KR101557823B1 - Protection circuit for transceiver module - Google Patents

Abstract

Disclosed is a protection circuit for a transmission and reception module. The protection circuit is arranged in a reception unit of the transmission and reception module, which transmits and receives signals through an antenna. The protection circuit includes: a first phase adjustment unit which performs phase retardation on a first distributed signal after receiving the first distributed signal, totally reflects the phase-retarded first distributed signal if the amplitude of the phase-retarded first distributed signal is at a level of a predetermined amplitude or at a higher level, performs phase retardation again on the totally reflected first distributed signal, and then outputs the first distributed signal with an inverted phase; a second phase adjustment unit which receives a second distributed signal and totally reflects the second distributed signal if the amplitude of the second distributed signal is at a predetermined level or at a higher level; and a first distribution coupled line which transmits the first distributed signal and the second distributed signal, generated by distributing applied signals in a circulator, to the first phase adjustment unit and the second phase adjustment unit, respectively and makes the first distributed signal and the second distributed signal be offset by each other by coupling the first distributed signal with the second distributed signal which are totally reflected by the first phase adjustment unit and the second phase adjustment unit.

Description

[0001] PROTECTION CIRCUIT FOR TRANSCEIVER MODULE [0002]

The present invention relates to a protection circuit of a transmission / reception module, and more particularly, to a protection circuit of a transmission / reception module capable of preventing a failure due to a reflected signal without deteriorating reception performance.

Most systems that transmit and receive radio signals, including antennas and transmit / receive modules, such as radar systems or communication systems, have a constant frequency range, rather than a single frequency signal, so that the mismatch between the antenna and the transmit or receive module This inevitably occurs.

1 shows an example of a system including an antenna and a transmission / reception module.

The system of FIG. 1 includes one antenna ANT and one transmission / reception module TR. The transmission and reception module TR includes a switch SW, a drive amplifier DRA, a high-power amplifier HPA, a circulator CLR, a limiter LMT, And a Low Noise Amplifier (LNA).

The switch SW selects one of a transmitting part and a receiving part of the transmission / reception module TR depending on whether a signal is to be transmitted or received. The driving amplifier DRA and the high power amplifier HPA select a gain of a signal And a transmitter for amplifying the power and transmitting the amplified power to the circulator (CLR).

The limiter LMT and the low noise amplifier LNA constitute a receiver for adjusting the level of a signal applied from the circulator CLR and transmitting the signal to the switch SW. The limiter LMT is included in the protection circuit PTC in the receiver and the limiter LMT transmits the strong power signal to the receiver in the transmitter so as to prevent the internal circuits of the transmitter / And limits the amplitudes above a predetermined level.

Like the switch SW, the circulator CLR is a circuit for selecting one of a transmitting part and a receiving part of the transmitting / receiving module TR to transmit a signal according to whether to transmit or receive a signal.

In the system as shown in FIG. 1, when a signal is transmitted, the signal applied from the switch SW is amplified by the transmitter and transmitted to the antenna ANT through the circulator CLR. However, due to mismatch between the transmission / reception module TR and the antenna ANT, a reflection signal may occur as shown in (1) of FIG. The reflected signal is transmitted to the receiver through the circulator (CLR). However, as described above, the limiter (LMT) of the receiver has a characteristic that, when a signal having an amplitude equal to or higher than a specified level is inputted, the input signal is totally reflected as in (2) in order to protect the circuit thereafter. That is, the signal applied from the circulator CLR to the limiter LMT is reflected and then transmitted to the circulator CLR. Then, the circulator (CLR) transmits the signal reflected from the limiter (LMT) to the transmitter as shown in (3).

This is a case where a signal flows in a reverse direction in contrast to a normal signal transmission path, and causes a failure of a high power amplifier (HPA) in which a reflected wave comes first in a transmission part.

Mismatching between the antenna ANT and the receiver may also occur, but this weakens the strength of the signal to be received and simply causes a performance degradation. However, the mismatch between the antenna ANT and the transmission unit causes a signal to be radiated to the outside through the antenna to be re-introduced to the transmission unit, thereby causing a failure of the high power amplifier HPA disposed at the front end of the transmission unit.

