CN206893802U - A kind of unit line array of X-band Optically controlled microwave four - Google Patents
A kind of unit line array of X-band Optically controlled microwave four Download PDFInfo
- Publication number
- CN206893802U CN206893802U CN201720813279.4U CN201720813279U CN206893802U CN 206893802 U CN206893802 U CN 206893802U CN 201720813279 U CN201720813279 U CN 201720813279U CN 206893802 U CN206893802 U CN 206893802U
- Authority
- CN
- China
- Prior art keywords
- period
- time
- unit line
- line array
- medium substrate
- Prior art date
- Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
- Expired - Fee Related
Links
Landscapes
- Variable-Direction Aerials And Aerial Arrays (AREA)
Abstract
The utility model discloses a kind of unit line array of X-band Optically controlled microwave four, including medium substrate, element antenna and constant power distributor;Constant power distributor is fixed on a surface of medium substrate;Constant power distributor includes the power splitter of the three-level one-to-two of two series connection;Two power splitters are connected with two element antennas respectively;Element antenna guides a period of time into and positioned at the excitation a period of time for guiding a period of time end into including what several neatly sorted from top to bottom;Excitation a period of time is connected with power splitter;Reflection a period of time is provided with another surface of medium substrate.The utility model is simple in construction, has the characteristics of miniaturization, easy to process low with cost, by the optimization design to structure, is effectively reduced the energy loss of antenna array, improves its gain.
Description
Technical field
The utility model belongs to the technical field of wireless communication technology, and in particular to a kind of X-band Optically controlled microwave four is single
First line array.
Background technology
In recent years, Phased Array Radar Antenna due to turning velocity is fast, low visibility, be difficult to be detected the advantages that it is logical in the modern times
There is increasingly consequence in letter system, in order to improve Anti-jamming Ability for Radar, reduce antiradiation missile and threaten, strengthen mesh
Resolving power and discernment are marked, solves the problems, such as multi-target imaging, Phased Array Radar Antenna must possess as far as possible as other antennas
Big instant bandwidth, but the aperture effect that has of phased-array radar in itself and aperture fill time make the sensing of its wave beam with frequency
Rate changes and offset, i.e., when sending and receiving, signal has certain delay.
Effect of the phased array antenna in ultra-wideband operations system is considerable in modern radar system, but is being
Aperture effect and aperture fill time in system be present glances off antenna beam, and an effective way for solving this problem is
Use real time delay (True Time Delay, TTD) technology.In recent years, TTD beam-forming technologies are combined with photon technology
The antenna array beam shaper of analog fiber optic link composition be widely studied, such as chirped fiber Bragg gratings, quick
Tunable laser, mirror based fiber optica, wave filter etc..
In past 50 years, phased array antenna system is listed in speed, sensitivity and big relative to mechanically scanned array
It is small etc. to have very big advantage.The Wave beam forming of the phased array antenna of photonic system control has many intrinsic characteristics, such as light
Just, compact and inexpensive phase array antenna beam shaper.The optical means for realizing photon TTD Beam-formers many at this stage
It has been be suggested that, such as Fourier Optics dispersive optical fiber, fiber grating or substrate guided wave technology are used, however, cost, size, work(
Component count needed for consumption and large-scale array is to limit the principal element of these system practical operations.
Utility model content
The purpose of this utility model is to be directed to above-mentioned deficiency of the prior art, there is provided a kind of X-band Optically controlled microwave
Four unit line arrays, it is bad to solve low prior art antenna beam deflection, broadband width and gain and miniaturization effect
Problem.
To reach above-mentioned purpose, the utility model adopts the technical scheme that:
A kind of unit line array of X-band Optically controlled microwave four, including medium substrate, element antenna and constant power distributor;
Constant power distributor is fixed on a surface of medium substrate;The three-level one that constant power distributor includes two series connection is divided
Two power splitter;Two power splitters are connected with two element antennas respectively;Element antenna includes several neat rows from top to bottom
Sequence guides a period of time into and positioned at the excitation a period of time for guiding a period of time end into;Excitation a period of time is connected with power splitter;In the another of medium substrate
One surface is provided with reflection a period of time.
Preferably, the patch length l1=0.45 λ in a period of time are guided intog, λgFor the operation wavelength of electromagnetic wave in the dielectric substrate.
Preferably, the patch length l2=0.5 λ in a period of time are encouragedg, λgFor the operation wavelength of electromagnetic wave in the dielectric substrate.
Preferably, the size for reflecting a period of time is 60mm*25.5mm.
Preferably, the bottom of medium substrate is provided with 50 ohm of sub-miniature A connectors being connected with constant power distributor.
Preferably, the material of medium substrate is the medium sheet materials of Rogers RT-duroid 6100, and its dielectric constant is
10.2nd, thickness 0.635mm, loss angle tangent 0.023.
