CN106656322B - A Method of Realizing Instantaneous Frequency Measurement Using Phase Modulator - Google Patents

Abstract

The invention discloses a kind of method for realizing Instantaneous Frequency Measurement using lithium niobate phase modulator, which is related to microwave technical field and technical field of photo communication, is mainly used in electronic reconnaissance field.Described this method is as shown in the picture, including laser, Polarization Controller, phase-modulator, standard single-mode fiber, optical splitter, the polarizer and photoreceiver.Utilize the Polarization-Sensitive characteristic of lithium niobate phase modulator, by rationally adjusting Polarization Controller, it can be realized simultaneously phase-modulation and intensity modulated, in conjunction with the dispersion characteristics of optical fiber, two opposite frequency response functions of variation tendency can be constructed, therefore resulting amplitude comparison function has faster variation in big frequency band.By calculating the power ratio of two branches up and down, may be implemented to treat the Frequency Estimation for surveying microwave signal.The measurement error that the device obtains in 1.6-24.6 GHz range is less than ± 0.3 GHz.

Description

The method for realizing Instantaneous Frequency Measurement using phase-modulator

Technical field

The present invention relates to technical field of photo communication and microwave technical fields more particularly to a kind of based on the micro- of phase-modulator Wave signal transient frequency measurement method.

Background technique

In electronic warfare field, intercept and capture and identify to realize from the radar of enemy or the radiation information of communication system, Firstly the need of the working frequency for estimating its electronic system.It can rapidly be realized by instantaneous frequency measurement technology and radiation source frequency is estimated Meter, in order to realize electronic reconnaissance, attack and defense.

Traditional electrical domain instantaneous frequency measurement system is generally realized by microwave interference to Frequency Estimation.Using microwave interference technology Instantaneous Frequency Measurement system need using RF Power Splitter and radio-frequency transmission line, and which has limited the expansions of system operating frequency Exhibition.As modern radar system gradually extends to higher frequency section, electrical domain Frequency Measurement System will be no longer applicable in.

Microwave photon technology can solve conventional electronics method and be difficult even insurmountable problem.Using microwave photon The Instantaneous Frequency Measurement system of technology auxiliary can work in higher frequency section, have more low-loss, smaller szie and anti-electromagnetism dry The advantages that disturbing.Therefore, the Technology of Measuring Instant Frequency based on microwave photon technology is expected to play in future electronic war field important Effect.

The invention proposes a kind of simple microwave photons of structure to assist Instantaneous Frequency Measurement system.Utilize lithium niobate phase Modulated optical signal is divided into two branches up and down, utilizes list by the modulator characteristic inconsistent to TE and TM optical mode modulation efficiency The dispersion characteristics of mode fiber can construct two opposite power fading functions of variation tendency in upper and lower two branch respectively.It is logical The power ratio for comparing two paths of signals is crossed, the frequency values of incident microwave signals can be quickly estimated.The apparatus structure is simple, Only need a light source and a phase-modulator, it is easy to accomplish.

Summary of the invention

The technical solution of the invention is as follows: the method for realizing Instantaneous Frequency Measurement using phase-modulator, feature exist In: the method using distributed feedback laser, Polarization Controller, phase-modulator, standard single-mode fiber, optical splitter, Inclined device and photodetector, vector network analyzer.The output end of laser passes through the first Polarization Controller and phase-modulation Device is connected, and the output end of phase-modulation is connected with standard single-mode fiber, and optical fiber output port is connected with optical splitter, optical splitter The first output port be connected with photoreceiver 1, the second output terminal mouth of optical splitter be sequentially connected respectively Polarization Controller and The polarizer finally injects photoreceiver 2.

Above-mentioned phase-modulator is Z axis cutting phase modulator, is apparently higher than TE optical mode to the modulation efficiency of TM optical mode Formula.

Above-mentioned photoreceiver integrates PIN diode by a waveguide and a trans-impedance amplifier is constituted.