Especially in recent years, the application range of a system using a plurality of antennas arrayed like an active phased array radar and a plurality of transmission / reception modules is increasing. In a system using a planar array antenna, not only the mismatch occurring in the single antenna and the single transceiver shown in FIG. 1 but also the signals radiated from the antennas and the transceiver disposed in the vicinity are introduced and the failure of the high output amplifier (HPA) It occurs frequently. Since a high power amplifier (HPA) can not operate the system, a means for preventing failure of a high output amplifier (HPA) should be devised.

2 shows another example of a system which conventionally includes an antenna and a transmission / reception module.

Fig. 2 shows a system in which the receiving switch SW and the termination circuit TRM are added to the receiving unit in the system of Fig. 1 to prevent the failure of the high output amplifier HPA.

The receiving switch SW selects one of a limiter (LMT) or a termination circuit (TRM) according to the timing of transmission and reception of a signal to transmit a signal applied from the circulator (CLR). The receiving switch RSW selects the termination circuit TRM at the time of signal transmission so that the applied signal is canceled. At the time of receiving the signal, the limit switch LMT is selected and the received signal is transmitted to the receiving unit.

However, in the system shown in FIG. 2, a further reception switch (RSW) is disposed at the front end of the receiver, thereby increasing the noise, resulting in deteriorating the signal-to-noise ratio (SNR), which is a main index of system performance.

Korean Patent No. 10-0883398 discloses a technique of providing an impedance matching chip for impedance matching between an antenna and a transmission / reception module. However, the impedance matching chip is aimed at improving the performance by reducing the reflection signal. Furthermore, even if the impedance matching chip is provided, it is practically impossible to perfectly perform the impedance matching so that there is no reflected wave between the antenna ANT and the transmitting / receiving module. Accordingly, a method for protecting the circuit of the transmitter by the reflection signal regardless of whether the impedance matching chip is provided should be considered.

SUMMARY OF THE INVENTION It is an object of the present invention to provide a protection circuit for a transmission / reception module capable of preventing a failure due to a reflected signal without causing deterioration of reception performance.

And a transmission / reception module for achieving the object of the present invention.

According to another aspect of the present invention, there is provided a protection circuit for a transmission / reception module, the protection circuit comprising: A first phase adjuster for totaling the first distributed signal when the amplitude of the first distributed signal is greater than or equal to a predetermined reference amplitude and for outputting a phase-inverted first distributed signal by phase-delaying the totally divided first distributed signal; A second phase adjuster for receiving the second distribution signal and for totaling the second distribution signal when the amplitude of the second distribution signal is equal to or greater than the reference amplitude; The first and second phase adjusting units transmit the first and second distributed signals generated by distributing signals applied from the circulator to the first and second phase adjusting units, respectively. The first and second phase adjusting units, A first distribution coupling line coupling the second distribution signals to cancel out the first and second distribution signals to each other; .

Wherein the first phase adjusting unit comprises: a first phase delay line for delaying the phase of the first distributed signal and the first distributed signal applied from the first distributed coupling line by 90 degrees; And a first limiter that receives the first distributed signal phase-delayed through the first phase delay line, and totally divides the phase-delayed first distributed signal if the amplitude of the first distributed signal is greater than or equal to the reference amplitude; And a control unit.

Wherein the second phase adjuster includes: a second limiter for totalizing the second distribution signal when the amplitude of the second distribution signal applied from the first distribution coupling line is equal to or greater than the reference amplitude; And a first phase delay line receiving the second distribution signal that is not totally reflected by the second limiter to delay the phase by 90 degrees; And a control unit.

And the distribution-coupled line distributes the first and second distribution signals so that each of the first and second distribution signals has the same phase and 1/2 amplitude as the reception signal.

The protection circuit further includes a second distribution coupling line for receiving and coupling first and second distributed signals phase-delayed from the first distribution coupling line through the first and second phase adjusting units, respectively.

