KR102423480B1 - Surface acoustic wave temperature sensor with high accuracy using pseudorandom binary sequence - Google Patents

Abstract

The present invention relates to a SAW temperature sensor system, which transmits an operation signal generated by modulating pseudorandom data representing a pseudorandom binary sequence having high autocorrelation and low cross-correlation to a SAW temperature sensor and receives a reflection signal from the SAW temperature sensor to read a temperature from the reflection signal. Therefore, even if the reflection signal from the SAW temperature sensor is damaged, the SAW temperature sensor system can verify whether the received reflection signal is a signal reflected in response to the operation signal, and thus can measure the temperature with high accuracy in a noisy environment.

Description

High-accuracy SAW temperature sensor system using pseudo-random data {SURFACE ACOUSTIC WAVE TEMPERATURE SENSOR WITH HIGH ACCURACY USING PSEUDORANDOM BINARY SEQUENCE}

The present invention relates to a SAW temperature sensor system, and more particularly, to a SAW temperature sensor system capable of measuring temperature with high accuracy using pseudo-random data.

Temperature environment is very important for power facilities and industrial facilities such as switchboards (or water substation boards), transformers, power transmission facilities, motor control panels, and distribution boards. Such power facilities or industrial facilities are liable to be overheated excessively due to deterioration, corrosion, etc. of connection points in the live part of the line to which power is supplied, which leads to damage to power facilities or to power outages, fires, and power loss. Accordingly, various temperature sensing devices for detecting damage or signs of power facilities by continuously monitoring the temperature of the power facilities are being used.

Conventionally, the temperature of various facilities was measured mainly using arc detection, thermal imaging camera, infrared sensor, optical cable wireless temperature sensor, and the like. However, arc detection or deterioration detection method can only detect indirect temperature despite the use of expensive equipment. It has many problems in that respect.

To solve this problem, a SAW temperature sensor system that measures temperature using a surface acoustic wave (SAW) sensor capable of measuring temperature in a non-contact manner has been developed. SAW sensor is a sensor using waves, has a simple structure and has no moving parts, so it can withstand external vibrations or shocks well. It has the advantage of being easy to mass-produce and inexpensive.

As an example of a conventional SAW temperature sensor system, there is Republic of Korea Patent Registration No. 10-1202878 "Wireless measuring device and method using a surface acoustic wave-based micro sensor". In No. 10-1202878, a pulse signal for measuring changes in environmental factors is generated and transmitted wirelessly to the SAW temperature sensor, the transmitted pulse signal is reflected from the SAW temperature sensor, and the interval between the received pulse signals is, A SAW temperature sensor system that generates a pulse signal every time it corresponds to the interval between pulse signals of a set environmental element, wirelessly transmits it to the SAW temperature sensor, and counts the number of occurrences of the pulse signal for a certain period of time to measure the change in the environmental element. is starting.

However, according to this prior art, the intensity of the reflected signal from the SAW temperature sensor is weak compared to the signal of the transceiver that transmits a signal to the SAW temperature sensor and receives the signal from the SAW temperature sensor. A problem such as generation or partial omission of a signal easily occurs, which makes it difficult for a transceiver to measure a reflected signal, and as a result, these problems lower the reliability of the temperature measurement result.

By driving the SAW temperature sensor using the signal generated by modulating the data of the pseudo-random sequence with high auto-correlation characteristics and low cross-correlation characteristics, it is not affected by the surrounding environment such as the distance between the SAW temperature sensor and the reader and surrounding noise. An object of the present invention is to provide a SAW temperature sensor system that can measure the temperature by accurately measuring the reflected signal from the SAW temperature sensor. It is not limited to the technical problems as described above, and another technical problem may be derived from the following description.

A SAW temperature sensor system according to an aspect of the present invention includes: a SAW temperature sensor for transmitting a reflected signal for the received driving signal when receiving a driving signal through an antenna; and a reader that generates and transmits the driving signal to the SAW temperature sensor, receives a reflected signal transmitted from the SAW temperature sensor, and reads the temperature sensed by the SAW temperature sensor from the received reflected signal, The reader generates the driving signal by modulating data representing a pseudo random binary sequence (PRBS) using a carrier wave.

The reader verifies whether the reflected signal received from the SAW temperature sensor is a signal reflected in response to the driving signal transmitted by the reader, and as a result of the verification, if the reflected signal is a reflected signal in response to the driving signal can read the temperature sensed by the SAW temperature sensor from the reflected signal.

The reader may include: a pseudo-random data generator for generating pseudo-random data representing the pseudo-random binary sequence; a driving signal transmitter for generating the driving signal by modulating the pseudo-random data generated by the pseudo-random data generator with a carrier wave, and transmitting the generated driving signal to the SAW temperature sensor; a reflected signal receiver which receives and demodulates a reflected signal from the SAW temperature sensor after transmitting the driving signal to generate reflected data representing a binary sequence; The correlation between the pseudo-random data generated by the pseudo-random data generator and the reflected data demodulated by the reflected signal receiver is analyzed, and the reflected signal received from the SAW temperature sensor is driven according to the correlation analysis result. a correlation analysis unit verifying whether the signal is a reflected signal in response to the driving signal transmitted by the signal transmitting unit; and a temperature reading unit that reads the temperature sensed by the SAW temperature sensor from the reflected signal when it is verified that the reflected signal received from the SAW temperature sensor is a signal reflected in response to the driving signal transmitted by the driving signal transmitter. may include

The SAW temperature sensor includes an antenna for transmitting and receiving signals; an inter-digital transducer (IDT) for generating a surface acoustic wave by a driving signal received through the antenna; and a reflector that reflects the surface acoustic wave generated by the IDT to generate a reflected wave and emit it to the antenna, wherein the resonant frequency of the SAW temperature sensor is changed according to the temperature of the SAW temperature sensor, and the reflected wave is the driving signal It is generated when the frequency of the driving signal transmitted by the transmitter is the same as the resonance frequency of the SAW temperature sensor, and the reflected wave generated by the reflector may be transmitted as a reflected signal through the antenna.

