KR100561617B1 - Apparatus and method for measuring received singal strength indicator using simple hardware architecture, and recording medium storing program embodying the same method - Google Patents

Abstract

The present invention relates to a Received Signal Strength Indicator (RSSI) measuring apparatus and method thereof that are simple to implement, and a recording medium storing a program for implementing the method. In this RSSI measuring apparatus, an analog / digital converter generated when the probability density function of an input signal and an output signal of a analog / digital converter that quantizes an I-channel signal and a Q-channel signal is approximated to a Gaussian having an average of 0. Based on the first relationship between the variance of the output signal and the variance of the input signal and the second relationship between the variance and the power in the probability density function of the Gaussian random variable, the power at the input of the analog / digital converter The signal is calculated using the signal at the output of the digital converter to determine the received signal strength. According to the present invention, hardware complexity is reduced since the square operation is not performed for every sample of the signal received through the receiving antenna. In addition, by measuring the RSSI at the connector of the receiving antenna, RSSI measurement closer to actual is performed. In addition, it is possible to know how many Watts or mWatt the exact value of the measured RSSI.

RSSI, ADC, received signal strength, analog / digital converter, Gaussian, probability density function,

Description

A simple measuring device and method for recording the same, and a recording medium storing a program for implementing the method, and a recording medium storing a program for implementing the method, and a recording medium storing the recording method. ≪ [RTI ID = 0.0 > APRATUS AND METHOD FOR MEASURING RECEIVED SINGAL STRENGTH INDICATOR

1 is a block diagram of a conventional RSSI measurement apparatus.

FIG. 2 is a diagram illustrating a general input / output relationship between the I channel and the Q channel ADCs shown in FIG. 1.

3 is a block diagram of an apparatus for measuring RSSI according to a first embodiment of the present invention.

4 is a block diagram of an RSSI measurement apparatus according to a second embodiment of the present invention.

5 is a block diagram according to an embodiment of the computer system shown in FIG. 4.

6 is a flowchart of a RSSI measuring method according to a second embodiment of the present invention.

The present invention relates to measurement of received signal strength indicator (hereinafter referred to as "RSSI"), and more specifically, RSSI using a simpler structure by converting the input power of an analog-to-digital converter using an output signal. An apparatus and method for measuring the same, and a recording medium storing a program for implementing the method.

Recently, due to the development of various wireless networks including mobile communication, many people live more active lives than before.

An important role in such wireless communication is to support the mobility of users. That is, even if the location of the terminal of the user moves, to maintain the communication path to maintain the wireless communication service for the user. As such, RSSI, a signal for detecting a level of a signal received from a wireless communication terminal, plays an important role in supporting mobility in wireless communication. Naturally, RSSI can be used for various functions.

1 is a block diagram of a conventional RSSI measurement apparatus.

As shown in FIG. 1, the conventional RSSI measuring apparatus includes a receiving antenna 10, an I-channel analog / digital converter (hereinafter referred to as “ADC”) 20, and Q ( Quadrature) channel ADC 30, I channel squarer 40, Q channel squarer 50, accumulator and dumper 60, and averager 70.

The receiving antenna 10 receives a radio signal transmitted from a base station through a wireless channel, and the I channel and Q channel ADCs 20 and 30 receive an I channel signal I (t) received through the receiving antenna 10. And converts the Q channel signal Q (t) into corresponding digital signals I _k and Q _k .

The I and Q channel squarers 40 and 50 square the digital I and Q channel signals I _k and Q _k respectively output from the I and Q channel ADCs 20 and 30, respectively, to correspond to the corresponding power signals. Outputs

The accumulator and dumper 60 receives power signals output from the I channel and Q channel squarers 40 and 50, respectively, and accumulates them for a predetermined period.

The averager 70 outputs a signal obtained by measuring the RSSI by averaging the signals accumulated in the accumulator and the dumper 60.

As such, the RSSI obtained by the conventional RSSI measuring apparatus illustrated in FIG. 1 may be expressed as Equation 1 below.

Here, N denotes the number of samples within a certain period accumulated in the accumulator and dumper 60, and the subscript k means the order of the samples within the predetermined period.

According to the RSSI obtained according to the prior art, it has only a functional relationship with the actual RSSI, and it is impossible to know with certainty that the intensity of the power actually received by the wireless terminal is a value, that is, how many Watts or mWatts, and also the I channel. In the Q channel squarers 40 and 50, a multiplier is required to obtain a power value for every sample for a certain period of time, thereby increasing the hardware complexity.

