KR20040032672A - Received using forward cancellation techniques - Google Patents

Abstract

1. The technical field to which the invention described in the claims belongs

The present invention relates to a receiver for reception interference signal and transmission leakage power cancellation.

2. The technical problem to be solved by the invention

According to the present invention, the performance of the receiver can be improved by eliminating neighboring reception interference signals, which are components that may degrade the reception sensitivity by disturbing the normal operation of the receiver or transmission signals leaking to the reception path during the transmission operation, by using a forward cancellation technique. Its purpose is to provide a receiver for improvement.

3. Summary of Solution to Invention

The present invention provides a receiver using a forward cancellation technique, comprising: directional coupling means for separating a received signal, a transmitted leakage power signal, and an interference signal input from an antenna into two paths; Main processing means for amplifying a desired received signal and an interference signal among the signals separated by the directional coupling means, and reducing a transmission leakage power signal; The desired received signal of the separated signals is suppressed, and the transmission leakage power signal and the interference signal are additional processing means for changing the transmission leakage power signal and the interference signal of the main processing means into a signal having a magnitude and an inverse phase. ; And combining the signals passing through the main processing means and the signals passing through the additional processing means, thereby providing a separation means for removing the canceled portion and passing only the desired received signal.

4. Important uses of the invention

The invention is used in a receiver.

Description

Received using forward cancellation techniques

The present invention relates to a receiver for reception interference signal and transmission leakage power cancellation.

In all communication systems including wireless mobile communication, the reception level received through the antenna is so weak that it is very sensitive to the influence of external and internally generated signals.

Components that can reduce the reception sensitivity or cause a condition that is impossible to talk include spurious signals including interference signals, video signals, IF beat components, and transmission leakage power. The effects of these signals on the receiver can be classified into four categories.

First, assuming two practical examples due to the influence of two or more large interfering signals in adjacent bands, the first example is a digital broadcast channel located at the edge of the transmission service area in a commercially available digital broadcast system. The reception level of is insignificant. In this case, when there is a large analog broadcast channel adjacent to this channel and flows into the digital broadcast tuner, and as a second example, the base station in a CDMA cellular mobile system The reception level of the mobile terminal at the edge of the cell is at its lowest state when there is an analog cellular base station or a base station for a digital trunked radio system (TRS) operating in the vicinity. In both cases, when a large amount of interference signal is introduced into the digital broadcast tuner and the CDMA terminal, the low noise amplifier and the mixer of the RF pre-stage may be saturated, and thus, the digital broadcast reception or the terminal call may not be possible.

Secondly, two or more large interfering signals in adjacent bands pass through a nonlinear circuit such as a low noise amplifier so that intermodulation components by these components are present in the receive passband in use, making it impossible to filter, resulting in poor reception sensitivity. If it is.

The third case is a case where a signal corresponding to a video signal, an IF Beat component, and a spurious component of a receiver is introduced or generated by the receiver to be frequency-converted into a reception passband including desired information to reduce reception sensitivity.

Fourthly, there is a case where the low noise amplifier is saturated due to the transmission leakage power and the reception sensitivity is lowered.

Meanwhile, several methods for solving the above four problems have been proposed. FIG. 1 is a schematic diagram of a typical heterodyne receiver, in which a spurious component caused by a video signal and a local power is removed after a low noise amplifier. Image Rejection Filter (IRF) is used to suppress the video signal and the leaked local power components, and the transmit / receive separation characteristics of the duplexer are used to suppress the transmission leakage power.

However, it is difficult to remove the strong interference signal existing in the adjacent band, which may cause the intermodulation component to exist in the reception pass band.

FIG. 2 is a block diagram of another embodiment of a general heterodyne receiver. In addition to the function of FIG. 1, when a signal level received by an antenna is above a predetermined level, that is, when an interference signal is present, the signal is bypassed through a low noise amplifier. A method of maintaining a minimum call by preventing the saturation of the mixer through the attenuation effect of the signal level corresponding to the gain of the low noise amplifier has been proposed.

While this method has the advantage of using the existing receiver circuit, the most fundamental disadvantage is that the receiver's reception sensitivity is deteriorated, which may result in frequent deterioration of call quality and disconnection.

FIG. 3 is a block diagram of another embodiment of a general heterodyne receiver, using a tracking filter for selecting a broadcast channel at a tuner (receive) front end to suppress interference signals by adjacent bands and converting a dual frequency through frequency up Suppresses the video signal and the IF Beat component using. However, this method requires additional apparatus for frequency mapping between the tracking filter and the voltage controlled oscillator due to the widening of the broadcast frequency band.

That is, the conventional receivers proposed above have many filters required for suppressing the interference signal and the like mentioned above, and their specifications are difficult, so that they are difficult to integrate with other elements (antennas and amplifiers). There is a problem that it is difficult to implement the miniaturization and low cost of the RF pre-stage increasingly required in terms of.

