KR100318953B1 - Method for compensating of received signal strength indicator - Google Patents

Abstract

The present invention relates to a method for compensating deviation for each set of reception strengths of a wireless terminal, and reads a code value at a specific power to collectively compensate mode power according to the slope of each input strength.

Description

How to compensate for variation in reception strength in wireless terminal {METHOD FOR COMPENSATING OF RECEIVED SIGNAL STRENGTH INDICATOR}

The present invention relates to a wireless terminal, and more particularly, to a method for compensating for variation in reception strength of a receiver for each wireless terminal during mass production.

Currently, most wireless terminals perform closed loop power control to check the current field situation through communication with the base station, and adjust the wireless transmit amplification degree according to the checked field situation so that the minimum power is used.

In general, a wireless terminal receives a signal received through an antenna as shown in FIG. 1 through a low noise amplifier 110 that minimizes and amplifies noise, passes through a low pass filter 120, and a low frequency through a mixer 130. One frequency conversion into band. After checking the state of the signal converted to the low frequency band to measure the strength of the received signal through the BBA 170 to check the field situation, the MSM 180 according to the measured strength of the received signal of the wireless terminal By controlling the automatic gain adjuster 160 that automatically adjusts the gain of the control of the strength of the received signal appropriately. At this time, the control code for controlling the automatic gain adjuster 160 according to the checked strength of the received signal is tabled, and is a control code for setting the gain of the automatic gain adjuster 160. This control code consists of 16 offsets and slopes in a table called RAS (RF Analog Substem) RAM.

FIG. 2A shows the OPEN LOOP AGC AMP GAIN characteristic of the actual board. The segment offset and the slope are control codes stored in the RAS RAM to compensate for this. This controlled plot shows the gain characteristics of the linear AGC AMP.

Referring to FIG. 2A, the segment SEGENT is placed on the horizontal axis and the output value of the actual AGC gain is shown on the vertical side.

FIG. 2B shows the linear characteristics of the upper and lower parts of the segment by changing the actual control code when the conventional algorithm of FIG. There is a problem that some errors occur without being seen.

3 shows a process of compensating the conventional reception strength.

Referring to FIG. 3, in step 301, the MSM 180 enters a test mode, and in step 303, the MSM 180 enters the actual measured power at a specific power (actually, a portion of the most linear region, eg, −90 dBm). Read the corresponding code value (eg: 50). In step 305, the MSM 180 subtracts a value previously stored corresponding to the specific power from the read code value (for example, a value corresponding to −90 dBm is 48), thereby receiving a set intensity difference (rf_offset_rssi). Find and initialize the segment (segment = 0). In step 307, the MSM 180 determines whether a reference reception intensity deviation has occurred. (Rf_offset_rssi = 0?) Here, if there is a difference between a code value actually read at the specific power and a previously stored value, There is a deviation of the reference reception strength. If it is determined that the deviation of the reference reception intensity has occurred, in step 309, the MSM 180 determines whether the segment is greater than or equal to 16. If the segment is smaller than 16, in step 311, the MSM 180 compensates for the variation in the reception strength by subtracting the reception strength deviation from the offset value corresponding to the segment and stores the variation in the reception strength in the RAS RAM table. The MSM 180 increases the segment value by 1 and performs the operation from step 309 again. That is, the MSM 180 stores the compensation of the deviation of the reception strength for all the powers in the total 16 tables by subtracting only the deviation (rf_offset_rssi) of the reception strength generated at the specific power.

If there is no variation in reception strength, in step 313, the MSM 180 determines whether the segment is greater than or equal to 16. If the segment is smaller than 16, in step 315, the MSM 180 stores the offset value corresponding to the segment in the RAS RAM table. The MSM 180 increases the segment value by 1 and performs the operation from step 313 again. That is, the MSM 180 writes the offset values for the 16 segments as they are in the RAS RAM as long as there is no variation in reception strength.

However, the conventional compensation method may be correct in one part (-90dBm) actually measured when subtracting all 16 tables from the offset value, but may not fit in the part where the slope is wrong as shown in FIG. 2B. There is a problem that the compensation of the deviation of each set is not properly made.

As described above, the conventional compensation method collectively compensates the error measured at one point among all the specific points in all 16 tables so that the compensation may be overcompensated or insufficient compensation to compensate for the actual set deviation. There is a problem that this is not done properly.

Accordingly, an object of the present invention is to provide a method of compensating reception strength in consideration of gain characteristics of an automatic gain adjustment amplifier in a wireless terminal.