On the other hand, the prior art related to the ADC as described above is US Patent US 5,675,339 "A / D REFERENCE LEVEL ADJUSTMENT CIRCUIT TO MAINTAIN OPEIMUM DYNAMIC RANGE AT THE A / D", US Patent US3,931,584 "AUTOMATIC GAIN CONTROL" .

The former patent relates to a method and circuit for controlling the reference voltage of the ADC and there are methods for indicating whether the ADC output is at least at the required voltage level. There is a processor that provides a reference voltage to the ADC according to the displayed value, and the processor requires that the supply voltage be increased when the I and Q ADC voltages are lower than the reference value, and the supply voltage is lowered when it is above the reference value. However, the former patent only discloses a method for accurately providing a reference voltage of the ADC, and there is no disclosure of a simple and accurate measurement of RSSI.

In addition, the latter patent relates to a method of minimizing the quantization noise of an ADC, in which the AGC, which serves to convert a signal with a significant change in signal power level, into a constant level of signal power level, is the power level of the ADC input signal. It is only disclosed to keep the constant size to minimize the quantization noise of the ADC, and there is no disclosure of a simple and accurate measurement of RSSI like the previous patent.

Therefore, the technical object of the present invention is to solve the above problems, the hardware implementation is simple, RSSI measurement apparatus and method and method that can accurately know how many watts or mWatt RSSI value measured, and the method The present invention provides a storage medium for storing a program.

In order to achieve the above object, a reception signal strength measuring apparatus according to a feature of the present invention,

An apparatus for measuring received signal strength of a signal transmitted and received in a wireless communication network,

An analog / digital converter for quantizing any one of an I (In-Phase) channel signal and a Q (Quadrature) channel signal extracted from a signal received from a wireless communication network into a digital signal; An absolute value calculator for calculating and outputting an absolute value of the digital signal quantized by the analog / digital converter; An accumulator for accumulating and outputting a value output from the absolute value calculator for a predetermined period of time; A squarer which squares a value output from the accumulator and outputs the squared value; And a specific value to a value output from the squarer, wherein the specific value approximates a probability density function of an input signal and an output signal of the analog / digital converter to a Gaussian having an average of 0, and the analog / digital converter. Determined based on the number of input bits, the input clip level and the inlet resistance of the multiplier, and outputs the received signal strength of the received signal.

Received signal strength measuring apparatus according to another aspect of the present invention,

An apparatus for measuring received signal strength of a signal transmitted and received in a wireless communication network,

An analog / digital converter for quantizing any one of an I (In-Phase) channel signal and a Q (Quadrature) channel signal extracted from a signal received from a wireless communication network into a digital signal; An absolute value calculator for calculating and outputting an absolute value of the digital signal quantized by the analog / digital converter; An accumulator for accumulating and outputting a value output from the absolute value calculator for a predetermined period of time; And receiving a value output from the accumulator and performing a square operation and a specific value, wherein the specific value approximates a probability density function of an input signal and an output signal of the analog / digital converter to a Gaussian having an average of 0. And a computer system for performing a multiplication operation, determined based on the number of input bits, input clip level, and inlet resistance of the analog-to-digital converter, to calculate the received signal strength of the received signal.

Here, the received signal strength measuring device,

And receiving a signal from a wireless communication network and outputting the signal to the analog / digital converter, wherein the gain from the reception antenna to the analog / digital converter is used when determining the specific value.

In addition, the variance of the output signal of the analog-to-digital converter is determined by multiplying the variance of the input signal of the analog-to-digital converter by a value determined by the number of input bits and the input clip level of the analog / digital input signal. .

In addition, the power of the output signal of the analog-to-digital converter is characterized in that determined based on the dispersion of the output signal of the analog-to-digital converter.

Received signal strength measuring method according to another aspect of the present invention,

A method of measuring received signal strength of a signal transmitted and received in a wireless communication network,

a) a cumulative value for measuring the strength of a signal received in a wireless communication network, wherein the cumulative value is a period of time for which one of an in-phase channel signal and a quadrature channel signal extracted from the received signal is received; Receiving an absolute value by quantizing the digital signal while the absolute value is accumulated; b) performing a square operation on the input cumulative value; And c) a specific value for the squared value, wherein the specific value approximates a probability density function of an input signal and an output signal of an analog / digital converter for quantizing the received signal into a digital signal to a Gaussian having an average of 0. And if yes, performing a multiplication operation, determined based on the number of input bits, input clip level, and inlet resistance of the analog-to-digital converter, to calculate the received signal strength of the received signal.