Further comprising a data processing unit for determining whether the reflection signal from the SAW temperature sensor is received by the reflection signal receiving unit, wherein the data processing unit is the reflection for a preset time period after the transmission of the driving signal by the driving signal transmitter When the reflected signal from the SAW temperature sensor is not received by the signal receiving unit, the driving signal transmitting unit may be controlled to modulate the pseudo-random data by changing the frequency of the carrier wave and then retransmit it to the SAW temperature sensor.

The correlation analysis unit determines the correlation between the pseudo-random data and the reflection data based on a plurality of result data sets generated by bitwise XNOR operation of the binary sequence of the pseudo-random data and the binary sequence of the reflection data. A correlation between random data and the reflected data can be analyzed.

The correlation analysis unit rotates the binary sequence of the pseudo-random data or the binary sequence of the reflection data, and generates the plurality of result data sets by performing bitwise XNOR operation of the binary sequence of the pseudo-random data and the binary sequence of the reflection data. and each result data set may represent a binary sequence representing a result value of a bitwise XNOR operation of the binary sequence of the pseudo-random data and the binary sequence of the reflection data performed in response to each rotation.

The correlation analyzer may determine a correlation between the pseudo-random data and the reflection data based on a sum of values constituting the binary sequence of each result data set.

The correlation analysis unit replaces '0' constituting the binary sequence of each result data set with '-1', and sums all values of -1 and 1 constituting the respective result data sets to obtain a plurality of correlations By calculating the value, it is possible to determine the correlation between the pseudo-random data and the reflection data.

The correlation analyzer may determine a correlation between the pseudo-random data and the reflection data based on magnitudes of the plurality of correlation values.

The correlation analysis unit responds to the reflected signal received from the SAW temperature sensor in response to the driving signal transmitted by the driving signal transmitter when at least one correlation value exceeding a preset threshold value among the plurality of correlation values exists. It can be determined by the reflected signal.

Modulation of the pseudo-random data and demodulation of the reflected signal may be performed by a phase shift keying (PSK) method.

The reader further includes a data storage unit for storing a mapping table in which a resonant frequency value of the SAW temperature sensor that varies depending on the temperature of the SAW temperature sensor and a temperature value corresponding to each resonant frequency are mapped, the temperature reading unit is the data Just before it is determined by the processing unit that the reflected signal has been received from the SAW temperature sensor, the frequency of the carrier wave used for modulation of the driving signal transmitted by the driving signal transmitter is determined as the resonance frequency of the SAW temperature sensor, and the determined SAW The temperature sensed by the SAW temperature sensor may be determined by reading a temperature value corresponding to the resonant frequency of the temperature sensor from a mapping table stored in the data storage unit.

A driving signal generated by modulating pseudo-random data representing a pseudo-random binary sequence with high autocorrelation and low cross-correlation characteristics is transmitted to the SAW temperature sensor, and the reflected signal is received from the SAW temperature sensor and the temperature is read from the reflected signal. By doing so, even if the reflected signal from the SAW temperature sensor is damaged in the transmission/reception process, it is possible to verify whether the received reflected signal is a reflected signal in response to the driving signal, and accordingly, the temperature can be measured with high accuracy even in a noisy environment.

In addition, it is verified whether the reflected signal received from the SAW temperature sensor is a reflected signal in response to the driving signal transmitted by the reader, and the reflected signal received from the SAW temperature sensor is reflected in response to the driving signal transmitted by the reader After it is verified that the signal is a validated signal, the temperature can be measured more accurately by reading the temperature from the reflected signal.

1 is a block diagram of a SAW temperature sensor system according to an embodiment of the present invention.
FIG. 2 is a block diagram of a SAW temperature sensor of the SAW temperature sensor system shown in FIG. 1 .
FIG. 3 is a block diagram of the reader shown in FIG. 1 .
FIG. 4 is a diagram illustrating a circuit of a pseudo-random data generating unit of the reader shown in FIG. 3 .
5 is a diagram conceptually illustrating an operation of a pseudo-random data generator.
6 is a diagram illustrating pseudo-random data generated by a pseudo-random data generator and a driving signal generated by a driving signal transmitter.
FIG. 7 is a diagram conceptually illustrating an operation of a correlation analysis unit of the reader shown in FIG. 3 .
8 is a view showing a result of verifying a reflected signal by a correlation analyzer according to an embodiment of the present invention.
9 is a view showing a change in the resonance frequency of the SAW temperature sensor according to the temperature.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. An embodiment of the present invention described below relates to a high-accuracy SAW temperature sensor system using pseudo-random data, and may be simply referred to as a 'SAW temperature sensor system'.

1 is a block diagram of a SAW temperature sensor system 100 according to an embodiment of the present invention. Referring to FIG. 1 , the SAW temperature sensor system 100 according to an embodiment of the present invention includes a SAW temperature sensor 110 and a reader 120 .

