vctrl by the high power and low power lamp voltage can reach the steady state at the same time by appropriately selecting the capacitors C1, C2. The use of the diode network 10 offers the advantage of smooth switching by the variable internal resistance of the diode, so that when the high power ramp voltage is supplied by the digital-to-analog converter 21, a sufficiently smooth input signal is input to the input 2. Note that it is obtained. It should also be noted that diode network 10 has a similar advantage when discharging capacitor C2.

In some cases, to obtain the same power output from different amplifiers 7, the reference voltages Vref applied to the reference input 5 will need to be of different magnitudes as shown in FIG. Unfortunately, as shown in Figure 7, conventional automatic level control circuits do not provide compensation for this requirement. As a result, depending on the reference voltage Vref supplied to the input 5, steady state conditions of the control voltage Vctrl supplied to the control input 8 will occur at different times from the initial application. Therefore, in the present invention, the change rate of the control voltage (Vctrl) is sensed using a change rate detector to turn on the transistor Q1 for a short period until the change rate drops below the threshold level LT when the threshold level LT is exceeded. To alleviate By doing so, as a result, the reference input 5 is temporarily shorted to ground, thereby changing the rate of change of the control voltage Vctrl. In this respect, the threshold level LT in this embodiment becomes the current I applied to the base B of the transistor Q1, and the current I becomes C3 * (dVctrl / dt). As will be apparent to those skilled in the art, the rate of change detector 19 causes the reference input 5 to be temporarily coupled to ground for a short period δ so that the reference voltage Vref of the reference input 5 changes as shown in FIG. 8. Will result in a modified control voltage Vctrl at the control input 8 as shown in FIG.

Advantageously, as shown in Figures 2-9, the present invention solves or mitigates at least one of the problems associated with the control of a radio frequency power amplifier.

Although the present invention has been described based on the preferred embodiments, it should be understood that the present invention is not limited by the above-described embodiments.

Claims (11)

In an automatic voltage level control circuit, Automatic voltage level control input, A comparator having a comparator output, a reference input, and a feedback input, An amplifier comprising a control input and a feedback output coupled to the comparator output, the feedback output providing a signal associated with the power level supplied by the amplifier and coupled with the feedback input, At least two selectable time constant networks coupled to the reference input and the automatic voltage level control input, allowing at least two time constants to be electrically associated with the reference input, and Automatic voltage level control circuitry, electrically associated with the time constant network, comprising automatic switching means for automatically switching from one time constant to another when sensing a voltage level above a threshold level. . The automatic voltage level control circuit as claimed in claim 1, wherein the automatic switching means is one or more diodes. 3. The automatic voltage level control circuit of claim 2, wherein the time constant network comprises a resistor-capacitor network, an inductor-capacitor network, or a combination thereof. 4. The method of claim 3, wherein one of the time constant networks is a first capacitor and a resistor coupled in series, and the other of the time constant networks is a second capacitor insertable in parallel to the first capacitor by the switching means. Voltage level control circuit. The automatic voltage level control circuit of claim 1, wherein the amplifier is a radio frequency amplifier. 6. The automatic voltage level control circuit of claim 5, further comprising a voltage controlled oscillator coupled to the radio frequency amplifier for driving the radio frequency amplifier. 10. The apparatus of claim 1, further comprising a rate of change detector electrically associated with the comparator output and the reference input, wherein the rate of change detector is configured at the reference input when the signal at the comparator output exceeds both a threshold level and a rate of change of threshold. Automatic voltage level control circuit adapted to temporarily change the rate of change of the signal. 8. The automatic voltage level control circuit of claim 7, wherein the rate of change detector includes a pull down switch to temporarily ground the reference input. 9. The automatic voltage level control circuit of claim 8, wherein the rate of change detector comprises a resistor-capacitor circuit coupled to the pull-down switch. 9. The automatic voltage level control circuit of claim 8, wherein the pull-down switch is a transistor having a base or gate input coupled to the resistor-capacitor circuit. 2. The automatic voltage level control circuit of claim 1, wherein the automatic voltage level control input is coupled to a signal source for supplying at least two ramp voltages having different magnitudes and rates of change.