DE102011075314B4 - Regulated high power amplifier - Google Patents

Abstract

Amplifier having a first amplifier circuit (13), at least one second amplifier circuit (14) and a control circuit (31),
wherein the first amplifier circuit (13) and the second amplifier circuit (14) are connected such that their output signals combine to form a total output signal (18), and
wherein the control circuit (31) performs a comparison of a signal determined from the total output signal (18) with a reference value (30),
the amplifier further comprising an attenuator (11) of adjustable attenuation which attenuates an input signal (10) of the amplifier,
wherein the control circuit (31) based on the comparison generates a control signal (29) of the attenuator (11) and thus sets the attenuation, and
wherein the control circuit (31) limits the actuating signal (29) with a maximum actuating signal.

Description

The invention relates to an amplifier and a method for operating an amplifier.

High-frequency power amplifiers often consist of many parallel-connected power transistors. Its output power is kept constant with a control circuit in which the output power detected by the detector is compared with a setpoint. That's how it shows DE 10 2005 058 464 A1 a high-power amplifier which detects both the output signal and the input signal, forms signals derived therefrom and compares them with each other. Based on this comparison, the gain is set.

A problem here is the failure of power transistors. If a control of the gain in all the transistors used, the resulting power loss leads to a compensation by the scheme. The remaining transistors must deliver more power, which in the worst case leads to consequential failures, but at least overdrive. This is undesirable in particular with linear amplifiers, since it can lead to disturbances in neighboring channels.

One solution to this problem is, for example, that actual value detectors behind several sub-amplifiers of the same output power decoupled via diodes are connected to the control amplifier, that the sub-amplifier with the largest output signal determines the scheme. As partial amplifiers, parallel-connected transistor pairs are preferably used via 3 dB directional couplers, since their RF output power is almost independent of the magnitude of the load resistance. If a transistor now fails, the modulation of the remaining transistors only changes if the subsystem determining the regulation is affected. Even then, the change is small, as all actual value detectors deliver nearly the same signal strength. The system only fails if at least one transistor has failed in all subsystems equipped with an actual-value detector.

However, there are systems in which the application of the above principle is not possible, because there are no corresponding sub-amplifier of the same output power. This is especially the case with Doherty amplifiers. In order to achieve a certain tolerance in this case with respect to transistor failures, the adjustment range of the control amplifier can be limited so that the overdriving of the intact transistors occurring in the event of a transistor failure can not lead to their failure. However, the range to be taken into account must be so large that it is possible to compensate for the changes in the amplification caused by the operational warming of the amplifier and the permissible temperature range as well as the change in the input signal.

In addition, the amplification over frequency and specimen is subject to a considerable dispersion, so that 3-5 dB are reached and exceeded quickly. Thus, a fixed adjustable restriction of the adjustment range is almost ineffective if it is not designed frequency and copy individual. This is possible, for example, by means of a look-up table. However, such solutions require a comprehensive matching process in which the frequency response and characteristics of the individual device are measured and taken into account. This is expensive and does not take temperature influences into account. These must be compensated by means of fixed characteristic curves taking into account the measured temperature. This overall solution is very complicated and intolerant of age-related changes.

Another regulated high power amplifier is out of the US 5,886,575 A known. However, it is not apparent from this document that the control circuit limits the actuator with a maximum actuating signal.

The present invention has for its object to show an amplifier and a method for operating an amplifier, which require little effort and at the same time have a high tolerance against failures of sub amplifiers.

The object is achieved according to the invention for the amplifier by the features of independent claim 1 and for the method for operating an amplifier by the features of independent claim 11. Advantageous developments are the subject of the dependent claims.

An amplifier according to the invention has a first amplifier circuit, a second amplifier circuit and a control circuit. The first amplifier circuit and the second amplifier circuit are connected such that their output signals combine to form a total output signal. The control circuit performs a comparison of a signal determined from the total output signal and a reference value. The amplifier also has an attenuator of adjustable attenuation which attenuates an input signal of the amplifier. The control circuit generates a control signal of the attenuator based on the comparison and thus sets the attenuation. The control circuit limits the actuating signal with a maximum actuating signal.

The control circuit preferably determines the maximum control signal at least indirectly from earlier control signals.