The SAW temperature sensor system 100 according to an embodiment of the present invention transmits a driving signal to the SAW temperature sensor 110 installed so that the reader 120 is adjacent to the temperature measurement target, and the SAW temperature sensor 110 receives the driving signal. When the reflected signal for the signal is transmitted to the reader 120, the reader 120 verifies whether the reflected signal received from the SAW temperature sensor 110 is the reflected signal corresponding to the driving signal transmitted from the reader 120. Then, the temperature of the temperature measurement target is more accurately measured by reading the temperature from the reflected signal received from the SAW temperature sensor 110 .

Hereinafter, the SAW temperature sensor 110 and the reader 120 according to an embodiment of the present invention will be described in more detail with reference to the drawings.

2 is a block diagram of the SAW temperature sensor 110 according to an embodiment of the present invention. Referring to FIG. 2 , the SAW temperature sensor 110 includes an antenna 210 , an inter digital transducer (IDT) 220 , a piezoelectric substrate 230 and a reflector 240 .

The antenna 210 wirelessly receives a driving signal from the reader 120 and wirelessly transmits a reflected signal generated in response to the driving signal. The IDT 220 generates a surface acoustic wave by a driving signal received through the antenna 210 . The surface acoustic wave generated by the IDT 220 is propagated while vibrating the piezoelectric substrate 230 , and the reflector 240 reflects the propagated surface acoustic wave to generate a reflected wave. The generated reflected wave is transmitted through the antenna 210 via the IDT 220 , and the reader 120 receives the reflected wave signal as a reflected signal. Since each component of the SAW temperature sensor 110 and the operation of each component are techniques known to those skilled in the art to which this embodiment belongs, in order to prevent the description of the embodiment according to the present invention from being verbose, a more detailed description is omit

On the other hand, in relation to the reflected signal transmitted by the SAW temperature sensor 110 , the SAW temperature sensor 110 changes the resonant frequency by changing the physical properties of the sensor according to the ambient temperature. When the frequency is the same as the resonant frequency of the SAW temperature sensor 110, the signal is amplified to generate a reflected wave. In other words, the reader 120 does not receive the reflected signal from the SAW temperature sensor 110 in response to all the transmitted driving signals, but the frequency of the driving signal transmitted by the reader 120 is the frequency of the SAW temperature sensor 110 . The reflected signal is received from the SAW temperature sensor 110 only when it is equal to the resonant frequency according to the ambient temperature. Using this point, the reader 120 sweeps the frequency, transmits the driving signal to the SAW temperature sensor 110, and determines whether the reflected signal is received from the SAW temperature sensor 110 in response to the transmission of the driving signal of which frequency. By detecting , the resonance frequency of the SAW temperature sensor 110 may be determined, and the temperature of the temperature measurement target may be measured based on the determined resonance frequency of the SAW temperature sensor 110 . Hereinafter, with reference to FIGS. 3 to 9, by transmitting a driving signal to the SAW temperature sensor 110, receiving a reflected signal from the SAW temperature sensor 110, and reading the temperature of the temperature measurement target from the received reflected signal. The reader 120 for reading the temperature of the temperature measurement target will be described in detail.

3 is a block diagram of a reader 120 according to an embodiment of the present invention. Referring to FIG. 3 , the reader 120 according to the embodiment of the present invention includes a pseudo-random data generator 310 , a driving signal transmitter 320 , a reflected signal receiver 330 , a data processor 340 , and a correlation. It consists of an analysis unit 350 , a temperature reading unit 360 , and a data storage unit 370 .

Those of ordinary skill in the art to which this embodiment pertains may realize that these components may be implemented as hardware providing a specific function, or may be implemented as a combination of a memory, a processor, a bus, etc. in which software providing a specific function is recorded. It can be understood that Each of the above-described components is not necessarily implemented as separate hardware, and several components may be implemented by a combination of common hardware, for example, a processor, a memory, a bus, and the like.

The pseudo-random data generator 310 generates pseudo-random data representing a pseudo random binary sequence (PRBS) to be transmitted to the SAW temperature sensor 110 . In an embodiment of the present invention, the pseudo-random data generation by the pseudo-random data generation unit 310 may include generating pseudo-random data by calling the pseudo-random data previously generated and stored in the data storage unit 370 . have.

In an embodiment of the present invention, the pseudo-random data generator 310 may be implemented as a pseudo random number generator to which a shift register is applied.

4 is a diagram illustrating a circuit of the pseudo-random data generator 310 according to an embodiment of the present invention. Referring to FIG. 4 , the pseudo-random data generator 310 according to an embodiment of the present invention includes n flip-flops 410 , an XOR gate 420 , and a clock (not shown). do. By connecting the XOR gate 420 to a shift register composed of n flip-flops 410, pseudo-random data can be generated. In this case, the number of flip-flops 410 constituting the shift register may be set as needed. The pseudo-random data generating unit 310 composed of n flip-flops 410 has a maximum of 2 ⁿ -1 Bit pseudo-random data can be generated.

In an embodiment of the present invention, the pseudo-random data generating unit 310 is composed of 13 flip-flops 410 to generate 2047 bits of pseudo-random data. However, this is merely an example for helping the understanding of the present invention, and is not limited thereto. For those skilled in the art, the number of flip-flops 410 constituting the pseudo-random data generation unit 310 and the pseudo-random data generation unit ( 310), it is obvious that the number of bits of the pseudo-random data generated by the method can be appropriately set to suit the usage environment and conditions.

On the other hand, as the bits of the pseudo-random data are longer, the signal generated by modulating the pseudo-random data is strong against noise, which makes it advantageous to verify the reflected signal. The shorter the bit, the faster temperature measurement is possible, but verification of the reflected signal may be difficult even with low noise. It is also possible to adjust the number of bits of generated pseudo-random data by adjusting the number.