According to an aspect of the present invention, there is provided a transmission / reception module including a transmitter for receiving a transmission signal, amplifying the transmission signal, and transmitting the amplified transmission signal to an antenna; The reception signal or the transmission signal is received by the reflection signal reflected by the antenna and is divided into the received signal or the reflection signal to generate first and second distributed signals of the same phase and amplitude, A reflection unit which reflects and reflects the phase of the first distribution signal when the amplitude of the reflection signal is equal to or larger than a predetermined reference amplitude and reflects the phase difference of the second distribution signal without phase change to cancel out; A switch for selecting one of the transmission unit and the reception unit at the time of transmission according to transmission or reception timing, transmitting the transmission signal to the transmission unit, and receiving the reception signal from the reception unit at the time of reception; And selecting one of the transmission unit and the reception unit at the time of transmission according to the transmission or reception timing, transmitting the reception signal applied from the antenna to the reception unit, and transmitting the transmission signal applied from the transmission unit to the antenna cycle; .

Wherein the receiver receives and distributes the received signal or the reflected signal from the circulator to generate the first and second distributed signals, and if the applied signal is the reflected signal, the phase of the first and second distributed signals is And a control circuit for controlling the first and second distributed signals so that the phases of the first and second distributed signals are the same when the applied signal is the received signal. And a low noise amplifier for receiving the received signal and low noise amplifying the received signal and transmitting the amplified signal to the switch; And a control unit.

Therefore, the protection circuit of the transmission / reception module of the present invention does not have a noise generating element such as a switch in the receiving part, distributes and combines the signals inputted to the receiving part into a balanced structure, So that the reflected signal is canceled out by utilizing the characteristic of the limiter, and the received signal can be received without loss. Therefore, it is possible to prevent the occurrence of a failure in the circuit on the transmission part due to the reflected signal, without causing deterioration of the performance of the system.

1 shows an example of a system including an antenna and a transmission / reception module.
2 shows another example of a system which conventionally includes an antenna and a transmission / reception module.
3 illustrates a system including an antenna and a transceiver module according to an embodiment of the present invention.
Fig. 4 shows a detailed configuration of the protection circuit of Fig.

In order to fully understand the present invention, operational advantages of the present invention, and objects achieved by the practice of the present invention, reference should be made to the accompanying drawings and the accompanying drawings which illustrate preferred embodiments of the present invention.

BEST MODE FOR CARRYING OUT THE INVENTION Hereinafter, the present invention will be described in detail with reference to the preferred embodiments of the present invention with reference to the accompanying drawings. However, the present invention can be implemented in various different forms, and is not limited to the embodiments described. In order to clearly describe the present invention, parts that are not related to the description are omitted, and the same reference numerals in the drawings denote the same members.

Throughout the specification, when an element is referred to as "including" an element, it does not exclude other elements unless specifically stated to the contrary. The terms "part", "unit", "module", "block", and the like described in the specification mean units for processing at least one function or operation, And a combination of software.

FIG. 3 shows a system including an antenna and a transmission / reception module according to an embodiment of the present invention, and FIG. 4 shows a detailed configuration of the protection circuit of FIG.

In FIG. 3, similar to FIG. 1, it is assumed that the system includes one antenna ANT and one transmission / reception module TR. However, the present invention is not limited to a system having one antenna ANT and one transmission / reception module TR, but may be implemented by a plurality of antennas ANT and a plurality of antennas And a plurality of transmission / reception modules TR corresponding to the plurality of transmission / reception modules ANT. That is, the present invention can be applied to a system including a plurality of antennas ANT arranged in a plane such as an active phased array radar and a plurality of transmission / reception modules TR.

3 includes a switch SW, a drive amplifier DRA, a high power amplifier HPA, a circulator CLR, a protection circuit PTC and a low noise amplifier (LNA).

The driving amplifier DRA and the high-power amplifier HPA constitute a transmitter for amplifying the gain and power of a signal applied from the switch SW and transmitting the amplified signal to the circulator CLR as in FIG. The drive amplifier DRA amplifies the gain of the signal applied from the switch SW and the high power amplifier HPA amplifies the power of the gain amplified signal from the drive amplifier DRA.

On the other hand, a protection circuit (PTC) and a low-noise amplifier (LNA) are provided in the receiving part to adjust the level of a signal applied from the circulator (CLR) and transmit the signal to the switch (SW).

4, the protection circuit PTC includes two limiters LMT1 and LMT2, two distribution coupling lines DCL1 and DCL2, and two phase delay lines DL1 and DL2. In the protection circuit PTC, the first limiter LMT1 and the first phase delay line DL1 form a first phase adjuster, the second limiter LMT2 and the second phase delay line DL2 form a second phase adjuster, And the first phase adjusting unit and the second phase adjusting unit are connected in parallel to each other between the two distribution coupling lines DCL1 and DCL2.