The amplifier according to the invention and the operating method according to the invention are preferably based on an adaptive adaptation of the control range of the control amplifier to the instantaneous conditions in the control loop. It exploits the fact that changes in the gain and the input signal caused by temperature and aging are slow. Advantageously, the manipulated variable, e.g. detects the set voltage of an attenuator at slow intervals. The limitation of the setting range results from the measured value plus a difference, which may not be exceeded until the next measurement under the condition of normal temperature or aging processes. That if the set voltage of the attenuator increases slowly after the power is turned on and the output power is initially adjusted, because the gain decreases with increasing temperature and the attenuation of the attenuator needs to be reduced to keep the output constant, the limitation of the setting range slowly increases.

In the event of abrupt changes, for example caused by a transistor failure or else sudden changes in the input signal, the adjustment of the limitation of the control range is preferably suspended. The limitation of the adjustment range is thus fully effective. A sudden change is preferably recognized by the fact that the change occurring between two measured values of the manipulated variable is greater than permissible. The restriction of the control range can be kept so safe in a range that prevents too much overdriving in case of error. In the event of transistor failure, the gain increase of the remaining transistors can be limited to <1 dB, and thus be kept within the framework of the systems described above with identical amplifiers.

Advantageously, while the restriction of the manipulated variable is kept constant, the state can now be analyzed and the source of the error can be determined. If the cause is, for example, a transistor failure, a setpoint of the output power can be corrected accordingly. The adaptive adaptation of the adjustment range can then preferably be resumed. Until the replacement of the defective transistor, the system can now continue to operate at reduced power.

In addition, the adaptive determination of the setting range can preferably be suspended whenever large changes are to be expected. For example, it may be useful to turn it on and off and change the reference value, i. the setpoint power to suspend the adaptive determination of the setting range.

• 1 ein erstes Ausführungsbeispiel des erfindungsgemäßen Verstärkers;
• 2 ein zweites Ausführungsbeispiel des erfindungsgemäßen Verstärkers;
• 3 ein erstes Ausführungsbeispiel des erfindungsgemäßen Verfahrens, und
• 4 ein zweites Ausführungsbeispiel des erfindungsgemäßen Verfahrens.

The invention will be described by way of example with reference to the drawing, in which an advantageous embodiment of the invention is shown. In the drawing show:

• 1 a first embodiment of the amplifier according to the invention;
• 2 A second embodiment of the amplifier according to the invention;
• 3 a first embodiment of the method according to the invention, and
• 4 A second embodiment of the method according to the invention.

First, based on the 1 - 2 the structure and operation of an amplifier explained. through 3 - 4 the mode of operation of the method according to the invention is then shown. Identical elements have not been repeatedly shown and described.

1 shows a first embodiment of the amplifier according to the invention. An input signal 10 is an adjustable attenuator 11 fed. This is with a power divider 12 connected, which in the embodiment with a first amplifier circuit 13, a second amplifier circuit 14 and a third amplifier circuit 15 connected is. The amplifier circuits 13 . 14 . 15 are with a power combiner 16 connected. This one is via a coupler 17 with a power detector 19 connected. The power detector 19 is with an input of a comparator 20 connected. With a second input of the comparator 20 is a control device 21 connected. The control device 21 has several status information inputs 22 . 23 , An output of the comparator 20 is via a diode 24 in the flow direction with an input of the adjustable attenuator 11 connected. The output of the comparator 20 is still using an analog-to-digital converter 25 with an input of the control device 21 connected. Furthermore, with an output of the control device 21 a digital-to-analog converter 26 connected, which via a diode 32 in the flow direction with the input of the attenuator 11 connected is. In addition, with the input of the attenuator 11 a supply voltage 28 about a resistance 27 connected.

The input signal 10 is from the attenuator 11 attenuated in response to a control signal and the power divider 12 fed. This divides the attenuated input signal and leads it to the amplifier circuits 13 , 14, 15 too. These amplify the signal and guide it combiners 16 to which the amplified sub-signals to a total output signal 18 combined. Via the coupler 17, the total output signal 18 the detector 19 additionally supplied. The detector 19 determines the power of the overall output signal and transmits a signal corresponding to the power of the overall output signal to the comparator 20 , This compares this signal with a reference value 30 which him from the controller 21 is supplied. Depending on the comparison, the comparator generates 20 a current (current) control signal 29 which is via the diode 24 the input of the adjustable attenuator 11 is supplied. The analog-to-digital converter 25 digitizes the current control signal 29 and leads it to the controller 21 to. The control device 21 compares this digitized signal with a digital maximum control signal. Is the current control signal 29 less than the maximum control signal, it changes the maximum control signal by going to the current control signal 29 adds a fixed value. Is however the current control signal 29 higher than the maximum actuating signal, it leaves the maximum actuating signal at its current value.