5 is a diagram conceptually illustrating the operation of the pseudo-random data generator 310 according to an embodiment of the present invention. FIG. 5 shows an operation of the pseudo-random data generator 310 implemented to generate 2047-bit pseudo-random data using 13 flip-flops 410 as an example. In FIG. 5 , each square represents each flip-flop 410 constituting the pseudo-random data generator 310 , and a number (0 or 1) written in each square represents data stored in each flip-flop 410 . . When a clock pulse for generating pseudo-random data is applied to each flip-flop 410 , the data stored in each flip-flop 410 is shifted to the next flip-flop 410 in the left direction. At this time, the data stored in the 12th flip-flop 410a and the 13th flip-flop 410b is input to the XOR gate, the XOR operation is performed, and the XOR operation result value is newly stored in the 1st flip-flop 410c, Data stored in the third flip-flop 410d is stored as bit values of pseudo-random data.

5A is a diagram illustrating a data storage state of the pseudo-random data generating unit 310 at one point in time. 1 is stored as data in the rightmost flip-flop 410c, and 0 is stored as data in flip-flops 2 to 13 thereafter. Also, data 0 stored in the third flip-flop 410d is stored as a bit value of the pseudo-random data. Referring to FIG. 5B, which shows a state after one clock pulse is applied at the time point of FIG. 5A, data stored in the flip-flops 1 410c to twelfth flip-flops 410a just before the clock pulse application is shifted to the left. and it can be confirmed that the data is stored in the second flip-flops to the 13th flip-flops 410b. At this time, the data value '0' stored in the 13th flip-flop 410b in FIG. 5A is removed, and the data value stored in the 12th flip-flop 410a and the 13th flip-flop 410b in FIG. '0', the result of XOR operation, is stored in flip-flop 1. In addition, data 0 stored in the third flip-flop 410d is stored in the next bit of the pseudo-random data bit in which the bit value is stored immediately before the clock pulse is applied. In this way, the data is shifted and the length of the pseudo-random data increases while performing the XOR operation.

If the process of performing the XOR operation while repeating the data shift in this way and storing the value stored in the third flip-flop 410d as a bit value of the pseudo-random data is repeated, the generated pseudo-random data has periodicity. The period of the random data is 2047 bits, so the pseudo-random data generating unit 310 generates pseudo-random data having a period of 2047 bits.

In this example, the data stored in the 12th flip-flop 410a and the 13th flip-flop 410b is XORed, and the data stored in the 3rd flip-flop 410d is stored as a bit value of pseudo-random data. However, it will be apparent to a person skilled in the art that a flip-flop storing data on which XOR operation is performed and a flip-flop storing data stored as bit values of pseudo-random data may be arbitrarily selected.

In the above manner, the pseudo-random data generation unit 310 may generate pseudo-random data representing an m-bit pseudo-random binary number sequence. The pseudo-random data generated in this way has high auto-correlation characteristics and low cross-correlation characteristics, so that the pseudo-random data generated by the pseudo-random data generating unit 310 and the reflected signal are demodulated by the reflected signal receiving unit 330 to generate the generated pseudo-random data. It is very advantageous to analyze the correlation of reflection data.

Meanwhile, in another embodiment of the present invention, the pseudo-random data generation unit 310 may generate pseudo-random data by calling the pseudo-random data previously generated and stored in the data storage unit 370 . The data storage unit 370 may store pseudo-random data representing one or more pseudo-random binary numbers, and the number of bits of each pseudo-random data may be different. When a temperature reading is requested, the pseudo-random data generating unit 310 generates pseudo-random data by calling pseudo-random data having an appropriate number of bits according to a signal transmission/reception environment among one or more pseudo-random data stored in the data storage unit 370 . can do.

In another embodiment of the present invention, the pseudo-random data generation unit 310 generates pseudo-random data using a random number generator using a shift register in general, and there is a change in the signal transmission/reception environment or a high temperature reading accuracy. In exceptional circumstances, such as required, it is also possible to generate pseudo-random data by calling pseudo-random data previously generated and stored in the data storage unit 370 .

The driving signal transmitting unit 320 modulates the pseudo-random data generated by the pseudo-random data generating unit 310 into a carrier wave to generate an analog driving signal, and transmits the generated driving signal to the SAW temperature sensor 110 . .

In an embodiment of the present invention, the driving signal transmitter 320 may modulate the pseudo-random data using a phase shift keying (PSK) method. Referring to FIG. 6A showing the pseudo-random data generated by the pseudo-random data generating unit 310 and FIG. 6B showing the driving signal generated by modulating the pseudo-random data by the driving signal transmitting unit 320, It can be confirmed that the random data is digital data having a value of 0 or 1, and the driving signal generated by modulating the pseudo-random data by the driving signal transmitter 320 is an analog waveform signal.