Here, the received signal measuring method,

Before the step a), extracting one of an I (In-Phase) channel signal and a Q (Quadrature) channel signal from the signal received in the wireless communication network and quantizing it into a corresponding digital signal; Calculating an absolute value of the quantized signal; And accumulating the calculated absolute value for the predetermined period and outputting a cumulative value.

In addition, the gain from the receiving antenna to the analog-to-digital converter to receive the signal from the wireless communication network and outputs the analog-to-digital converter when determining the specific value is used.

Received signal strength measuring method according to another aspect of the present invention,

Apparatus for measuring received signal strength including an analog-to-digital converter for quantizing any one of the I (In-Phase) channel signal and the Q (Quadrature) channel signal extracted from the signal received in the wireless network to a digital signal A method for measuring received signal strength at

The power generated at the input terminal of the analog-to-digital converter is determined as the received signal strength, and is generated when the probability density function of the input signal and the output signal of the analog-to-digital converter is approximated to a Gaussian having an average of 0. An input stage of the analog / digital converter based on a first relationship between the dispersion of the output signal of the analog / digital converter and the dispersion of the input signal and a second relationship between power and dispersion in the probability density function of the Gaussian random variable The power at is calculated using the signal at the output of the analog-to-digital converter to determine the received signal strength.

DETAILED DESCRIPTION Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art may easily implement the present invention. As those skilled in the art would realize, the described embodiments may be modified in various different ways, all without departing from the spirit or scope of the present invention. In the drawings, parts irrelevant to the description are omitted in order to clearly describe the present invention. Like parts are designated by like reference numerals throughout the specification.

Hereinafter, an RSSI measuring apparatus according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings.

과 Q 채널 ADC(30)의 입력 신호의 분산

이 동일하고, I 채널 ADC(20)의 출력 신호의 분산

과 Q 채널 ADC(30)의 출력 신호의 분산

이 동일해진다. 따라서 I 채널 및 Q 채널 ADC(20, 30)의 입력 신호 및 출력 신호에 대해서는 다음의 [수학식 2]가 성립된다.In general, the probability density functions of the input signals and the output signals of the I and Q channel ADCs 20 and 30 shown in FIG. 1 are approximated to a Gaussian having an average of 0 in a wireless communication system. In this case, the variance of the input signal of the I-channel ADC 20

Of the input signal from the Q-channel ADC 30

Is the same, and the dispersion of the output signal of the I-channel ADC 20

Of the output signal from the Q-channel ADC 30

Is the same. Therefore, Equation 2 below holds for the input signals and the output signals of the I and Q channel ADCs 20 and 30.

)은 다음의 [수학식 3]을 이용하여 구할 수 있다.On the other hand, the power at the input of each ADC (20, 30)

) Can be obtained using Equation 3 below.

Here, R is the inlet resistance of the ADCs 20 and 30.

2 is a diagram illustrating general input / output relations of the I channel and Q channel ADCs 20 and 30 shown in FIG. 1.

과

의 관계는 다음의 [수학식 4]와 같다.Referring to Figure 2, the resolution of the ADC (20, 30), that is, the number of input bits B, the input clip level of the ADC (20, 30) that the output of the ADC (20, 30) is saturated Vc Is assumed to be represented by [Equation 2]

and

Is shown in Equation 4 below.

이다.here,

to be.

On the other hand, the probability density function of the Gaussian random variable Z can be expressed as Equation 5 below.

의 관계가 성립되므로 궁극적으로 다음의 [수학식 6]이 유도된다.In this case, for the Gaussian random variable Z

Since the relationship is established, the following Equation 6 is ultimately derived.

As such, the reason for using Equation 6 for Gaussian random variable Z is to simplify RSSI measurement implementation.

[Equation 3] representing the power at the input terminal of the ADC (20, 30) using the derived equation (6) as the output terminal signal of the ADC (20, 30) as shown in the following [Equation 7] Can be.