The unit line array of X-band Optically controlled microwave four provided by the utility model, has the advantages that:
The utility model fixes four element antennas on medium substrate, and element antenna is connected shape with the power splitter of one-to-two
Into four unit line arrays, the spacing between each unit line array is half free space wavelength, is set in power splitter opposite
In the reflection a period of time put, electromagnetic wave is reflected, improve the figuration precision of antenna pattern main beam, i.e., radiate antenna array
Directional diagram to the face is reflected, and reduces the energy loss of antenna, improves gain.Except this, pass through optimization design, optimization Simulation
And actual measurement, and compared with traditional light-operated phase control techniques, its projecting point is, the utility model antenna reflection coefficient less than-
10dB bandwidth of operation is 10.1GHz-11.5GHz;Antenna gain has reached 8.0dBi at center frequency point 10GHz, has wider
While broadband, the energy loss of antenna array is effectively reduced, improves its gain.
The utility model is simple in construction, has the characteristics of miniaturization, easy to process low with cost, passes through the optimization to structure
Design, is effectively reduced the energy loss of antenna array, improves its gain.
Brief description of the drawings
Fig. 1 is the positive structure schematic of the unit line array of X-band Optically controlled microwave four.
Fig. 2 is the structure schematic diagram of the unit line array of X-band Optically controlled microwave four.
Fig. 3 is the straight line system of battle formations of the unit line array of X-band Optically controlled microwave four.
Fig. 4 is emulation and the test reflectance factor comparison diagram of the unit line array of X-band Optically controlled microwave four.
Fig. 5 is the gain diagram of the unit line array of X-band Optically controlled microwave four.
Wherein, 1, element antenna;2nd, a period of time is guided into;3rd, a period of time is encouraged;4th, power splitter;5th, medium substrate;6th, 50 ohm of SMA
Joint;7th, a period of time is reflected.
Embodiment
Specific embodiment of the present utility model is described below, in order to which those skilled in the art understand
The utility model, it should be apparent that the utility model is not limited to the scope of embodiment, to the common skill of the art
For art personnel, if various change in the spirit and scope of the present utility model that appended claim limits and determines,
These changes are it will be apparent that all are created in the row of protection using the utility model of the utility model design.
According to one embodiment of the application, with reference to shown in figure 1 and Fig. 2, the unit of X-band Optically controlled microwave four of this programme
Line array, including medium substrate 5, element antenna 1 and constant power distributor.
The bottom of medium substrate 5 is provided with 50 ohm of sub-miniature A connectors 6 being connected with the constant power distributor, is easy to integrated phase
Chip is moved, one beam scanning is realized to improve.The medium sheet materials of material Rogers RT-duroid 6100 of medium substrate 5, its
Dielectric constant is 10.2, thickness 0.635mm, loss angle tangent 0.023.
Constant power distributor is fixed on the bottom on a surface of medium substrate 5, and constant power distributor is by the three of two series connection
The power splitter 4 of level one-to-two is composed in series.
Element antenna 1 guides a period of time 2 into and positioned at the excitation a period of time 3 for guiding the end of a period of time 2 into by what is neatly sorted from top to bottom
Composition, the excitation a period of time 3 of two power splitters 4 respectively with two element antennas 1 are connected.
Reflection a period of time 7 is provided with another surface of medium substrate 5, electromagnetic wave is reflected, improved by reflection a period of time 7
The figuration precision of antenna pattern main beam, i.e., the directional diagram that antenna array is radiated to the face are reflected, and reduce the energy of antenna
Amount loss.
Guide a period of time 2, reflector into and encourage the parameter between a period of time 3 as follows:
Operation wavelength of the electromagnetic wave in medium substrate 5 be:
Wherein εeFor the relative dielectric constant of medium substrate 5, c is the free space light velocity, f0For the centre frequency of antenna, λg
For the operation wavelength of electromagnetic wave in media as well.
Spacing between adjacent cells antenna 1 is:
Wherein c is the free space light velocity, and f is that the centre frequency f of medium substrate 5 is 10GHz.
Spacing h1 between reflector and excitation a period of time 3 is 0.25 λg, excitation a period of time 3 and guide a period of time 2 and adjacent into
The spacing d guided between a period of time 2 is 0.2 λg, wherein λgFor operation wavelength of the electromagnetic wave in medium substrate 5.
Guide the patch length l1=0.45 λ in a period of time 2 intog, wherein λgFor operation wavelength of the electromagnetic wave in medium substrate 5.
Encourage the patch length l2=0.5 λ in a period of time 3g, wherein λgFor operation wavelength of the electromagnetic wave in medium substrate 5.
The size for reflecting a period of time 7 is 60mm*25.5mm.
With reference to figure 3, the element antenna 1 and power splitter 4 on the surface of medium substrate 5 one by parameter L, W, l1, l2, w2, h1, h2,
D, s, la, la1, wa, lb, lb1, wb, lc and wc determine, this 17 parameter values be respectively 60mm, 46mm, 5mm, 5mm, 1.8m,
1.8mm、3mm、2.26mm、0.5mm、2.8mm、2.78mm、0.5mm、7.5mm、7.5mm、1.65mm、7.5mm、1mm;Medium base
The parameter in reflection a period of time 7 of the another side of plate 5 is L and w1, and the two parameter values are respectively 60mm, 25.5mm.