That is, unlike FIG. 1, the transmission / reception module TR of the present invention is provided with two limiters LMT1 and LMT2, and the two limiters LTM1 and LMT2 are included in the protection circuit PTC.

The two distribution coupling lines DCL1 and DCL2 and the two phase delay lines DL1 and DL2 are not implemented as separate circuits or elements but are implemented in the form of transmission lines. As is well known, a signal in a high frequency band can be formed into various circuits by adjusting the width, length, and shape of a signal transmission line without using a separate element such as RLC. Therefore, it is assumed that the two distribution-coupled lines DCL1 and DCL2 and the two phase delay lines DL1 and DL2 of the present invention do not have separate elements and are implemented as transmission lines.

One end of the first distribution coupling line DCL1 is connected to the circulator CLR and the other ends of the first distribution coupling line DCL1 are connected to the first and second phase control sections respectively to divide the amplitude of the signal applied from the circulator CLR by half And transmits the divided signals to the first phase adjuster and the second phase adjuster, respectively.

On the other hand, a first phase delay line DL1 and a first limiter LTM1 are serially connected in series between the first distribution coupling line DCL1 and the second distribution coupling line DLC2, The second phase adjuster, unlike the first phase adjuster, sequentially connects the second limiter LTM2 and the second phase delay line DL2 in series. Therefore, in the first phase adjusting unit, a signal applied from the first distribution-coupling line DCL1 is transmitted to the first limiter LMT1 via the first phase delay line DL1, while in the second phase adjusting unit, A signal applied from the coupling line DCL1 is transmitted to the first phase delay line DL1 via the first limiter LMT1.

The first and second phase delay preferences DL1 and DL2 delay the phase of the received signal by 90 degrees, respectively.

The second distribution coupling line DCL2 has one end connected to the two distribution coupling lines and the other end connected to the low noise amplifier LNA to couple the signals applied from the first and second phase adjusting sections to the low noise amplifier LNA).

The operation of the protection circuit PTC in Fig. 4 can be divided into a case where a reflection signal is applied and a case where a normal reception signal is applied. First, when the reflection signal is applied, the reflected signal is applied from the circulator CLR to the first distribution coupling line DCL1. At this time, it is assumed that the amplitude is 2A and the phase is 0 ° (2A∠0 °) as shown in ① of the applied signal.

The first distribution coupling line DCL1 distributes the applied reflection signal and transmits the first and second distribution signals to the first phase adjusting unit and the second phase adjusting unit, respectively. At this time, the first and second distributed signals divided in the reflection signal are transmitted with a half of the amplitude of the reflected signal and a signal having the amplitude of A and the phase of 0 ° (A∠ 0 °), respectively. The first distributed signal transmitted to the first phase adjuster is transmitted to the first limiter LMT1 through the first phase delay preference DL1. Accordingly, as shown in (2), a signal A∠ having an amplitude of A and a phase of 90 90 DEG) is applied to the first limiter LMT1. On the other hand, since the second distributed signal transmitted to the second phase adjuster is directly transmitted to the second limiter LMT2, the signal A [theta] having the amplitude of A and the phase of 0 [ And transmitted to the limiter LMT2.

The first and second limiters LMT1 and LMT2 totally reflect the first and second distributed signals, respectively. The first distribution signal totally reflected by the first limiter LMT1 in the first phase adjuster passes through the first phase delay preference DL1 again to generate a signal A∠180 having an amplitude of A and a phase of 180 °) and is applied to the first distribution-coupling line DCL1. That is, the first distribution signal distributed in the first distribution coupling preference DCL1 is inverted in phase while being equal in amplitude, and is applied again to the first distribution coupling line DCL1. On the other hand, the second distribution signal totally reflected by the second limiter (LMT2) in the second phase adjuster is a signal with the amplitude of A and the phase of 0 DEG And is applied to the coupling line DCL1.