라고 하면 수신안테나의 커넥터에서의 RSSI 측정값은 다음의 [수학식 8]과 같이 나타낼 수 있다.On the other hand, it is more precise that RSSI should be defined at the connector of the receiving antenna. This is because if the RSSI is defined at the ADC input terminal instead of the connector of the receiving antenna, the gain from the connector of the receiving antenna to the ADC can be reflected and an accurate RSSI cannot be measured. Therefore, the gain from the connector of the receiving antenna to the ADC

In this case, the RSSI measurement value at the connector of the receiving antenna can be expressed as Equation 8 below.

는 RSSI를 측정하기 위해 사용하는 n번째 신호에서 k번째로 양자화된 I 또는 Q 채널 값, 즉 ADC의 출력 신호이다.here,

Is the kth quantized I or Q channel value from the nth signal used to measure the RSSI, i.e., the output signal of the ADC.

If Equation 8 is more simply expressed, it may be expressed as Equation 9 below.

를 곱하면 수신안테나의 커넥터에서의 실제 RSSI의 정확한 값을 계산할 수 있다.According to Equation 9 above, one of the two ADCs in the I channel or the Q channel is selected, the absolute value is taken in the output signal of the selected ADC, accumulated over a period of time, and corresponds to a known value. doing

Multiply by to calculate the exact value of the actual RSSI at the connector of the receiving antenna.

3 is a block diagram of an apparatus for measuring RSSI according to a first embodiment of the present invention.

As shown in FIG. 3, the RSSI measuring apparatus according to the first embodiment of the present invention includes a receiving antenna 100, an ADC 200, an absolute value calculator (ABS, 300), an accumulator 400, and a squarer ( 500 and multiplier 600.

The reception antenna 100 receives a radio signal transmitted from a base station through a wireless channel, and the ADC 200 selects one of an I channel signal and a Q channel signal received through the reception antenna 100 to respond. The digital signal is converted and output.

The ABS 300 calculates and outputs an absolute value of the signal output from the ADC 200.

The accumulator 400 accumulates and outputs a signal output from the ABS 300 for a predetermined period of time.

The squarer 500 calculates and outputs a squared value of a signal accumulated in the accumulator 400.

를 곱하여 RSSI를 계산한 신호로서 출력한다. 이 때,

값은 ADC(200)의 입구 저항 R, ADC(200)의 입력 비트수 B, ADC(200)의 입력 클립 레벨 Vc, 및 수신안테나(100)의 커넥터에서 ADC(200)에 이르는 회로 및 선로 이득

을 이용하여 미리 계산된다.The multiplier 600 is a value previously calculated and stored in Equation 9 to the value output from the squarer 500.

Multiply by and output the RSSI as a calculated signal. At this time,

The values are the inlet resistance R of the ADC 200, the number of input bits B of the ADC 200, the input clip level Vc of the ADC 200, and the circuit and line gain from the connector of the receiving antenna 100 to the ADC 200.

It is calculated in advance using.

As described above, according to Equation (9), the number of ADCs is reduced in comparison with the conventional method because only one of the I channel or Q channel signal is selected and quantized from the reception antenna 100 by doing so. The hardware complexity is reduced because only one squarer is used for the accumulated value, rather than using a squarer to obtain the power value for each sample. In addition, by measuring the RSSI at the connector of the receiving antenna 100, a more practical RSSI is obtained, and by calculating the RSSI according to [Equation 9], it is possible to accurately know how many Watts or how many mWatts the RSSI is measured. .

On the other hand, in the above description only for measuring the RSSI by hardware only, the calculation according to [Equation 9] can be calculated in software except for the actual measuring part of the ADC, so in the following the RSSI by using a combination of hardware and software A second embodiment of the present invention to be calculated will be described.

4 is a block diagram of an RSSI measurement apparatus according to a second embodiment of the present invention.

In the second embodiment of the present invention, the same components as the components included in the RSSI measurement apparatus according to the first embodiment of the present invention described with reference to FIG. Use the sign.

As shown in FIG. 4, the RSSI measuring apparatus according to the second embodiment of the present invention includes a receiving antenna 100, an ADC 200, an ABS 300, an accumulator 400, and a computer system 700. do.

Since the reception antenna 100, the ADC 200, the ABS 300, and the accumulator 400 are the same as the functions described in the first embodiment of the present invention, they are omitted here for convenience of explanation, and the rest of the configuration Only the elements are described.

The computer system 700 includes an accumulator (I or Q channel signal received and output from the receiving antenna 100 is quantized by the ADC 200 into a digital signal and converted into an absolute value by the ABS 200. 400, the RSSI is calculated and displayed to the user by receiving the accumulated value for a certain period of time.

