KR101199942B1 - Frequency hopping system - Google Patents

Abstract

The present invention relates to a frequency hopping system, and more particularly, to a system for performing frequency hopping using a fractional type of a phase locked loop (PLL) frequency synthesizer in radio frequency (RF) communication. will be. To this end, the present invention is a transmission unit for transmitting the transmission signal to the outside by adjusting the frequency up to a high frequency band after mixing a predetermined fractional frequency signal for frequency hopping to the transmission signal of the baseband transmission signal and the PN spreading code Wow; It is composed of a receiver which demodulates the baseband received signal by mixing the PN despreading code with the received signal outputted by mixing down the frequency of the high frequency received signal received from the outside and then mixing the predetermined fractional frequency signal for frequency hopping. .

Description

Frequency hopping system {FREQUENCY HOPPING SYSTEM}

1 is an exemplary view for explaining a sigma delta modulation and demodulation unit according to an embodiment of the present invention.

2 is an exemplary diagram for explaining a fractional frequency synthesizer using a sigma delta modulation and demodulation unit according to an exemplary embodiment of the present invention.

3 is an exemplary view showing a transmitter of a frequency hopping system according to an embodiment of the present invention.

4 is an exemplary view showing a receiver of a frequency hopping system according to an exemplary embodiment of the present invention.

The present invention relates to a frequency hopping system, and more particularly, to a system for performing frequency hopping using a fractional type of a phase locked loop (PLL) frequency synthesizer in radio frequency (RF) communication. will be.

In general, Frequency Hopping Spread Spectrum (FH-SS) is used for military or telecommunications security, and is band-spread like DS-CDMA (Direct Sequence Code Division Multiple Access) of PCS. It is a method of transmitting and receiving signals. Such FH-SS is a typical diffusion modulation method along with a direct diffusion modulation (DS) method. While the DS method modulates a carrier wave by a digital code sequence (pseudo noise sequence), the FH method discontinuously shifts a carrier frequency in a pattern determined by the code sequence. This is similar to many frequency code selection FSK. This method selects one million separate frequencies and is selected based on the information and code they transmit. The FH-SS system basically consists of a code generator and a fast response frequency synthesizer that responds to its output. Since the FH method transmits only a single frequency at each moment, the so-called far far problem is that when the desired station is far from the base station or the communication between the mobile stations and the disturbing station is near, the signal of the disturbing station is strong. The wave becomes unreceivable).

However, this conventional FH-SS system has a problem that is not free in the multi-access method. In addition, a hardware configuration for performing fast frequency hopping (FFH) is required.

Accordingly, an object of the present invention is to provide a frequency hopping system capable of performing a rapid frequency hopping by using a fractional type of a phase locked loop (PLL) frequency synthesizer in a radio frequency (RF) communication. In providing.

In order to achieve the above object, the present invention mixes a predetermined fractional frequency signal for frequency hopping with a baseband transmission signal and a PN spreading code, and then adjusts the frequency up to a high frequency band for transmission. A transmitter for transmitting a signal to the outside;

It consists of a receiver which demodulates the baseband received signal by mixing the PN despreading code with the received signal which is output by mixing down the frequency of the high frequency received signal received from the outside and then mixing the predetermined fractional frequency signal for frequency hopping. It features.

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

It should be noted that in the following description, only parts necessary for understanding the operation and operation according to the present invention will be described, and descriptions of other parts will be omitted so as not to distract from the gist of the present invention.

In the following description specific details of the frequency hopping communication system are presented to provide a more general understanding of the invention. It will be apparent to one of ordinary skill in the art that the present invention may be readily practiced without these specific details and also by their modifications.

1 is an exemplary view for explaining a sigma delta modulation and demodulation unit according to an embodiment of the present invention.

Referring to FIG. 1, the third sigma delta modulation and demodulation unit includes the first to third accumulators 110, 120, and 130, the first to third adders 150, 170, and 180, and the first and second flip-flops ( In one example, D-flip-flop (140, 160).