Furthermore, the control device 21 the maximum control signal in digitized form to the digital-to-analog converter 26 out, which converts it into an analog signal. About the diode 32 the maximum actuating signal is the input of the attenuator 11 fed. By the supply voltage 28 which about the resistance 27 also the input of the attenuator 11 is supplied forms at the input of the attenuator 11 a voltage which is the lower value from the group of the current control signal 29 and the maximum actuating signal corresponds. It is thus ensured that the attenuator performs at most one attenuation in the context of the maximum control signal.

2 shows a second embodiment of the amplifier according to the invention. Here only the interconnection of the control device 41 , the comparator 40, the analog-to-digital converter 45 and the digital-to-analog converter 46 shown. Incidentally, the circuit corresponds to the circuit 1 , In the circuit shown here can be on the diodes 24 and 32 and on the supply voltage 28 and the resistance 27 be waived. This significantly reduces the complexity. The output signal of the digital-to-analogue converter 46 is here as supply voltage to the comparator 40 fed. This causes the comparator 40 as the maximum output signal, the output signal of the digital-to-analog converter 46 , which indicates the maximum actuating signal 1 corresponds, can spend.

The diodes 24 and 32 out 1 In addition, they produce an operating point dependent voltage drop in the current control signal 29 and the maximum control signal. This provides for a degree of inaccuracy. This inaccuracy is in the amplifier after 2 by doing without the diodes 24 . 32 avoided. Here it only has to be considered that the comparator 40 can output a slightly reduced maximum value compared to its supply voltage. The control device 41 compensates this by adding an additional fixed value to the maximum control signal, which they the digital-to-analog converter 46 supplies. Advantageously, the comparator 40 implemented such that its output signal can be as close to the supply voltage. Compensation is then not necessary.

In 3 a first embodiment of the inventive method for operating an amplifier is shown. In a first step 50 the total output power of the amplifier is determined. In a second step 51 this total output power is compared with a reference value. A current control signal is in a third step 52 determined by comparison. In a fourth step 53 that will be the third step 52 certain current control signal is limited by a maximum control signal. Concerning. the determination of the maximum actuating signal is applied to the explanations 4 directed.

In a fifth step 54 An input signal of the amplifier is attenuated in response to the limited current control signal. The steps 50 to 54 are repeated in a closed loop while the amplifier is operating. Repetition may, however, be suspended as described below.

4 shows a second embodiment of the inventive method for operating an amplifier. In a first step 60 a current control signal is measured. In a second step 61 the current control signal is compared with a maximum control signal. If the current actuating signal is smaller than the maximum actuating signal, in a third step 62 determines a new maximum control signal by adding a predetermined value to the current control signal. This value is chosen so that thermal influences and age-related influences can be compensated. After the determination of the new maximum control signal becomes the first step 60 continued. It is between the third step 62 and the first step 60 waited for a certain time τ. The larger τ is selected, the longer it is waited until the determination of a new maximum control signal.

Is at the second step 61 However, the current control signal is greater than the maximum control signal, so is the fourth step 63 continued. The maximum actuating signal is kept constant. In a fifth step 64 Now the amplifier is checked. This means, for example, that all subamplifiers are checked for functionality. If there is a restriction of the functionality, eg due to a defective transistor, then in a sixth step 65 depending on the result of the check out step 64 in accordance with the still possible output power, for example given by the number of still intact transistors, a new reference value, with which the entire output signal of the amplifier is compared determined. Subsequently, with the first step 60 continued. But it shows up in the fifth step 64 No limitation of functionality, so comes the third step 62 continued.

The invention is not limited to the illustrated embodiment. Any number of sub amplifiers can be used. Also amplifiers can be used, which are not Doherty amplifier. All features described above or features shown in the figures can be combined with each other in any advantageous manner within the scope of the invention.