값을 곱셈 연산하여 RSSI를 계산한다. 이 때,

값은 ADC(200)의 입구 저항 R, ADC(200)의 입력 비트수 B, ADC(200)의 입력 클립 레벨 Vc, 및 수신안테나(100)의 커넥터에서 ADC(200)에 이르는 회로 및 선로 이득

을 이용하여 미리 계산되어 저장되어 있는 것으로 가정한다.That is, the computer system 700 receives the accumulated value from the accumulator 400 and performs a square operation, and then the result value according to [Equation 9]

Calculate the RSSI by multiplying the values. At this time,

The values are the inlet resistance R of the ADC 200, the number of input bits B of the ADC 200, the input clip level Vc of the ADC 200, and the circuit and line gain from the connector of the receiving antenna 100 to the ADC 200.

It is assumed that the data is precomputed and stored using.

As the computer system 700, both a general purpose computer system and a dedicated computer system may be used, and the computer system used includes components as shown in FIG. 5.

Referring to FIG. 5, the computer system 700 may include a system bus 710, a central processing unit (CPU) 720, a random access memory (RAM) 730, a read only memory 740, and an input / output (I / O). / Output) card 750, a hard disk drive (HDD) 760, a video card 770, and a monitor 780.

The system bus 710 serves as a path for connecting data, commands, control signals, and the like in the computer system 700 to each component, and the RAM 720 is connected to the system bus 710 to temporarily store data. The memory is stored therein, and the ROM 730 is connected to the system bus 710, and the memory permanently stores data, and the I / O card 750 is connected to the system bus 710 to connect the computer system 700. And the HDD 760 is connected to the I / O card 750, and is an external storage device for permanently storing data, and the video card 770 is a system bus. A character or graphic is displayed on the monitor 780 which is a screen display device. Meanwhile, the accumulator 400 is connected to the I / O card 750 via an I / O cable or wirelessly.

Hereinafter, a method of measuring RSSI according to a second embodiment of the present invention will be described in detail with reference to FIG. 6.

The CPU 720 of the computer system 700 executes a program command according to the software for RSSI measurement preloaded in the ROM 740 to start an operation for RSSI measurement.

First, the computer system 700 accumulates an I channel or Q channel signal received and output from the reception antenna 100 into a digital signal by the ADC 200, and is converted into an absolute value by the ABS 200, and then accumulated. The value accumulated for a predetermined period by the device 400 is received through the I / O card 750 under the control of the CPU 720 and stored in the RAM 730 through the system bus 710 (S100).

값을 곱셈 연산하여 RSSI를 계산한다(S120). 이 때,

값은 ADC(200)의 입구 저항 R, ADC(200)의 입력 비트수 B, ADC(200)의 입력 클립 레벨 Vc, 및 수신안테나(100)의 커넥터에서 ADC(200)에 이르는 회로 및 선로 이득

을 이용하여 미리 계산되어 RAM(730)이나 HDD(760)을 통해 판독할 수 있는 하드디스크 등에 저장되어 있는 것으로 가정한다. Thereafter, the CPU 720 performs a square operation on the cumulative value stored in the RAM 730 (S110), and as shown in Equation 9 in the result value.

The RSSI is calculated by multiplying the values (S120). At this time,

The values are the inlet resistance R of the ADC 200, the number of input bits B of the ADC 200, the input clip level Vc of the ADC 200, and the circuit and line gain from the connector of the receiving antenna 100 to the ADC 200.

It is assumed that the data is stored in a hard disk or the like that is calculated in advance using the RAM 730 or the HDD 760.

Thereafter, the CPU 720 displays the RSSI calculated in the step S120 to the user through the monitor 780 connected to the video card 770 so as to know how many Watts or mWatts the RSSI actually measured is. (S130).

As described above, according to Equation (9), the number of ADCs is reduced in comparison with the conventional method because only one of the I channel or Q channel signal is selected and quantized from the reception antenna 100 by doing so. As we use only one squarer for the accumulated value, instead of using a squarer to obtain the power value for each sample, the hardware complexity is reduced, and furthermore, the hardware complexity is further reduced by processing the square and multiplication operations through software. Can be. In addition, by measuring the RSSI at the connector of the receiving antenna 100, a more practical RSSI is obtained, and by calculating the RSSI according to [Equation 9], it is possible to accurately know how many Watts or how many mWatts the RSSI is measured. .