The first distribution control line DCL1 receives the first distributed signal having the phase inverted by the first phase adjusting unit and receives the total divided second distributed signal without phase change by the second phase adjusting unit, . Since the first and second distribution signals totally reflected by the first and second phase adjusting units are signals whose phases are inverted to the same amplitude, when they are combined, they cancel each other as shown by (4), and the signal (0∠ 0 °) disappears. That is, not sent back to the circulator (CLR). Therefore, the reflection signal can be prevented from being applied to the circuit of the transmission section.

Meanwhile, when the normal reception signal is applied, the first distributed coupling line DCL1 and the first phase delay line DL1 operate in the same manner as when the reflected signal is applied. That is, the first distribution coupling line DCL1 distributes the amplitude of the normal reception signal 2A∠0 ° received via the antenna ANT and outputs the divided signals to the first phase adjusting unit and the second phase adjusting unit, (A∠ 0 °), and the first phase delay preference DL 1 delays the phase of the applied first distributed signal by 90 ° and transmits it to the first limiter LMT 1.

Accordingly, the first limiter LMT1 is supplied with the first distribution signal A∠90 ° delayed by 90 ° and the second limiter LMT 2 is supplied with the second distribution signal A∠ 0 ° not delayed in phase Receive. Since the distribution signal for the normal reception signal is smaller in amplitude than the distribution signal for the reflection signal, the first and second limiters LMT1 and LMT2 transmit the applied first and second distribution signals intact without being reflected. Thus, in the first phase adjusting unit, the signal output from the first limiter LMT1 is applied to the second distribution coupling line DCL2 as it is with the first divided signal A∠90 ° delayed by 90 °. However, in the second phase adjusting unit, a signal output from the second limiter LMT2 is applied to the second phase delay line DL2, and a second divided signal delayed by 90 degrees is transmitted to the second distribution coupling line DCL2. As a result, the first and second distribution signals (A∠90 °) delayed by 90 ° are applied to the second distribution coupling line DCL2, and the second distribution coupling line DCL2 is supplied with the first and second distribution signals A ∠90 °), and transmits a signal (2A∠90 °) with a 90 ° phase delay, which has the same amplitude as the amplitude of the signal and the normal reception signal input to the protection circuit (PTC), to the low noise amplifier (DNA). That is, in the case of a normal received signal, only the phase is delayed by 90 degrees, and the normal received signal is directly applied to the low noise amplifier (DNA).

Referring again to FIG. 3, the low noise amplifier (LNA) receives the low power level signal received through the antenna ANT through the protection circuit PTC and transmits the signal to the switch SW.

In the above description, a signal (2A∠90 °) delayed by 90 ° is applied to the low noise amplifier (DNA). In some cases, a 270 ° phase delay A third phase delay line (not shown) may be further provided to apply a normal reception signal delayed by 360 ° to the low noise amplifier (DNA).

As a result, the protection circuit of the present invention does not have a noise generating element such as a switch on the receiving part, distributes and couples the signals inputted to the receiving part into a balanced structure, and uses two delayed lines So that the reflected signal is canceled out by utilizing the characteristic of the limiter, and the received signal can be received without loss.

Although the present invention is an invention for protecting the high power amplifier (HPA) of the transmitter in the transmission / reception module TR, the provision of the protection circuit (PTC) on the receiver part is advantageous in that the high power amplifier (HPA) And the path through which the signal flows is applied via the receiving section. Therefore, it is possible to prevent the occurrence of a failure in the circuit on the transmission part due to the reflected signal, without causing deterioration of the performance of the system.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is evident that many alternatives, modifications and variations will be apparent to those skilled in the art.

Accordingly, the true scope of the present invention should be determined by the technical idea of the appended claims.

Claims (11)