First, the first accumulator 110 receives a 12-bit input signal value k, adds it, outputs a carry out to the second adder 170, and outputs the carry out to the second accumulator 120. .

The second accumulator 120 receives and adds a 12-bit output signal of the first accumulator 110 to output a carryout to the first adder 150 and outputs the carryout to the third accumulator 130.

The third accumulator 130 receives a 12-bit output signal of the second accumulator 120, outputs a carryout to the first adder 150, and outputs the carry-out to the first flip-flop 140. In this case, the first flip-flop 140 and the second flip-flop 160 to be described later perform an operation of delaying one clock. The first flip-flop 140 outputs a carryout of the third accumulator 130, which is one clock delay, to the first adder 150. The second flip-flop 160 delays the output signal of the first adder 150 by one clock and then outputs it to the second adder 170.

The first adder 150 receives and adds a carryout from the second and third accumulators 120 and 130 and subtracts an output signal of the first flip-flop 140 from the added result. 2 is output to the adder 170.

The second adder 170 adds the carryout of the first accumulator 110 and the output signal of the first adder 150, and then subtracts the output value of the second flip-flop 160 from the added result. To the third adder 180. Here, the output signal of the second adder 170 is denoted as M (3 bits) in FIG. 1.

The third adder 180 receives an output signal of the second adder 170 and a signal N output from a sigma delta controller (not shown), which is not shown in FIG. The predetermined feedback coefficient Bi (t) is output.

Referring to FIG. 1, the operation of the sigma delta modulation and demodulator will be described. First, when a control bit of k bits is input, the first accumulator 110 adds an input signal. In other words, if the integer 5 is inputted, the output is the same as 10, 15, 20. In this case, the carry out is a bit carried out by the first accumulator 110 and is input to the second adder 170. Since 'k' is 12 bits, when the integer 4095 value is exceeded, '1' occurs in the carryout. In this manner, the signal is developed up to the second and third accumulators 120 and 130. In this case, the first and second adders 150 and 170 add a carry out signal, a signal delayed by the first and second flip-flops 140 and 160, and an original signal.

In this way, M (3) outputs random numbers from -2 to 4. If k is entered as integer 2048, then integers 0 and 1 are outputted repeatedly, the average of which is 0.5. Also, depending on the value of k, it can be expressed as

'M (3) = k / 4096', that is, decimal point output is possible. The M 3 bits are added to the upper 3 bits of N to output b1 (t).

The aforementioned configuration of FIG. 1 is an internal configuration of the sigma delta modulation and demodulation unit described below.

2 is an exemplary view for explaining a fractional frequency synthesizer using a sigma delta modulation and demodulation unit according to an exemplary embodiment of the present invention.

Referring to FIG. 2, the phase-frequency detector 200 detects the reference frequency and the phase and frequency of the output signal divided by the divider 250 and generates a pulse output signal according to the detected phase and frequency signal. .

The charge pump 210 supplies or decreases a predetermined current according to the pulse output signal from the phase-frequency detector 200 and outputs the predetermined current.

The low pass filter 220 filters the low frequency component of the signal output from the charge pump 210 and outputs a frequency control voltage.

The voltage controlled oscillator 230 oscillates according to the frequency control voltage output from the low pass filter 220 and outputs a frequency signal.

The sigma delta modulation and demodulator 240 modulates the sigma delta by the value K of the input signal applied from the divider controller 260 and a predetermined feedback coefficient Bi set therein, and the voltage controlled oscillator 230 The frequency signal output from is inputted to the clock to generate and output a fractional division ratio as the value K of the input signal changes. Here, the output signal has a minimum frequency adjustment range that can be adjusted by the division ratio.

The sigma delta controller 260 is an N bit signal for setting a value K of an input signal applied to the sigma delta modulator 240 and the division ratios N and N + 1 of the divider 250. Outputs

The frequency divider 250 has a fractional division ratio (N, N + 1) added to the N bit output signal set by the sigma delta controller 260 and the output signal of the sigma delta modulator 240, and the sigma. The delta modulation and demodulation unit 240 is changed by a fast change in clock speed. In addition, the divider 250 operates by the added fractional division ratios N and N + 1, and multiplies the division ratios N and N + 1 by a reference frequency signal to convert the voltage controlled oscillation frequency signal. Create

3 is an exemplary view showing a transmitter of a frequency hopping system according to an embodiment of the present invention.