On the other hand, the driving signal transmitter 320 of the present invention sweeps the frequency of the carrier wave, modulates the pseudo-random data, generates a driving signal, and transmits it to the SAW temperature sensor 110 . In this case, the frequency range of the carrier wave swept by the driving signal transmitter 320 may be set to be the same as the frequency range corresponding to the temperature range that the SAW temperature sensor 110 receiving the driving signal can measure. In one embodiment of the present invention, the driving signal transmitter 320 sweeps the frequency of the carrier within the range of 420 MHz to 450 MHz, modulates the pseudo-random data, and then sends the SAW temperature sensor 110 through an antenna (not shown). can be sent to

On the other hand, the interval of the frequency of the carrier wave swept by the driving signal transmitter 320 may be set according to the temperature measurement precision required for the reader 120 according to the embodiment of the present invention. If the interval of the frequency of the carrier wave swept by the driving signal transmitter 320 is small, it takes a lot of time for signal transmission and reception and signal processing, but it is possible to measure the temperature more accurately. On the other hand, if the interval of the frequency of the carrier wave swept by the driving signal transmitter 320 is large, the number of signal transmission/reception and signal processing is reduced, so that the temperature can be quickly measured, but the reliability of the temperature measurement result is lowered. Therefore, it is necessary to set the frequency sweep interval in consideration of the purpose of temperature measurement or the measurement environment.

In one embodiment of the present invention, the driving signal transmitter 320 sweeps the frequency of the carrier wave at intervals of 1 kHz to generate a driving signal by modulating pseudo-random data, and transmits the generated driving signal to the SAW temperature through an antenna (not shown). It can be transmitted to the sensor 110 . For example, when the frequency sweep interval of the carrier wave is 1 kHz, the driving signal transmitting unit 320 modulates the m-bit pseudo-random data generated by the pseudo-random data generating unit 310 into a 430 MHz carrier wave to the SAW temperature sensor 110 . After transmitting to , the m-bit pseudo-random data may be modulated with a carrier wave of 430.001 MHz and transmitted to the SAW temperature sensor 110 .

The reflected signal receiver 330 receives the analog reflected signal from the SAW temperature sensor 110 after the drive signal transmitter 320 transmits the drive signal and demodulates it into digital data to generate reflected data representing a binary sequence.

In an embodiment of the present invention, the reflected signal receiver 330 may receive a reflected signal from the SAW temperature sensor 110 through an antenna (not shown), and demodulate the received reflected signal using the PSK method.

The data processing unit 340 determines whether a reflection signal is received from the SAW temperature sensor 110 by the reflection signal receiving unit 330 . The data processing unit 340 checks whether the reflected signal is received by the reflected signal receiving unit 330 for a preset time period after the driving signal is transmitted by the driving signal transmitting unit 320 .

On the other hand, the data processing unit 340 changes the frequency of the carrier wave when the reflected signal is not received by the reflected signal receiving unit 330 for a preset time period after the driving signal is transmitted by the driving signal transmitting unit 320 (sweep) After modulating the pseudo-random data, the drive signal transmitter 320 is controlled to retransmit it to the SAW temperature sensor 180 . In the process of sweeping the frequency of the carrier wave to modulate the pseudo-random data and then retransmitting the data to the SAW temperature sensor 110 , the data processing unit 340 receives the reflected signal from the SAW temperature sensor 110 by the reflected signal receiving unit 330 . This is repeated until it is determined that

When the data processing unit 340 determines that the reflected signal is received by the reflected signal receiving unit 330 for a preset time period after the driving signal is transmitted by the driving signal transmitting unit 320 , the correlation analyzing unit 350 is reflected It is verified whether the reflected signal received from the SAW temperature sensor 110 by the signal receiving unit 330 is a reflected signal corresponding to the driving signal transmitted by the driving signal transmitting unit 320 .

More specifically, the correlation analyzer 350 analyzes the correlation between the pseudo-random data generated by the pseudo-random data generator 310 and the reflected data demodulated by the reflected signal receiver 330 , and analyzes the correlation. According to the result, it is verified whether the reflected signal received from the SAW temperature sensor 110 is a reflected signal corresponding to the driving signal transmitted by the driving signal transmitter 320 .

The correlation analyzer 350 performs an XNOR operation on the binary sequence of the pseudo-random data generated by the pseudo-random data generator 310 and the binary sequence of the reflected data demodulated by the reflected signal receiver 330 bit by bit, and a plurality of results are obtained. The correlation between the pseudorandom data and the reflected data is analyzed by generating a data set and determining the correlation between the pseudorandom data and the reflected data based on the plurality of generated result data sets.

In this case, the correlation analysis unit 350 rotates one of the binary sequence of the reflection data or the binary sequence of the pseudo-random data and performs an XNOR operation to form a plurality of result data sets. Each result data set represents a binary sequence representing a result value of a bitwise XNOR operation of a binary sequence of pseudo-random data and a binary sequence of reflected data performed corresponding to each rotation.

7 is a diagram conceptually illustrating the generation of a result data set by the correlation analyzer 350 according to an embodiment of the present invention. 7 illustrates a state in which m-bit reflection data is rotated and XNOR operation is performed with m-bit pseudorandom data. Referring to FIG. 7 , the data of each bit of the pseudorandom data is XNORed with the data of each corresponding bit of the reflection data ( FIG. 7A ). One result data set consisting of m bits of 0 or 1 is generated by this single XNOR operation.

Thereafter, when a clock pulse is applied to the correlation analyzer 350, the bit value of the reflected data is rotated by 1 bit, so that 1, the first bit value before the clock pulse is applied, becomes the second bit value, and the mth bit value, 0, becomes the first th bit value (FIG. 7B). In this way, when the bit value of the reflected data is rotated by 1 bit, XNOR operation is performed again on each bit of the m-bit pseudo-random data and the corresponding bit of the reflected data.

The XNOR operation of these reflection data and pseudo-random data continues until the reflection data returns to the original data by rotation. Therefore, after the initial XNOR operation, the result data set consisting of m-bit binary numbers by rotation m-1 times. m are generated.

