KR101092484B1 - terahertz spectrum analyzer - Google Patents

Abstract

The present invention relates to a THz spectrum analyzer, and more particularly, to a THz spectrum analyzer capable of higher accuracy based on absolute frequency and absolute power measurement.
To this end, the present invention includes an absolute frequency measurement unit for measuring the absolute frequency of the THz wave through the optical heterodyne detection method using a THz frequency comb as a local oscillator and a THz detector as a heterodyne detector; An absolute output measuring unit measuring an absolute output of a THz wave by using a THz detector; It is configured to provide a THz spectrum analyzer, characterized in that based on the absolute frequency and the absolute output, it is possible to obtain the output spectrum of the THz continuous wave.

Description

Terahertz spectrum analyzer

The present invention relates to a terahertz (THz) spectrum analyzer, and more particularly, to a THz spectrum analyzer capable of higher accuracy based on absolute frequency and absolute power measurements.

As the THz wave technology advances, accurate measurement of THz frequency and output is required as in the optical frequency field, and absolute frequency and output measurement are an important problem, especially in metrology.

While many results have been reported for optical frequency measurements, few have been reported for frequency measurements in the THz field. In addition to conventional Fourier-transform spectrometers, Fabry-Perot interferometer And a THz spectrometer using a bolometer detector have been reported, which has the disadvantage of requiring Fourier transforms and algorithms to obtain THz spectra from the measurement results.

Recently, the absolute frequency and spectral shape of THz continuous waves are measured using a THz frequency comb and a photoconductive antenna, and research on THz radiometry has been continued.

The present invention has been studied in view of the above points, it is composed of a plurality of local oscillator very stable at the frequency point regularly separated by the repetition frequency to function as a frequency ruler (frequency ruler) The absolute frequency of the THz wave is measured by an optical heterodyne detection method using a THz frequency comb and a THz detector as a heterodyne detector, and the absolute output of the THz wave is measured by the THz detector. The aim is to provide a precise THz spectrum analyzer based on absolute frequency and power measurements.

The present invention for achieving the above object is an absolute frequency measuring unit for measuring the absolute frequency through the optical heterodyne detection method using a THz frequency comb as a local oscillator and a THz detector as a heterodyne detector; An absolute output measuring unit measuring an absolute output of a THz wave to be measured using the THz detector; It is configured to provide a THz spectrum analyzer, characterized in that based on the absolute frequency and the absolute output, it is possible to obtain the output spectrum of the THz continuous wave.

In a preferred embodiment, the absolute frequency measuring unit comprises: a femtosecond laser for generating an optical frequency comb; A THz frequency comb generator for receiving a stabilized femtosecond optical pulse (optical frequency comb) from the femtosecond laser and generating a stabilized THz frequency comb; A THz beam combiner for combining the THz frequency comb with the THz wave to be measured; A THz detector for detecting the THz wave coupled in the THz beam combiner; A radio frequency (RF) spectrum analyzer for measuring the spectrum of the heterodyne bit signal detected by the THz detector; A frequency counter for measuring a repetition frequency of the femtosecond laser through a photo detector; And a control unit.

In addition, the repetition frequency of the femtosecond laser is characterized in that stabilized at a variable reference frequency of the signal generator based on the frequency standard.

In particular, the absolute frequency measuring unit comprises: a repetition frequency stabilization device for stabilizing the repetition frequency of the femtosecond laser; An optical detector for transmitting an optical frequency comb signal from the femtosecond laser to the repetitive frequency stabilization device; It characterized in that it further comprises.

In another preferred embodiment, the absolute power measuring unit comprises: a chopper for modulating the THz wave to be measured, in addition to the THz detector for measuring the output of the THz wave to be measured; A lock-in amplifier for measuring the THz wave detected by the THz detector; And further comprising:

Through the above problem solving means, the present invention provides the following effects.

According to the present invention, the absolute frequency is measured by the optical heterodyne detection method using the THz frequency comb as the local oscillator and the THz detector as the heterodyne detector, and the absolute power is measured by the THz detector. The spectrum can be obtained, providing a more precise THz spectrum analyzer.

1 is a schematic diagram showing a THz spectrum analyzer according to the present invention;
2 is an output spectrum of a continuous THz wave around 336.168 GHz measured by the THz spectrum analyzer of the present invention.