Although the preferred embodiment of the present invention has been described in detail above, the present invention is not limited thereto, and various other changes and modifications are possible.

For example, although the structure of the computer system shown in FIG. 5 is used in the above, the technical scope of the present invention is not limited thereto, and the software calculates the RSSI by receiving an accumulated value output from the accumulator 400. Desktop devices, palmtop computers, PDAs (Personal Digital Assistants), small and medium computer systems, and large computer systems can all be used as the devices that can be mounted and run.

According to the present invention, hardware complexity is reduced since the square operation is not performed for every sample of the signal received through the receiving antenna.

In addition, hardware complexity is further reduced by processing the square and multiply operations for RSSI calculation using software.

In addition, by measuring the RSSI at the connector of the receiving antenna, RSSI measurement closer to actual is performed.

In addition, it is possible to know how many Watts or mWatt the exact value of the measured RSSI.

Claims (17)

In the apparatus for measuring the received signal strength (Received Signal Strength Indicator) of the signal transmitted and received in a wireless communication network, An analog / digital converter for quantizing any one of an I (In-Phase) channel signal and a Q (Quadrature) channel signal extracted from a signal received from a wireless communication network into a digital signal; An absolute value calculator for calculating and outputting an absolute value of the digital signal quantized by the analog / digital converter; An accumulator for accumulating and outputting a value output from the absolute value calculator for a predetermined period of time; A squarer which squares a value output from the accumulator and outputs the squared value; And A specific value to a value output from the squarer, where the specific value approximates a probability density function of the input signal and the output signal of the analog / digital converter to a Gaussian having an average of 0; A multiplier outputting the received signal strength of the received signal by multiplying the number of input bits, determined based on the input clip level and the inlet resistance value Received signal strength measuring apparatus comprising a. In the apparatus for measuring the received signal strength (Received Signal Strength Indicator) of the signal transmitted and received in a wireless communication network, An analog / digital converter for quantizing any one of an I (In-Phase) channel signal and a Q (Quadrature) channel signal extracted from a signal received from a wireless communication network into a digital signal; An absolute value calculator for calculating and outputting an absolute value of the digital signal quantized by the analog / digital converter; An accumulator for accumulating and outputting a value output from the absolute value calculator for a predetermined period of time; And A value obtained from the accumulator and a square operation and a specific value, wherein the specific value approximates a probability density function of an input signal and an output signal of the analog / digital converter to a Gaussian having an average of 0, A computer system for performing a multiplication operation, determined based on the number of input bits, input clip level, and inlet resistance of the digital converter, to calculate the received signal strength of the received signal. Received signal strength measuring apparatus comprising a. The method according to claim 1 or 2, Receiving a signal from a wireless communication network further includes a receiving antenna for outputting to the analog-to-digital converter, The gain from the receiving antenna to the analog-to-digital converter is used in determining the particular value. Receiving signal strength measuring apparatus, characterized in that. The method of claim 3, The dispersion of the output signal of the analog-to-digital converter is determined by multiplying the dispersion of the input signal of the analog-to-digital converter by a value determined by the number of input bits and the input clip level of the analog / digital input signal. Intensity measuring device. The method of claim 4, wherein The value k ² is

Here, B is the number of input bits of the analog-to-digital converter,         Vc is the input clip level of the analog / digital converter Received signal strength measuring apparatus, characterized in that determined by. The method of claim 4, wherein Receiving apparatus for measuring the received signal, characterized in that the power of the output signal of the analog-to-digital converter is determined based on the dispersion of the output signal of the analog-to-digital converter. The method of claim 6, The power E ² of the output signal of the analog-to-digital converter is

here

Is the variance of the output signal of the analog-to-digital converter The reception signal strength measuring apparatus, characterized in that determined according to. The method of claim 6, The specific value (

) Is the relation

       Here, B is the number of input bits of the analog-to-digital converter,                R is the inlet resistance of the analog-to-digital converter,                Vc is the input clip level of the analog-to-digital converter,