Thereafter, the correlation analysis unit 350 determines the correlation between the pseudo-random data and the reflected data based on the sum of values constituting the binary sequence of each result dataset.

More specifically, the correlation analysis unit 350 determines the correlation between the pseudo-random data and the reflected data by calculating a correlation value of each of the generated m result data sets. Correlation analysis unit 350 according to the embodiment of the present invention replaces the value of 0 constituting the m-bit binary sequence constituting each result data set with -1, and -1 constituting each result data set By summing all the values of 1, we can calculate the correlation value for each result data set.

For example, in a result data set consisting of m bits of 0 and 1, if k bits have a value of 0 and m-k bits have a value of 1, the correlation value of this result data set is -k+(m-k) becomes When correlation values are calculated for each of the m result data sets in this way, a total of m correlation values are calculated.

7-bit pseudo-random data of 1011100 is generated by the pseudo-random data generator 310 to help the understanding of the correlation value calculation process by the correlation analyzer 350 , and demodulated by the reflected signal receiver 330 . It is assumed that the reflected reflected data is 7-bit data of 1011100.

A result data set of 1111111 is generated by the first XNOR operation (1011100 XNOR 1011100), and the correlation value of the generated result data set becomes 7 (1+1+1+1+1+1+1). When a clock pulse is applied to the correlation analyzer 350, the reflected data is rotated and becomes 0111001, a result data set of 0011010 is generated by the second XNOR operation (1011100 XNOR 0111001), and the correlation value is -1 (- 1-1+1+1-1+1-1). When the operation is performed in this way, the correlation value of the third XNOR operation (1011100 XNOR 1110010) is -1, the correlation value of the fourth XNOR operation (1011100 XNOR 1100101) is -1, and the fifth XNOR operation (1011100 XNOR) The correlation value of 1001011) is -1, the correlation value of the sixth XNOR operation (1011100 XNOR 0010111) is -1, and the correlation value of the last seventh XNOR operation (1011100 XNOR 0101110) becomes -1.

From this, when the transmitted driving signal and the reflected signal reflected and received are the same (that is, when the pseudo-random data and the reflected data are the same), a value equal to the number of bits of the pseudo-random data and the reflected data is the largest of the correlation values. It can be confirmed that it is calculated as the maximum value, and the remainder except for the maximum value has a value of -1 or 1. As such, the correlation analyzer 350 reflects the reflected signal received by the reflected signal receiver 330 in response to the driving signal transmitted by the driving signal transmitter 320 based on the magnitudes of the plurality of correlation values. signal can be determined.

On the other hand, when the reflected signal from the SAW temperature sensor 110 is not properly acquired due to noise in the process of being received by the reflected signal receiver 330, the SAW temperature in response to the driving signal from the driving signal transmitter 320 Even when the reflected signal is generated from the sensor 110 , the reflected data demodulated by the reflected signal receiver 330 may have data composed of a binary sequence different from the pseudo-random data.

For example, the 7-bit pseudo-random data of 1011100 generated by the pseudo-random data generation unit 310 is modulated and transmitted to the SAW temperature sensor 110, and the reflected signal from the SAW temperature sensor 110 generated in response thereto is 7-bit data of 1111101 in which second and seventh bit values are changed due to noise in the process of being received and demodulated by the reflected signal receiver 330 may be acquired. However, even in this case, when the correlation value of the pseudo-random data and the reflection data is calculated by the correlation analysis unit 350, the correlation values of 3, -1, -1, -1, -1, -1, 3 This is calculated

As such, the pseudo-random data generated by the pseudo-random data generating unit 310 is XNORed with reflected data having the same data value corresponding to the pseudo-random data due to the high auto-correlation and low cross-correlation characteristics of the PRBS data. In addition, it can be seen that one or more correlation values, which are generated corresponding to pseudo-random data, but whose bit values are partially changed, can be obtained in XNOR operation with reflection data, which are also large compared with other values.

In an embodiment of the present invention, the correlation analyzer 350 demodulates the pseudo-random data generated by the pseudo-random data generator 310 and the reflected signal received from the SAW temperature sensor 110 to generate reflected data. If there is one or more correlation values exceeding a preset threshold among the correlation values of , it is determined that the reflected signal is reflected in response to the transmitted driving signal, and among the correlation values of the pseudo-random data and the reflected data, When there is no correlation value exceeding the set threshold, it may be determined that the reflected signal is not a reflected signal corresponding to the transmitted driving signal.

8 is a diagram illustrating correlation values determined by the correlation analyzer 350 in various embodiments. FIG. 8 calculates and shows correlation values between the 2047-bit pseudorandom data transmitted by the driving signal transmitter 320 and the 2047-bit reflected data received by the reflected signal receiver 330 . 8A shows that 2047 bits of pseudo-random data and received 2047 bits of reflected data have the same bit values, that is, when a reflected signal is received without any data loss, FIG. 8B shows 1362 bits of data among 2047 bits In the same case, FIG. 8C shows a plurality of correlation values when 336 pieces of data out of 2047 bits are identical, and FIG. 8D shows a plurality of correlation values when 0 data out of 2047 bits are the same.

Referring to FIG. 8A , when the bit values of the 2047-bit pseudo-random data and the received 2047-bit reflected data are the same, the maximum value of the correlation values is 2047 equal to the number of bits of the pseudo-random data and the reflected data. can be seen to indicate In this case, the correlation analyzer 350 may determine that the received reflected signal is a reflected signal corresponding to the transmitted driving signal.