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

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

1 is a schematic diagram showing a THz spectrum analyzer according to the present invention.

The present invention provides accurate THz spectrum in which the spectrum of THz continuous waves is measured based on the absolute frequency and output through absolute frequency measurement by optical heterodyne detection using THz frequency comb and THz detector and absolute power measurement using THz detector. It was intended to provide an analyzer.

For this purpose, an optical heterodyne detection scheme is used to measure the absolute frequency of the THz wave, the stabilized THz frequency comb is used as the local oscillator, and the THz detector is used as the heterodyne detector.

According to the present invention, a stabilized THz frequency comb is adopted as the local oscillator, which is made in the THz frequency comb generator 40 which receives the optical frequency comb irradiated by the femtosecond laser 10 having the stabilized repetition frequency.

That is, the stabilized THz frequency comb generated by the THz frequency comb generator using the femtosecond laser 10 whose stabilization frequency is stabilized is used as the local oscillator.

The optical frequency comb from the femtosecond laser 10 is f _m = mf _r + f _ceo It consists of several modes with a frequency of m, m is an integer, f _r is a repetition frequency, and f _ceo is a carrier-envelop offset frequency.

At this time, by the optical frequency comb from the femtosecond laser 10, a THz frequency comb composed of several modes having a frequency of f _n = nf _{r r} is generated, where n is an integer.

Therefore, only the repetition frequency of the femtosecond laser 10 can be stabilized, so that the frequency of the THz frequency comb can be stabilized. Therefore, the optical frequency comb from the femtosecond laser 10 is detected by the photodetector PD1, and the detection signal is detected. Is input to the repetition frequency stabilization device 12, the stable repetition frequency of the femtosecond laser 10 is implemented by the repetition frequency stabilization device.

At this time, the variable reference frequency signal of the signal generator 14 synchronized to the frequency standard 16 is input to the repetition frequency stabilization device 12, and the repetition frequency is stabilized at the reference frequency, so that the THz frequency comb is a frequency standard. It has the same frequency stability as (16). As the frequency standard 16, a rubidium (Rb) frequency standard or a hydrogen maser can be used.

According to the present invention, the THz frequency comb generated in the THz frequency comb generator 40 enters the THz beam combiner 18 and simultaneously the THz wave to be measured enters the THz beam combiner 18 and is measured with the THz frequency comb. THz waves are combined by THz beam combiner 18, and the combined THz waves are detected by THz detector 22.

In this case, the THz frequency comb generator 40 may be a photoconductive antenna, a nonlinear photonic crystal, or a semiconductor, and the THz detector 22 may be a bolometer.

On the other hand, the spectrum of the heterodyne bit signal between the THz frequency comb detected by the THz detector 22 and the THz wave to be measured is measured by the RF spectrum analyzer 24, and at the same time the repetition frequency is measured by the photodetector PD2. As measured by the frequency counter 26, the RF spectrum analyzer 24 and the frequency counter 26 are synchronized to the frequency standard 16.

That is, the waveform measured by the THz detector 22 (spectrum of the detected bit signal) is amplified by the preamplifier 30, and the amplified bit signal is measured by the RF spectrum analyzer 24, wherein the femtosecond laser is measured. The repetition frequency of 10 is measured at the frequency counter 26 via the photo detector PD2.

Of the many bit signals between the THz wave and the various modes of the THz frequency comb, only the bit signal resulting from the THz frequency comb mode closest to the THz wave is measured in the detection band determined by the THz detector 22 and the preamplifier 30. do.

On the other hand, the absolute frequency of the THz wave is bar, f _THz according to the bit frequency (f _b) by f _THz = Nf _r ± f _b is the absolute frequency of the THz wave, N is closest to the comb mode for the THz wave ( comb mode).

From the bit frequencies f _b and f _b + Δf _b measured at different repetition frequencies f _r and f _r + Δf _r , an absolute frequency can be determined by Equation 1 below.

THz continuous waves can be easily measured through the THz spectrum analyzer of the present invention. 2 is a spectrum of a bit signal measured at a resolution bandwidth (RBW) of 1 Hz and a frequency interval of 1 Hz, and an output spectrum of a continuous THz wave represented by an absolute frequency (lower horizontal axis) as described above. to be.