Referring to FIG. 3, first, the baseband unit 310 outputs a baseband transmission signal.

The first mixer 320 mixes the baseband radio signal outputted through the baseband unit 310 and the PN spreading code, spreads the band of the baseband signal, and simultaneously encrypts and outputs the band.

The frequency hopping unit 200 performs frequency hopping by modulating the sigma delta so that the frequency division type is a fractional type so as to be maintained in a specific phase. Here, the internal configuration of the frequency hopping part 200 is the same as the above-described FIGS. 1 and 2. Accordingly, detailed description of the frequency hopping part 200 will be omitted.

The second mixer 330 mixes and outputs the output signal of the frequency hopping unit 200 and the band-spread baseband output signal of the first mixer 320.

The third mixer 340 mixes the output signal of the second mixer 330 and the carrier and outputs a high frequency signal whose frequency is upwardly adjusted.

The high power amplifier 350 outputs a high power amplified output signal of the third mixer 340. As a result, a high power amplified high frequency signal is transmitted through the antenna ANT.

Next, a receiver of a frequency hopping system will be described with reference to the accompanying drawings.

4 is an exemplary view illustrating a receiver of a frequency hopping system according to an exemplary embodiment of the present invention.

Referring to FIG. 4, first, a low noise amplifier (LNA) 410 low noise amplifies and outputs a high frequency signal received through an antenna ANT.

The first mixer 420 removes a carrier frequency from the high frequency received signal by mixing a high frequency received signal and a carrier.

The frequency hopping unit 200 performs sigma delta demodulation so that the frequency division type is a fractional type so as to be maintained in a specific phase.

The second mixer 430 mixes the output signal of the frequency hopping part 200 and the output signal of the first mixer 420 to down-regulate and output the hopping frequency signal.

The third mixer 440 mixes the output signal of the second mixer 430 and the PN despreading code and outputs a baseband signal that is band despread and demodulated.

The synchronizer 460 synchronizes N and k bits from the output signal of the third mixer 440 and then outputs the same to the frequency hopping unit 200. At this time, the frequency hopping part 200 is input to the sigma delta control unit 270, and the sigma delta modulation and demodulation unit 260 operates under the control of the sigma delta control unit 27 so that the phase-locking loop 250 performs a second mixer ( 430) outputs an output signal. Here, the frequency hopping part performs the same configuration and operation as the frequency hopping part described above. Accordingly, detailed description of the frequency hopping section will be omitted. In addition, the sigma delta modulation and demodulation unit demodulates the sigma delta by the input signal applied from the sigma delta control unit 270 and a predetermined feedback coefficient set therein, and the frequency signal output from the divider 250 is inputted to the clock and clocked. Fractional ratios in the form of fractions that change as the speed changes are output as signals with periodicity.

While the present invention has been described in connection with what is presently considered to be the most practical and preferred embodiment, it is to be understood that the invention is not limited to the disclosed embodiments, but is capable of various modifications within the scope of the invention. Therefore, the scope of the present invention should not be limited to the described embodiments, but should be defined not only by the scope of the following claims, but also by the equivalents of the claims.

As described in detail above, the present invention has an effect of enabling rapid frequency hopping by inserting a sigma delta modulation and demodulation unit into the upper bits of a programmable counter of a conventional phase synchronizing loop frequency synthesizer.