Is the gain from the receiving antenna to the analog-to-digital converter,               N is the number of samples within a certain period accumulated in the accumulator Received signal strength measuring apparatus, characterized in that determined by. In the method for measuring the received signal strength (Received Signal Strength Indicator) of the signal transmitted and received in a wireless communication network, a) a cumulative value for measuring the strength of a signal received in a wireless communication network, wherein the cumulative value is a period of time for which one of an in-phase channel signal and a quadrature channel signal extracted from the received signal is received; Receiving an absolute value by quantizing the digital signal while the absolute value is accumulated; b) performing a square operation on the input cumulative value; And c) a specific value for the squared value, wherein the specific value approximates a probability density function of an input signal and an output signal of an analog / digital converter that quantizes the received signal into a digital signal to a Gaussian having an average of 0; And calculating a received signal strength of the received signal by performing a multiplication operation based on the input bit number, the input clip level and the inlet resistance of the analog-to-digital converter. Received signal strength measurement method comprising a. The method of claim 9, Before step a), Extracting one of an I (In-Phase) channel signal and a Q (Quadrature) channel signal from the signal received in the wireless communication network and quantizing the signal into a corresponding digital signal; Calculating an absolute value of the quantized signal; And Accumulating the calculated absolute value for the predetermined period and outputting a cumulative value; Received signal strength measurement method further comprising. The method of claim 9 or 10, The gain from the receiving antenna to the analog-to-digital converter, which receives a signal from the wireless communication network and outputs the signal to the analog-to-digital converter, is used when determining the specific value. Receiving signal strength measuring method, characterized in that. Received Signal Strength including an analog-to-digital converter that quantizes one of the in-phase channel signal and the quadrature channel signal extracted from the signal received from the wireless network into a digital signal In the method for measuring the received signal strength in the apparatus for measuring the (Indicator), The power generated at the input terminal of the analog-to-digital converter is determined as the received signal strength, and is generated when the probability density function of the input signal and the output signal of the analog-to-digital converter is approximated to a Gaussian having an average of 0. Based on the first relationship between the variance of the output signal of the analog / digital converter and the variance of the input signal, and the second relationship between power and variance in the probability density function of the Gaussian random variable, The power at the input is calculated using the signal at the output of the analog-to-digital converter to determine the received signal strength. Receiving signal strength measuring method, characterized in that. The method of claim 12, The first relationship is the following relationship

here,

Is the variance of the input signal of the analog-to-digital converter,

Is the variance of the output signal of the analog-to-digital converter,               k is the relation

to be.               Here, B is the number of input bits of the analog-to-digital converter,                        Vc is the input clip level at which the output of the analog-to-digital converter is saturated Receiving signal strength measuring method according to claim. The method of claim 12, The second relationship is Power and variance in the probability density function of the Gaussian random variable

    E is the power in the probability density function of the Gaussian random variable,

Is the variance in the probability density function of the Gaussian random variable Receiving signal strength measuring method according to claim. The method according to any one of claims 12 to 14, The receiving strength measuring apparatus further includes a receiving antenna for receiving a signal from a wireless communication network and outputs to the analog-to-digital converter, The gain from the receiving antenna to the analog-to-digital converter is used to determine the received signal strength. Receiving signal strength measuring method, characterized in that. In a recording medium storing a program for implementing a method for measuring the received signal strength (Received Signal Strength Indicator) of the signal transmitted and received in a wireless communication network, a) a cumulative value for measuring the strength of a signal received in a wireless communication network, wherein the cumulative value is a period of time for which one of an in-phase channel signal and a quadrature channel signal extracted from the received signal is received; A function of receiving an absolute value by quantizing with a digital signal and accumulating the absolute value; b) performing a square operation on the input cumulative value; And c) a specific value for the squared value, wherein the specific value approximates a probability density function of an input signal and an output signal of an analog / digital converter that quantizes the received signal into a digital signal to a Gaussian having an average of 0; And calculating a received signal strength of the received signal by performing a multiplication operation based on the input bit number, the input clip level, and the inlet resistance of the analog-to-digital converter. Record medium that stores the program to implement. Received Signal Strength including an analog-to-digital converter that quantizes one of the in-phase channel signal and the quadrature channel signal extracted from the signal received from the wireless network into a digital signal In a recording medium storing a program for implementing a method for measuring received signal strength in an apparatus for measuring an indicator, The power generated at the input terminal of the analog / digital converter is determined as the received signal strength, and is generated when the probability density function of the input signal and the output signal of the analog / digital converter is approximated to a Gaussian having an average of 0. An input stage of the analog / digital converter based on a first relationship between the dispersion of the output signal of the analog / digital converter and the dispersion of the input signal and a second relationship between power and dispersion in the probability density function of the Gaussian random variable And a program for implementing a method of measuring a received signal strength to calculate the power of the signal using the signal at the output of the analog-to-digital converter to determine the received signal strength.

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