According to the present invention, in order to represent the output spectrum by absolute output, the total absolute output of the THz wave is measured directly using the THz detector 22. The THz detector 22 should have responsivity. The THz wave, which is mechanically modulated by the chopper 20, is detected by the THz detector 22 and amplified by the preamplifier 30 for a more accurate output measurement. The detected signal is then measured by the lock-in amplifier 32.

The total absolute power of the THz wave is evaluated by P _THz = V / ΓG , where P _THz is the total absolute power, V is the value measured from the lock-in amplifier, Γ is the reactivity of the THz detector 22, G Represents the gain of the preamplifier 30.

The absolute output of the THz wave is linearly associated with the output of the bit signal by P _THz = RP _b / 2Γ ² G ² P _N , where R is the resistance, P _b is the output of the bit signal, and P _N is the bit signal. Represents the absolute output of the associated N-th comb mode.

Thus, the output spectrum of FIG. 2 can be expressed such that the frequency-integrated output is equal to the total absolute output P _THz as shown on the right vertical axis.

As a result, according to the present invention, the output spectrum of the THz wave expressed in absolute frequency and absolute output can be obtained.

In conclusion, according to the present invention, it is possible to provide a THz spectrum analyzer capable of measuring the output spectrum of the THz continuous wave represented by the absolute frequency and the output with high precision based on the absolute frequency and the absolute output measurement.

10 femtosecond laser 12 repetition frequency stabilization device
14: signal generator 16: frequency standard
18: THz Beam Combiner 20: Chopper
22: THz detector 24: RF spectrum analyzer
26 frequency counter 30 preamplifier
32: lock-in amplifier 40: THz frequency comb generator
PD1, PD2: Photo Detector

Claims (9)

An absolute frequency measuring unit measuring an absolute frequency through an optical heterodyne detection method using a THz frequency light generator that makes a THz frequency comb as a local oscillator and a THz detector as a heterodyne detector;
An absolute output measuring unit measuring an absolute output of a THz wave by using a THz detector;
By configuring, based on the absolute frequency and the absolute output, so as to obtain the output spectrum of the THz continuous wave,
The absolute frequency measuring unit,
A femtosecond laser 10 having a stabilized repetition frequency;
A THz frequency comb generator 40 that receives the optical frequency comb irradiated from the femtosecond laser having the stabilized repetition frequency and generates a stabilized THz frequency comb;
A THz beam combiner (18) for coupling the THz frequency comb and the THz wave to be measured;
A THz detector 22 for detecting the THz wave coupled at the THz beam combiner 18;
An RF spectrum analyzer (24) for measuring the spectrum of the bit signal detected by the THz detector (22);
A frequency counter (26) for measuring the repetition frequency of the femtosecond laser through a photo detector (PD2);
It is configured to include,
The absolute output measuring unit,
A chopper 20 for modulating the THz wave to be measured;
A THz detector 22 for detecting the modulated THz wave;
A lock-in amplifier 32 for measuring the THz wave from the signal detected by the THz detector 22;
THz spectrum analyzer, characterized in that configured to include.
delete The method according to claim 1,
THz spectrum analyzer, characterized in that the repetition frequency of the femtosecond laser (10) is stabilized at a variable reference frequency of the signal generator (14) based on the frequency standard (16).
The method according to claim 1, wherein the absolute frequency measuring unit:
A repetition frequency stabilization device (12) for stabilizing the repetition frequency of the femtosecond laser (10) to a variable reference frequency of the signal generator (14);
A photo detector (PD1) for transmitting the optical frequency comb signal from the femtosecond laser (10) to the repetitive frequency stabilization device (12) for this purpose;
THz spectrum analyzer, characterized in that it further comprises.
The method according to claim 1,
THz spectrum analyzer, characterized in that the RF spectrum analyzer (24) and the frequency counter (26) is synchronized with a frequency standard (16).
The method according to claim 1,
The THz frequency comb generator (40) is a THz spectrum analyzer, characterized in that the photoconductive antenna, nonlinear photonic crystal, or semiconductor.
delete delete The method according to claim 1,
The THz spectrum analyzer, characterized in that the THz detector 22 is a bolometer.

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