The present invention is to solve the above-mentioned conventional problems, and the reception interference signal of the adjacent band, which is a component that can deteriorate the reception sensitivity by disturbing the normal operation of the receiver or the transmission signal leaked to the reception path during the transmission operation, It is an object of the present invention to provide a receiver for improving the performance of the receiver by canceling using a forward cancellation technique.

1 is a block diagram of a typical heterodyne receiver.

Figure 2 is a general heterodyne receiver configuration of another embodiment.

Figure 3 is another embodiment of a general heterodyne receiver configuration.

4 is a diagram illustrating an embodiment of a receiver using a forward cancellation technique in accordance with the present invention.

Figure 5 is an embodiment frequency spectrum showing a process of removing the transmission leakage power signal when using the present invention.

Figure 6 is an embodiment frequency spectrum showing a process of removing the received interference signal of the adjacent band when using the present invention.

In order to achieve the above object, the present invention provides a receiver using a forward cancellation technique, comprising: directional coupling means for separating a received signal, a transmitted leakage power signal, and an interference signal input from an antenna into two paths; Main processing means for amplifying a desired received signal and an interference signal among the signals separated by the directional coupling means, and reducing a transmission leakage power signal; The desired received signal of the separated signals is suppressed, and the transmission leakage power signal and the interference signal are additional processing means for changing the transmission leakage power signal and the interference signal of the main processing means into a signal having a magnitude and an inverse phase. ; And separating means for combining the signals passing through the main processing means and the signals passing through the additional processing means, removing the canceled portion and passing only the desired received signal.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

4 is a diagram illustrating an embodiment of a receiver using a forward cancellation technique according to the present invention.

As shown in the figure, a receiver using a forward cancellation technique according to the present invention (generating signals having the same magnitude and out of phase with these signals by using a phase shifter and a delayer) has a general heterodyne receiver structure. B) a directional coupler 402 and a delay line 406 are added to the receiver structure of the direct conversion method, and additionally, variable gain amplifiers (VGAs) 409 and 412 and phase shifters 408 and 411. It consists of two forward loops consisting of a back and the like.

In this case, a portion including the low noise amplifier 403, the reception band pass filter 404, the RF amplifier 405, and the delayer 406 shown in the drawing is referred to as a main processing unit, and the band pass filters 407 and 410 and the phase shifter. The part including the crises 408 and 411 and the variable gain amplifiers 409 and 412 is called an additional processing unit. In addition, the subtraction circuit 413 is referred to as a separation unit as a circuit for removing (subtracting) portions that cancel each other by combining signals transmitted from the main processing means and the additional processing means. In this case, the switch 314 operates in the ON state using the following elimination technique.

5 is an embodiment frequency spectrum showing a process of removing the transmission leakage power signal when using the present invention, Figure 6 is an embodiment frequency spectrum showing a process of removing the received interference signal of the adjacent band when using the present invention to be.

Hereinafter, a transmission leakage power cancellation scheme will be described with reference to FIGS. 4 and 5, and an interference signal cancellation scheme will be described with reference to FIGS. 4 and 6.

First, the transmission leakage power cancellation method is described as follows.

When the transceiver is in normal operation, the desired signal received through the antenna 401 and the transmission leakage power generated by the transmitter when the signal is transmitted are transmitted / received by the dual-feed antenna 401 as shown in FIG. The transmission leakage power is reduced by the separation characteristic (<-20 dB or so).

These two signals are then separated via the directional coupler 402 through the existing main path (main processing unit) and additional forward loops (additional processing unit).

First, a low noise amplifier (LNA) 403, a receive band pass filter 404, and an RF amplifier 405 through the main path, the desired received signal is low noise amplified, and the unwanted transmit leakage power is passed through the pass band filter 404 As a result, the desired received signal is amplified and the transmit leakage power is slightly reduced.

Next, an additional forward loop samples (<-10 dB) the desired received signal and transmit leakage power through a coupling port of the directional coupler 402 and has a spectrum as shown in FIG.

These signals then pass through bandpass filter 407 and the desired received signal is suppressed (<-42 dB), passing only the transmit leakage power signal separately.

Then, the transmission leakage frequency component sampled through the phase shifter 408 is adjusted so that the phase is reversed to have a spectrum as shown in FIG. 5D, and then to equalize the magnitude of the transmission leakage power of the forward loop and the main path. After going through a variable gain amplifier 409 (VGA), it has the same frequency spectrum as E of FIG. 5 (a signal having the same magnitude as B of FIG. 5 and having a reversed phase).