Claims (7)

A transmitter which transmits a transmission signal to the outside by mixing a baseband transmission signal and a PN spreading code with a predetermined fractional frequency signal for frequency hopping and then adjusting the frequency up to a high frequency band; It consists of a receiver which demodulates the baseband received signal by mixing the PN despreading code with the received signal which is output by mixing down the frequency of the high frequency received signal received from the outside and then mixing the predetermined fractional frequency signal for frequency hopping. Characterized by a frequency hopping system. The method of claim 1, wherein the transmitting unit, A baseband section for outputting a baseband signal; A first mixer for mixing the baseband signal and the PN spreading code to spread and output a band of the baseband signal; A frequency hopping unit for performing frequency hopping by sigma delta modulating the frequency division type into a fractional type to maintain a specific phase; A second mixer for mixing and outputting the output signal of the frequency hopping unit and the output signal of the first mixer; A third mixer for mixing the second mixer output signal and the carrier to output a high frequency signal whose frequency is upwardly adjusted; And a high power amplifier configured to high power amplify and output the output signal of the third mixer. The method of claim 2, wherein the frequency hopping unit, A fractional frequency synthesizing apparatus using a sigma delta modulation and demodulation unit includes: a phase-frequency detection unit for generating a pulse by detecting a phase difference between a reference frequency and an output signal of a divider; A charge pump which receives an output pulse of the phase-frequency detector and outputs a predetermined current; A low pass filter for outputting a frequency control voltage by filtering the low pass component of the signal output from the charge pump; A voltage controlled oscillator for oscillating according to the frequency control voltage output from the low pass filter and outputting a frequency signal; A divider which divides and outputs a frequency signal of the voltage controlled oscillator at a predetermined division ratio; A sigma delta modulation and demodulation unit configured to output a signal by sigma delta modulation in synchronization with the output signal of the divider; And a sigma delta control unit for outputting an input signal applied to the sigma delta modulation and demodulation unit and a signal for setting the division ratio of the frequency divider. The method of claim 3, wherein the sigma delta modulation and demodulation unit, The sigma delta modulation is performed by an input signal applied from the sigma delta control unit and a predetermined feedback coefficient set therein, and a fractional division ratio that changes as the clock speed is input to the frequency signal output from the divider is changed. A frequency hopping system, characterized in that it is output as a signal having a periodicity. The method of claim 1, wherein the receiving unit, A first mixer for mixing the high frequency received signal and the carrier to remove the received signal from the carrier frequency to output the received signal from which the carrier frequency has been removed; A frequency hopping unit for performing sigma delta demodulation so that the division type is a fractional type to be maintained in a specific phase; A second mixer configured to mix the output signal of the frequency hopping unit and the output signal of the first mixer and to adjust the frequency signal to be hopped down and to output it; A third mixer for mixing the output signal of the second mixer and the PN despreading code to output a band despread and demodulated baseband signal; A synchronization unit for synchronizing an input signal for sigma delta demodulation with the output signal of the third mixer and feeding the feedback signal back to the frequency hopping unit; And a baseband portion configured to receive a baseband signal from the output signal of the third mixer. The method of claim 5, wherein the frequency hopping unit, A fractional frequency synthesizing apparatus using a sigma delta modulation and demodulation unit includes: a phase-frequency detection unit for generating a pulse by detecting a phase difference between a reference frequency and an output signal of a divider; A charge pump which receives an output pulse of the phase-frequency detector and outputs a predetermined current; A low pass filter for outputting a frequency control voltage by filtering the low pass component of the signal output from the charge pump; A voltage controlled oscillator for oscillating according to the frequency control voltage output from the low pass filter and outputting a frequency signal; A divider which divides and outputs a frequency signal of the voltage controlled oscillator at a predetermined division ratio; A sigma delta modulation and demodulation unit configured to output a signal by sigma delta modulation in synchronization with the output signal of the divider; And a sigma delta control unit for outputting an input signal applied to the sigma delta modulation and demodulation unit and a signal for setting the division ratio of the frequency divider. The method of claim 6, wherein the sigma delta modulation and demodulation unit, The sigma delta demodulates according to an input signal applied from the sigma delta control unit and a predetermined feedback coefficient set therein, and the frequency division signal output from the divider is inputted to the clock to change the fractional division ratio that changes as the clock speed changes. A frequency hopping system, characterized in that it is output as a signal having a periodicity.

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