Another object of the present invention is to provide a method of compensating reception intensity according to a characteristic of a slope in order to minimize the occurrence of a set-by-set deviation in a wireless terminal.

In order to achieve these objects, the present invention provides a method of reading an actual code value for a reference power in a test mode, comparing the read code value with a value already stored for the power, and a deviation in the comparing step. When the deviation occurs, the step of calculating the deviation of the reference received strength in consideration of the deviation and the deviation portion according to each slope in the offset to compensate for the received strength, characterized in that the step of storing in the memory.

1 is a schematic configuration diagram of a wireless terminal to which the present invention is applied.

2A is a diagram showing the gain of a typical automatic gain amplifier.

2B is a diagram showing a gain of an automatic gain amplifier due to a conventional deviation.

3 is a diagram illustrating a process of compensating a conventional reception strength.

4 is a diagram illustrating a process of compensating reception strength according to the present invention.

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

4 illustrates a process of compensating reception strength according to the present invention.

1 and 4, in step 401, the MSM 180 enters a test mode and in step 403 reads and stores an actual code value corresponding to a reference power (eg, −90 dBm). In operation 405, the MSM 180 determines a difference between the code value read from the reference power and a code value (for example, 48) previously stored in correspondence with the reference power, and the deviation of the reference reception intensity (rf_offset_rssi). ), And set the initial value of the segment to '0'. In step 407, the MSM 180 determines whether the reference reception intensity deviation (rf_offset_rssi) value becomes '0'. If it is determined that the reference reception strength deviation is not '0', the MSM 180 determines whether the segment is greater than or equal to '16' in step 409. If it is determined that the segment is not greater than or equal to '16' (small), in step 411, the MSM 180 determines a slope value of the reference power and a slope value of the increased segment. [segment]) is compared to determine whether they are equal. If it is determined that the inclination value in the reference power is not equal to the inclination value of the increased segment, in step 413, the MSM 180 subtracts the reception intensity deviation from the offset value corresponding to the segment, thereby causing the deviation of the reference reception intensity (rf_offset_riss). ) And store it in the RAS RAM table. On the contrary, if it is determined that the inclination value in the reference power is equal to the inclination value of the increased segment, in step 415, the MSM 180 may determine {reference reception intensity deviation and (inclination of the segment) in the offset value corresponding to the segment. Value is multiplied by the slope value corresponding to the reference value), and stored in the RAS RAM. (RAS RAM [] = offset [segment] -rf_offset_rssi * slope [segment] / slope [reference value]) Since the slope value of the segment is different for each segment, the variation in reception intensity is compensated by considering the slope value of each segment and the slope value of the reference value in which the reference reception intensity deviation is measured. In step 417, the MSM 180 increments the segment by one (segment ++).

On the other hand, if there is no variation in reception strength, in step 419, the MSM 180 determines whether the segment is greater than or equal to 16. If the segment is smaller than 16, in step 421, the MSM 180 stores the offset value corresponding to the segment in the RAS RAM table. In addition, the MSM 180 increases the segment value by 1 and performs the operation from step 419 again. That is, the MSM 180 writes the offset values for the 16 segments as they are in the RAS RAM as long as there is no variation in reception strength.

As described above, the present invention can solve the problem that the code values for adjusting the reception strength for each set and the automatic gain controller do not fit well for each input power, which are caused by component deviations during mass production of the wireless terminal. Therefore, the present invention can improve the reception performance in the wireless terminal, and can reduce the error even in the closed loop power control, thereby improving the transmission and reception performance.

Claims (3)

In the reception strength compensation method in a wireless terminal, A first step of reading and storing the actual code for the reference power in the test mode; A second process of comparing a code value read for the reference power with a value already stored corresponding to the reference power; A third step of comparing a slope value of the current segment with a slope value corresponding to the reference power when there is a difference between the code value read for the reference power and the stored value; And if it is determined that the slope value of the current segment is different from the slope value corresponding to the reference power, a fourth process of compensating for the deviation of the reception intensity in consideration of the deviation of the slope. The method of claim 1, wherein the fourth process, And compensating for the variation in the reception intensity by reflecting the slope value of the current segment and the slope value corresponding to the reference power in the standard reception intensity deviation. The method of claim 2, wherein the fourth process, The method of claim 1, characterized in that for compensating for the variation in the received intensity. offset [segment] -rf_offset_rssi * slope [segment] / slope [reference value] offset [segment]: offset value of the current segment rf_offset_rssi: deviation of reference reception strength slope [segment]: slope of the current segment slope [reference value]: slope value of the reference power