Referring to FIG. 8B , even when the bit values of 1362 bits among 2047 bits are the same, it can be seen that the maximum value exceeding 500 is detected four times among the plurality of correlation values. In this case, when the preset threshold value is 500, the correlation analyzer 350 may determine that the received reflected signal is a reflected signal corresponding to the transmitted driving signal. However, when the threshold value preset for more precise temperature measurement is 1000, the correlation analyzer 350 may determine that the received reflected signal is not a reflected signal corresponding to the transmitted driving signal.

8C and 8D do not have a positive maximum in the correlation value set, the correlation analyzer 350 may determine that the received reflected signal is not a reflected signal corresponding to the transmitted driving signal.

In this way, the correlation analysis unit 350 calculates a correlation value between the pseudo-random data generated by the pseudo-random data generation unit 310 and the reflection data demodulated by the reflection signal receiving unit 330 through XNOR operation, and , by verifying that the received reflected signal is a reflected signal corresponding to the transmitted driving signal by checking whether it has one or more correlation values exceeding a preset threshold among the plurality of calculated correlation values. Even in a situation where signal reception is not good due to an environmental disturbance, it can be more accurately determined that the received reflected signal is reflected in response to the transmitted driving signal, which increases the reliability of the temperature measurement result.

When the temperature reading unit 360 determines that the reflected signal received from the SAW temperature sensor 110 is reflected in response to the driving signal transmitted by the driving signal transmitter 320 by the correlation analysis unit 350, The temperature sensed by the SAW temperature sensor 110 is read from the reflected signal.

The data storage unit 370 stores a mapping table in which a resonant frequency value that varies according to a change in a physical characteristic that varies depending on the temperature of the SAW temperature sensor 110 and a temperature value corresponding to each resonant frequency are mapped. 9 is a graph showing the resonance frequency value of the SAW temperature sensor 110 according to the temperature of the SAW temperature sensor 110 . As the temperature of the measurement target measured by the SAW temperature sensor 110 increases, the resonance frequency of the SAW temperature sensor 110 decreases.

When the temperature reading unit 360 is verified by the correlation analysis unit 350 that the reflected signal received from the SAW temperature sensor 110 is reflected in response to the driving signal transmitted by the driving signal transmitter 320, The frequency of the transmitted driving signal corresponding to the received reflected signal may be determined as the resonance frequency of the SAW temperature sensor 110 . In other words, the temperature reading unit 360 is used for modulation of the driving signal transmitted by the driving signal transmitting unit 320 immediately before it is determined by the data processing unit 340 that the reflected signal has been received from the SAW temperature sensor 110 . The frequency of the carrier wave may be determined as the resonance frequency of the SAW temperature sensor 110 .

For example, the temperature reading unit 360 sweeps and modulates the pseudo-random data generated by the pseudo-random data generation unit 310 by the driving signal transmission unit 310 by sweeping the frequency of the carrier wave, and transmitting it to the SAW temperature sensor 110 . In , when the driving signal transmitter 320 transmits the driving signal whose frequency is modulated to A Hz to the SAW temperature sensor 110, the reflected signal was not received from the SAW temperature sensor 110, and then the frequency at a predetermined frequency interval If a reflected signal is received from the SAW temperature sensor 110 when a driving signal whose frequency is modulated by sweeping B Hz is transmitted to the SAW temperature sensor 110, the frequency of the driving signal transmitted immediately before the reflected signal is received B Hz may be determined as the resonance frequency of the SAW temperature sensor 110 .

When the resonant frequency of the SAW temperature sensor 110 is determined, the temperature reading unit 360 reads a temperature value corresponding to the resonant frequency of the SAW temperature sensor 110 , a resonant frequency value that varies depending on the temperature stored in the data storage unit 370 . The temperature sensed by the SAW temperature sensor 110 can be determined by reading from the mapping table to which the temperature values corresponding to the and resonant frequencies are mapped.

For example, the temperature value corresponding to the resonance frequency of 430 MHz of the SAW temperature sensor 110 is 40° C. and the temperature corresponding to the resonance frequency of 430.1 MHz is 30° C. is stored in the data storage unit 370, and the frequency is modulated to 430.1 MHz. If the reflected signal is received from the SAW temperature sensor 110 when the driving signal is transmitted to the SAW temperature sensor 110, the temperature reading unit 360 may determine that the temperature sensed by the SAW temperature sensor 110 is 30°C. have.

According to the SAW temperature sensor system according to the embodiment of the present invention, a driving signal generated by modulating pseudo-random data representing a pseudo-random binary sequence having high auto-correlation characteristics and low cross-correlation characteristics is transmitted to the SAW temperature sensor, and the SAW temperature By receiving the reflected signal from the sensor and reading the temperature from the reflected signal, even if the reflected signal from the SAW temperature sensor is damaged in the transmission/reception process, it is possible to verify whether the received reflected signal is a reflected signal in response to the driving signal. Temperature can be measured with high accuracy even in the environment.

In addition, it is verified whether the reflected signal received from the SAW temperature sensor is a reflected signal in response to the driving signal transmitted by the reader, and the reflected signal received from the SAW temperature sensor is reflected in response to the driving signal transmitted by the reader After it is verified that the signal is a validated signal, the temperature can be measured more accurately by reading the temperature from the reflected signal.

So far, preferred embodiments of the present invention have been mainly looked at. Those of ordinary skill in the art to which the present invention pertains will understand that the present invention may be implemented in a modified form without departing from the essential characteristics of the present invention. Therefore, the disclosed embodiments are to be considered in an illustrative rather than a restrictive sense. The scope of the present invention is indicated in the claims rather than the foregoing description, and all differences within the scope equivalent thereto should be construed as being included in the present invention.