A protection circuit for a transmission / reception module provided in a reception part of a transmission / reception module for transmitting / receiving a signal through an antenna,
The first distributed signal is phase-delayed, the total delayed first distributed signal is phase-delayed if the amplitude of the first distributed signal is greater than or equal to the preset reference amplitude, and the phase-inverted first distributed signal is output A first phase adjusting unit for adjusting a phase of the phase-
A second phase adjuster for receiving the second distribution signal and for totaling the second distribution signal when the amplitude of the second distribution signal is equal to or greater than the reference amplitude; And
Wherein the first and second phase adjusting units transmit the first and second distributed signals generated by distributing a signal applied from the circulator to each of the first and second phase adjusting units, A first distribution coupling line coupling the two distribution signals to cancel out the first and second distribution signals to each other; Lt; / RTI >
The first phase adjuster
A first phase delay line for delaying the phase of the first distributed signal and the first distributed signal applied from the first distributed coupling line by 90 degrees; And
A first limiter which receives the first distributed signal phase-delayed through the first phase delay line and totally divides the phase-delayed first distributed signal if the amplitude of the first distributed signal is greater than or equal to the reference amplitude; / RTI >
The second phase adjuster
A second limiter for totalizing the second distribution signal when the amplitude of the second distribution signal applied from the first distribution coupling line is equal to or greater than the reference amplitude; And
A second phase delay line that receives the second distribution signal that is not totally reflected by the second limiter and delays the phase by 90 degrees; And a protection circuit for protecting the transmission / reception module. delete delete 2. The apparatus of claim 1, wherein the distribution-
And distributes the first and second distribution signals so that each of the first and second distribution signals has the same phase and 1/2 amplitude as the reception signal. 2. The circuit of claim 1, wherein the protection circuit
And a second distribution coupling line for receiving and coupling the first and second distribution signals phase-delayed from the first distribution coupling line through the first phase adjusting unit and the second phase adjusting unit, respectively, Protection circuit of the module. A transmitter for receiving a transmission signal, amplifying the amplified transmission signal, and transmitting the amplified transmission signal to an antenna;
The reception signal or the transmission signal is received by the reflection signal reflected by the antenna and is divided into the received signal or the reflection signal to generate first and second distributed signals of the same phase and amplitude, A reflection unit which reflects and reflects the phase of the first distribution signal when the amplitude of the reflection signal is equal to or larger than a predetermined reference amplitude and reflects the phase difference of the second distribution signal without phase change to cancel out;
A switch for selecting one of the transmission unit and the reception unit at the time of transmission according to transmission or reception timing, transmitting the transmission signal to the transmission unit, and receiving the reception signal from the reception unit at the time of reception; And
And a transmission unit for selecting one of the transmission unit and the reception unit at the time of transmission according to the transmission or reception timing and transmitting the reception signal applied from the antenna to the reception unit, ; Lt; / RTI >
The receiving unit
The first and second distribution signals are generated by distributing the reception signal or the reflection signal from the circulator so that the phases of the first and second distribution signals are inverted if the applied signal is the reflection signal, A protection circuit for adjusting and outputting the first and second distributed signals so that the phases of the first and second distributed signals are the same if the applied signal is the received signal; And
A low noise amplifier for receiving the received signal and low noise amplifying the received signal and transmitting the amplified signal to the switch; Lt; / RTI >
The protection circuit
The first distribution signal is phase-delayed, the total delay is delayed when the amplitude of the first distributed signal is retarded to be equal to or greater than a preset reference amplitude, the phase-delayed first distribution signal is phase- A first phase adjuster for outputting the phase difference;
A second phase adjuster for receiving the second distribution signal and for totaling the second distribution signal when the amplitude of the second distribution signal is equal to or greater than the reference amplitude; And
Wherein the first and second phase adjusting units transmit the first and second divided signals generated by distributing a signal applied from the circulator to each of the first and second phase adjusting units, A first distribution coupling line coupling the second distribution signals to cancel out the first and second distribution signals to each other; / RTI >
The first phase adjuster
A first phase delay line for delaying the phase of the first distributed signal and the first distributed signal applied from the first distributed coupling line by 90 degrees; And
A first limiter which receives the first distributed signal phase-delayed through the first phase delay line and totally divides the phase-delayed first distributed signal if the amplitude of the first distributed signal is greater than or equal to the reference amplitude; Lt; / RTI >
The second phase adjuster
A second limiter for totalizing the second distribution signal when the amplitude of the second distribution signal applied from the first distribution coupling line is equal to or greater than the reference amplitude; And
A second phase delay line that receives the second distribution signal that is not totally reflected by the second limiter and delays the phase by 90 degrees; Receiving module. delete delete delete delete 7. The apparatus of claim 6, wherein the protection circuit
And a second distribution coupling line that receives and distributes first and second distributed signals phase-delayed from the first distributed coupling line through the first phase adjusting unit and the second phase adjusting unit, respectively, and transmits the first and second distributed signals to the low noise amplifier Receiving module.

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