Using phase-modulator realize transient microwave frequency measurement method the following steps are included:

(1) it is by the wavelength that laser exportsλLinearly polarized light be injected into phase-modulator by Polarization Controller, adjust Section Polarization Controller makes the main shaft of incident ray polarized light and phase-modulator in 45 °；

(2) prevention at radio-frequency port of the phase modulated device of microwave signal to be measured of unknown frequency is loaded on phase-modulator, is adjusted The polarisation-multiplexed signal of system output TM and TE；

(3) polarisation-multiplexed signal is transmitted by 5km standard single-mode fiber；

(4) the palarization multiplexing optical signal transmitted through optical fiber is divided into two branches up and down using optical splitter；

(5) optical signal of branch is directly injected into photoreceiver on；

(6) optical signal of branch first passes through Polarization Controller under, and TE and TM polarization signal are then realized at the polarizer Interference, the light wave after interference is linearly polarized light, into photoreceiver.

(7) by adjusting the Polarization Controller of lower branch, the main shaft and TE and TM polarization state of the polarizer can be changed simultaneously It is opposite to realize that the frequency response function of two branches up and down has for relative phase shift between two polarization states of angle and TE and TM Variation tendency.

(8) by calculating the electric signal power ratio of two branches up and down, the frequency of microwave signal to be measured can be uniquely determined Rate value.

The invention proposes a kind of simple microwave photons of structure to assist instantaneous frequency measurement method.This method utilizes niobic acid Modulated optical signal is divided into two branches up and down by the lithium phase-modulator characteristic different to the modulation efficiency of TE with TM optical mode, Using the dispersion characteristics of single mode optical fiber, two opposite frequency response letters of variation tendency can be constructed in upper and lower two branch respectively Number can construct the amplitude comparison function with larger slope by comparing the power of upper and lower branch, and then realize bigger High-precision Instantaneous Frequency Measurement in bandwidth range.

This method only needs a phase-modulator, therefore does not need bias control circuit.The configuration of single laser source so that System does not need optical wavelength division multiplexing device, and frequency-measurement accuracy is not influenced by light source power floating.

This method does not need the device of the frequency limiteds such as RF Power Splitter or electric frequency mixer, the frequency measurement range of system only light The limitation of the bandwidth of transmitter and photoreceiver.

Detailed description of the invention

Fig. 1 is that the present invention is based on the Instantaneous Frequency Measurement schematic diagrams of phase-modulator；

Fig. 2 is the frequency response function figure of upper and lower two branch in experiment test；

Fig. 3 is to test in test, obtained two branch power ratio curve figure up and down；

Fig. 4 is frequency measurement in experiment test；

Fig. 5 is frequency error measurement result figure in experiment test.

Specific embodiment

Elaborate with reference to the accompanying drawing to the embodiment of the present invention: the present embodiment before being with technical solution of the present invention It puts and is implemented, the detailed implementation method and specific operation process are given, but protection scope of the present invention is not limited to down The embodiment stated:

As shown in Figure 1, device includes: distributed feedback laser, Polarization Controller 1, vector network analysis in the present embodiment Instrument, phase-modulator, optical splitter, Polarization Controller 2, the polarizer, photoreceiver 1 and photoreceiver 2.The output end of laser Mouth is connected with the input port of Polarization Controller 1, and the output of Polarization Controller is connected with the input port of phase-modulator, radio frequency The output of signal source is connected with the prevention at radio-frequency port of phase-modulator.The input port phase of the output port of phase-modulator and optical fiber Even, the output port of optical fiber is connected with the input port of optical splitter, the upper branch of optical splitter export directly with photoreceiver 1 It is connected, the lower branch output of optical splitter is sequentially connected Polarization Controller 2 and the polarizer, the output port and light of the polarizer respectively The input port of receiver is connected.By adjusting two Polarization Controllers, the frequency response function of upper and lower two branch has on the contrary Variation tendency, can estimate the input power of radiofrequency signal by calculating power ratio.

In this example, the specific implementation step of method is:

Step 1: laser generates operation wavelengthHalf-wave is input to after Polarization Controller 1 for the light carrier of 1552 nm Voltage is the Z axis cutting phase modulator of 7 V.Adjustment Polarization Controller 1 makes the linearly polarized light and phase-modulator of input Main shaft is in 45 °.The radio frequency output of vector network analyzer is connected with the prevention at radio-frequency port of phase-modulator, output radio-frequency power setting For -3 dBm.