The signal output through the forward loop (E of FIG. 5) is a transmission signal (B of FIG. 5) originally leaked to the receiver main path, a subtraction circuit 413, and a delayer 406, a delay line, and a signal by the main path. If the time passed by adjusting the delay), only the desired received signal exists as shown in F of FIG. 5 to effect the transmission leakage power signal by the transmitter pre-end 420 (Tx-FE, Transmitter Front-End). Can be removed.

Next, the interference cancellation scheme is described as follows.

If the desired signal received through the antenna 401 and a large level RF signal of a reception adjacent band are applied during normal operation of the receiver, these two signals will have a spectrum as shown in FIG.

The two signals are then separated through the directional coupler 402 through the main path and an additional forward loop, as described in the transmit leakage power cancellation scheme.

First, through the low noise amplifier 403, the band pass filter 404, and the RF amplifier 405 of the main path, the desired reception signal and the interference signals of adjacent bands including the same as shown in B of FIG. will be.

Next, the additional forward loop samples (<-10 dB) the desired received and interfering signals through the coupling terminal of the directional coupler 402 to have a spectrum such as C 'in FIG.

Then, these signals pass through the bandpass filter 410, and the desired received signal is suppressed, and only interference signals in adjacent bands are separated.

The frequency component of the interfering signal sampled through the phase shifter 411 is then adjusted so that the phase is reversed to have a spectrum such as D 'of FIG. 6, and then the magnitude of the interfering signal of adjacent bands in the forward loop and the main path is adjusted. After going through the variable gain amplifiers 412 and VGA to be equal, they have a frequency spectrum as shown in E ′ of FIG. 6.

The interference signal output through the forward loop (E ′ of FIG. 6) is originally applied to the receiving end main path, and the amplified interference signal (B of FIG. 6), the subtraction circuit 414, and the delayer 406 are adjusted. As shown in F of 6, only a desired reception signal exists to remove the influence of the interference signal in the adjacent band.

The present invention described above is not limited to the above-described embodiments and the accompanying drawings, and various substitutions, modifications, and changes are possible in the art without departing from the technical spirit of the present invention. It will be clear to those of ordinary knowledge.

The present invention as described above has an excellent effect that it is possible to eliminate the interference signal of the adjacent band and the leakage power by the transmitter without deteriorating the performance of the receiver, that is, normal reception operation.

In addition, it is possible to replace some functions of the duplexer, which is difficult to integrate, and it is also applied to the active integrated antenna technology, which enables the miniaturization and low-cost RF predistortion.

That is, when the present invention is applied to a reception system that is used in adjacent bands and similar frequency bands, the interference signal introduced through the receiving antenna is a phase shifter, a band pass filter, a variable gain amplifier and a subtraction circuit in a forward loop through a directional coupler. It can be removed through the to maintain the reception performance, there is an excellent effect that the transmission leakage power suppression is possible at the same time during the transmitter operation through another forward loop.

In addition, it is possible to partially replace the existing duplexer function (the role of suppressing out-of-band component and transmitting / receiving leakage power by transmission signal during transmitter operation), thus transmitting / receiving pre-end including Tx / Rx Active integrated antenna technology can be partially applied to fabricate the front-end on a single board, and the RF front end can be realized with the miniaturization, low cost, and light weight of the system.

Claims (3)

In a receiver using a forward cancellation technique, Directional coupling means for separating the received signal, the transmitted leakage power signal, and the interference signal input from the antenna into two paths; Main processing means for amplifying a desired received signal and an interference signal among the signals separated by the directional coupling means, and reducing a transmission leakage power signal; The desired received signal of the separated signals is suppressed, and the transmission leakage power signal and the interference signal are additional processing means for changing the transmission leakage power signal and the interference signal of the main processing means into a signal having a magnitude and an inverse phase. ; And Separating means for combining the signals passing through the main processing means and the signals passing through the additional processing means to remove the canceled portion and pass only the desired received signal. Receiver using a forward cancellation technique comprising a. The method of claim 1, The main processing means, A low noise amplifier for low noise amplifying a received signal and an interference signal among the signals separated by the directional coupling means; A passband filter for reducing a transmission leakage power signal among the signals separated by the directional coupling means; An RF amplifier for amplifying the received and interfering signals passing through a low noise amplifier and a passband filter; And A delayer for delaying the output time of the signals passing through the RF amplifier to match the output time of the signals output from the additional processing means Receiver using a forward cancellation technique comprising a. The method according to claim 1 or 2, The additional processing means, A bandpass filter for suppressing a desired received signal among the signals separated by the directional coupling means, and separately passing a transmission leakage power signal and an interference signal; A phase shifter for reversing phases of the transmit leakage power signal and the interference signal; And A variable amplifier for equalizing the leakage power signal and the interference signal with the magnitudes of the transmission leakage power signal and the interference signal of the main processing means Receiver using a forward cancellation technique comprising a.