100: SAW temperature sensor system
110: SAW temperature sensor
120: reader
310: pseudo-random data generating unit
320: drive signal transmitter
330: reflected signal receiver
340: data processing unit
350: correlation analysis unit
360: temperature reading unit
370: data storage unit

Claims (13)

SAW temperature sensor for transmitting a reflected signal to the received driving signal when receiving the driving signal through the antenna; and
a reader that generates and transmits the driving signal to the SAW temperature sensor, receives a reflected signal transmitted from the SAW temperature sensor, and reads the temperature sensed by the SAW temperature sensor from the received reflected signal,
the reader
a pseudo-random data generator for generating pseudo-random data representing a pseudo random binary sequence (PRBS);
a driving signal transmission unit for generating the driving signal by modulating the pseudo-random data generated by the pseudo-random data generating unit with a carrier wave, and transmitting the generated driving signal to the SAW temperature sensor;
a reflected signal receiver for receiving and demodulating a reflected signal from the SAW temperature sensor after transmitting the driving signal to generate reflected data representing a binary sequence;
The correlation between the pseudo-random data generated by the pseudo-random data generator and the reflected data demodulated by the reflected signal receiver is analyzed, and the reflected signal received from the SAW temperature sensor is driven according to the correlation analysis result. a correlation analysis unit for verifying whether the signal is a reflected signal in response to the driving signal transmitted by the signal transmitting unit; and
When it is verified that the reflected signal received from the SAW temperature sensor is a signal reflected in response to the driving signal transmitted by the driving signal transmitter, a temperature reading unit for reading the temperature sensed by the SAW temperature sensor from the reflected signal do,
The correlation analysis unit determines the correlation between the pseudo-random data and the reflection data based on a plurality of result data sets generated by bitwise XNOR operation of the binary sequence of the pseudo-random data and the binary sequence of the reflection data. SAW temperature sensor system, characterized in that analyzing the correlation between the random data and the reflected data. delete delete The method of claim 1,
The SAW temperature sensor is
An antenna for transmitting and receiving signals;
an inter-digital transducer (IDT) for generating a surface acoustic wave by a driving signal received through the antenna; and
and a reflector that reflects the surface acoustic wave generated by the IDT to generate a reflected wave and emits it to the antenna,
The resonance frequency of the SAW temperature sensor is changed according to the temperature of the SAW temperature sensor,
The reflected wave is generated when the frequency of the driving signal transmitted by the driving signal transmitter is equal to the resonance frequency of the SAW temperature sensor, and the reflected wave generated by the reflector is transmitted as a reflected signal through the antenna. SAW temperature sensor system. 5. The method of claim 4,
Further comprising a data processing unit for determining whether the reflection signal from the SAW temperature sensor is received by the reflection signal receiving unit,
When the reflected signal from the SAW temperature sensor is not received by the reflected signal receiver for a preset time period after the drive signal transmitter transmits the drive signal, the data processing unit changes the frequency of the carrier to generate the pseudo-random data. SAW temperature sensor system, characterized in that controlling the drive signal transmitter to retransmit to the SAW temperature sensor after modulation. delete 6. The method of claim 5,
The correlation analysis unit rotates the binary sequence of the pseudo-random data or the binary sequence of the reflection data, and generates the plurality of result data sets by performing bitwise XNOR operation of the binary sequence of the pseudo-random data and the binary sequence of the reflection data. do,
SAW temperature sensor system, characterized in that each of the result data sets represents a binary sequence representing a result value of a bitwise XNOR operation of the binary sequence of the pseudo-random data and the binary sequence of the reflected data performed in response to each rotation. 8. The method of claim 7,
SAW temperature sensor system, characterized in that the correlation analyzer determines the correlation between the pseudo-random data and the reflected data based on the sum of values constituting the binary sequence of each result data set. 9. The method of claim 8,
The correlation analysis unit replaces '0' constituting the binary sequence of each result data set with '-1', and sums all values of -1 and 1 constituting each result data set to obtain a plurality of correlations SAW temperature sensor system, characterized in that the correlation between the pseudo-random data and the reflected data is determined by calculating a value. 10. The method of claim 9,
SAW temperature sensor system, characterized in that the correlation analyzer determines the correlation between the pseudo-random data and the reflection data based on the magnitudes of the plurality of correlation values. 11. The method of claim 10,
The correlation analysis unit responds to the reflected signal received from the SAW temperature sensor in response to the driving signal transmitted by the driving signal transmitter when at least one correlation value exceeding a preset threshold value among the plurality of correlation values exists. SAW temperature sensor system, characterized in that it is determined by the reflected signal. The method of claim 1,
The SAW temperature sensor system, characterized in that the modulation of the pseudo-random data and the demodulation of the reflected signal are performed by a PSK (phase shift keying) method. 12. The method of claim 11,
The reader further includes a data storage unit storing a mapping table in which a resonant frequency value of the SAW temperature sensor that varies depending on the temperature of the SAW temperature sensor and a temperature value corresponding to each resonant frequency are mapped,
The temperature reading unit
Just before it is determined by the data processing unit that the reflected signal has been received from the SAW temperature sensor, the frequency of the carrier wave used in modulating the driving signal transmitted by the driving signal transmitter is determined as the resonance frequency of the SAW temperature sensor,
The SAW temperature sensor system, characterized in that the temperature sensed by the SAW temperature sensor is determined by reading a temperature value corresponding to the determined resonance frequency of the SAW temperature sensor from a mapping table stored in the data storage unit.

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