Step 2: modulated polarisation-multiplexed signal is input in 5 km standard single-mode fibers, the abbe number of optical fiber is 17 ps/nm/km。

Step 3: the optical signal of optical fiber output is divided into two branches up and down.Upper branch is directly connected with photoreceiver 1, under Branch output is successively connected with Polarization Controller 2, the polarizer and photoreceiver 2.Polarization Controller 2 is adjusted to polarize at two The relative phase shift introduced between state is 0.8 π, and polarization direction and polarizer angle are 0.14 π.

Step 4: the output end of photoreceiver is connected with the rf inputs of vector network analyzer.Utilize vector network The frequency response curve of available two branches up and down of analyzer, as shown in Figure 2.

Step 5: amplitude can be constructed using the power ratio of upper and lower two branch according to resulting frequency response curve Comparison function, as shown in Figure 3.Frequency is established with radio-frequency power than corresponding look-up table using measured data.

Step 6: the RF signal power of input is changed to -20 dBm for the feasibility of validated measurement systems, change The frequency of input signal, and record the power of two branches up and down.Using established look-up table, by tabling look-up, frequency is realized in search Estimation.Measurement result as shown in figure 4, corresponding measurement error as shown in figure 5, error be less than ± 0.3GHz.

To sum up, the present invention realizes the Instantaneous Frequency Measurement to microwave signal, the device using lithium niobate phase modulator Structure is simply easily achieved, cheap, is not influenced by electronic bottleneck.Further, since using only single laser source, system is not WDM device is needed, and measurement accuracy is not influenced by light source power fluctuation.The program only needs a phase-modulator, There is no the bias drift problems for being influenced by environment and being generated, therefore do not need complicated bias control circuit.Pass through construction two The opposite frequency response function of variation tendency, the program can realize the microwave frequency measurement of large scale and high accuracy.

In short, embodiments described above is only the embodiment of the present invention, not it is only used for limiting protection model of the invention It encloses, it is noted that for those skilled in the art, in present disclosure, can also make Several equivalent variations and replacement, phase-modulator are not limited to Z axis cutting, optical carrier wavelength, the length of optical fiber, dispersion values, polarization The adjustment of state etc. also should be regarded as the scope of protection of the invention.

Claims (3)

1. a method utilizing phase modulator to realize instantaneous frequency measurement, is characterized in that, described method adopts distributed feedback laser, polarization controller, phase modulator, standard single-mode fiber, optical splitter, polarizer and Optical receiver, the output of the laser is connected to the phase modulator through the first polarization controller, the microwave signal of unknown frequency to be measured is input to the radio frequency port of the phase modulator, the output of the phase modulator is connected to the optical fiber, and the output port of the optical fiber is connected to the optical branch The first output port of the optical splitter is connected to the first optical receiver, the second output port of the optical splitter is connected to the second polarization controller and the polarizer in turn, and finally injected into the second optical receiver, The frequency information of the signal to be measured can be estimated by measuring and comparing the output RF power. The phase modulator has different modulation efficiencies for TE and TM optical modes. By adjusting the first polarization controller, the incident line polarized light and the main axis of the phase modulator At a certain angle, after transmission through the optical fiber, the output of the upper branch of the optical splitter is a phase modulation signal, and the second polarization controller of the lower branch is adjusted. After the polarizer, the electro-optical intensity modulation can be realized. Considering the dispersion effect, The frequency response functions of the upper branch and the lower branch have opposite trends. The frequency response functions of the upper and lower branches can be measured by a vector network analyzer, and the power ratio of the upper branch and the lower branch can be calculated using the obtained data. A look-up table of frequency-RF power ratio can be established. For microwave signals of unknown frequency to be measured, the power ratio of the upper and lower branches can be calculated. The frequency information of the signal to be measured can be quickly estimated by searching the look-up table. 2. the method that utilizes phase modulator to realize instantaneous frequency measurement according to claim 1, it is characterized in that, the modulation efficiency of phase modulator for TE and TM optical modes is different, combined with polarization controller and polarizer can realize phase simultaneously Modulation and intensity modulation. 3. the method that utilizes phase modulator to realize instantaneous frequency measurement according to claim 1, is characterized in that, the frequency response function of upper and lower branches has opposite change tendency, by calculating the power ratio of upper and lower two branches, the amplitude of gained The comparison function has a larger slope over a larger frequency range.