Claims (17)

Amplifier having a first amplifier circuit (13), at least one second amplifier circuit (14) and a control circuit (31), wherein the first amplifier circuit (13) and the second amplifier circuit (14) are connected such that their output signals combine to form a total output signal (18), and wherein the control circuit (31) performs a comparison of a signal determined from the total output signal (18) with a reference value (30), the amplifier further comprising an attenuator (11) of adjustable attenuation which attenuates an input signal (10) of the amplifier, wherein the control circuit (31) based on the comparison generates a control signal (29) of the attenuator (11) and thus sets the attenuation, and wherein the control circuit (31) limits the actuating signal (29) with a maximum actuating signal. Amplifier after Claim 1 wherein the control circuit (31) determines the maximum control signal at least indirectly from previous control signals (29). Amplifier after Claim 1 or 2 , wherein the control circuit (31) sets the maximum control signal such that an overload of the first amplifier circuit (13) and / or the second amplifier circuit (14) is excluded. Amplifier after one of Claims 1 to 3 wherein the control circuit (31) regularly updates the maximum control signal. Amplifier after one of Claims 1 to 4 wherein the control circuit (31) takes into account the current value of the control signal (29) when determining the maximum control signal. Amplifier after one of Claims 1 to 5 wherein the control circuit (31) determines the maximum control signal by adding a predetermined value to the current control signal (29) if the current control signal (29) does not exceed the maximum control signal, and wherein the control circuit (31) holds the maximum control signal constant, when the current actuating signal (29) exceeds the maximum actuating signal. Amplifier after one of Claims 1 to 6 wherein the control circuit (31) includes a comparator (20, 40), a controller (21, 41), an analog-to-digital converter (25, 45) and a digital-to-analog converter (26, 46) Control means (21, 41) generates the reference value (30) and supplies it to the comparator (20, 40), the comparator (20, 40) comparing the reference value (30) with a signal derived from the total output signal (18) and the actuating signal (30) 29), wherein the analog-to-digital converter (25, 45) detects the control signal (29) and the control means (21, 41) supplies, wherein the control means (21, 41) based on the detected control signal (29), the maximum control signal determined, and wherein the control means (21, 41) by means of the digital-to-analog converter (26, 46) limits the control signal (29) generated by the comparator (20, 40) to the maximum control signal. Amplifier after Claim 7 , wherein a control signal input of the attenuator (11) to the analog-to-digital converter (25) and by means of a first diode (24) connected to an output of the comparator (20), wherein the control signal input of the attenuator (11) by means of a second diode (32) is connected to the digital-to-analog converter (26), and wherein the control signal input of the attenuator (11) by means of an ohmic resistor (27) to a supply voltage (28) is connected. Amplifier after Claim 7 wherein an output of the comparator (40) is connected to a control signal input of the attenuator, wherein the digital-to-analog converter (46) with a supply voltage input of the comparator (40) is connected, and wherein an output signal of the digital-to-analog converter (46) acts as the supply voltage of the comparator (40). Amplifier after one of Claims 1 to 9 in that the control circuit (31) is designed such that it checks the first amplifier circuit (13) and / or the second amplifier circuit (14) when the maximum control signal is exceeded by the current control signal (29), and wherein the control circuit (31 ) Defines the reference value (30) in case of failure of the first amplifier circuit (13) and / or the second amplifier circuit (14). Method for operating an amplifier with a first amplifier circuit (13) and at least one second amplifier circuit (14), wherein the output signals of the first amplifier circuit (13) and the second amplifier circuit (14) are combined to form a total output signal (18), wherein a comparison of a signal determined from the total output signal (18) and a reference value (30) is performed, wherein based on the comparison, a control signal (29) is generated, by means of which an attenuation of an input signal (10) of the amplifier is set, and wherein the actuating signal (29) is limited by a maximum actuating signal. Method according to Claim 11 wherein the maximum control signal is at least indirectly determined from previous control signals (29). Method according to Claim 11 or 12 , wherein the maximum control signal is set such that an overload of the first amplifier circuit (13) and / or the second amplifier circuit (14) is excluded. Method according to one of Claims 11 or 13 , wherein the maximum actuating signal is updated regularly. Method according to one of Claims 11 to 14 , wherein in the determination of the maximum control signal, the current value of the control signal (29) is taken into account. Method according to one of Claims 11 to 15 wherein the maximum actuating signal is determined by adding a predetermined value to the current actuating signal (29) if the current actuating signal does not exceed the maximum actuating signal, and wherein the maximum actuating signal is kept constant if the current actuating signal (29) exceeds the maximum actuating signal , Method according to one of Claims 11 to 16 , wherein when the maximum control signal is exceeded by the current control signal (29), a check of the first amplifier circuit (13) and / or the second amplifier circuit (14) is performed, and wherein in case of failure of the first amplifier circuit (13) and / or the second amplifier circuit (14) the reference value (30) is redefined.

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