Contrasted with reference to figure 4 and Fig. 5, Fig. 4 for the emulation of the unit line array of X-band Optically controlled microwave four and test reflectance factor
Figure.As can be seen from the figure as reflectance factor S11≤- 10dB, the frequency range corresponding to simulation result is 10.1GHz-
11.5GHz, S11 minimum value are -23dB;Frequency range corresponding to test result is 10.0GHz-11.2GHz, and S11 is most
Small value is -20dB, and the two relative bandwidth is more or less the same.Resonant frequency point corresponding to simulation result is 10.7GHz, simulation result
Corresponding resonant frequency point is 10.55GHz.Generally the two is more or less the same, but the two has necessarily from oscillogram
Deviation, it is caused the reason for extraneous factor and sub-miniature A connector when making mainly due to antenna, measurement.Fig. 5 is X-band light
The gain diagram of the unit line array of phased array four is controlled, as can be seen from the figure its maximum gain is 8dB.
By optimization Simulation and actual measurement, compared with traditional light-operated phase control techniques, its projecting point is the utility model
Antenna reflection coefficient is 10.1GHz-11.5GHz in the bandwidth of operation less than -10dB;Antenna gain reaches at center frequency point 10GHz
8.0dB has been arrived, while there is wider broadband, the energy loss of antenna array has been effectively reduced, improves its gain.
Although being described in detail with reference to accompanying drawing to the embodiment of utility model, should not be construed as to this
The restriction of the protection domain of patent.In the scope described by claims, those skilled in the art are without creative work
The various modification and variation that can be made still belong to the protection domain of this patent.
Claims (6)
- A kind of 1. unit line array of X-band Optically controlled microwave four, it is characterised in that:Including medium substrate, element antenna and wait work( Rate distributor;The constant power distributor is fixed on a surface of medium substrate;The constant power distributor includes the three-level of two series connection The power splitter of one-to-two;Two power splitters are connected with two element antennas respectively;The element antenna include several from What top to bottm neatly sorted guides a period of time into and positioned at the excitation a period of time for guiding a period of time end into;Described excitation a period of time and power splitter phase Even;Reflection a period of time is provided with another surface of the medium substrate.
- 2. the unit line array of X-band Optically controlled microwave four according to claim 1, it is characterised in that:It is described to guide a period of time into Patch length l1=0.45 λg, λgFor the operation wavelength of electromagnetic wave in the dielectric substrate.
- 3. the unit line array of X-band Optically controlled microwave four according to claim 1, it is characterised in that:Described excitation a period of time Patch length l2=0.5 λg, λgFor the operation wavelength of electromagnetic wave in the dielectric substrate.
- 4. the unit line array of X-band Optically controlled microwave four according to claim 1, it is characterised in that:Described reflection a period of time Size be 60mm*25.5mm.
- 5. the unit line array of X-band Optically controlled microwave four according to claim 1, it is characterised in that:The medium substrate Bottom be provided with 50 ohm of sub-miniature A connectors being connected with the constant power distributor.
- 6. the unit line array of X-band Optically controlled microwave four according to claim 1, it is characterised in that:The medium substrate Material be the medium sheet materials of Rogers RT-duroid 6100, its dielectric constant is 10.2, thickness 0.635mm, loss angle just It is cut to 0.023.
Priority Applications (1)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
CN201720813279.4U CN206893802U (en) | 2017-07-06 | 2017-07-06 | A kind of unit line array of X-band Optically controlled microwave four |
Applications Claiming Priority (1)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
CN201720813279.4U CN206893802U (en) | 2017-07-06 | 2017-07-06 | A kind of unit line array of X-band Optically controlled microwave four |
Publications (1)
Publication Number | Publication Date |
---|---|
CN206893802U true CN206893802U (en) | 2018-01-16 |
Family
ID=61297685
Family Applications (1)
Application Number | Title | Priority Date | Filing Date |
---|---|---|---|
CN201720813279.4U Expired - Fee Related CN206893802U (en) | 2017-07-06 | 2017-07-06 | A kind of unit line array of X-band Optically controlled microwave four |
Country Status (1)
Country | Link |
---|---|
CN (1) | CN206893802U (en) |
Cited By (1)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN109860995A (en) * | 2019-01-24 | 2019-06-07 | 中国电子科技集团公司第三十八研究所 | A kind of light-type phased array antenna means for correcting |
-
2017
- 2017-07-06 CN CN201720813279.4U patent/CN206893802U/en not_active Expired - Fee Related
Cited By (1)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN109860995A (en) * | 2019-01-24 | 2019-06-07 | 中国电子科技集团公司第三十八研究所 | A kind of light-type phased array antenna means for correcting |
Similar Documents
Publication | Publication Date | Title |
---|---|---|
US6061035A (en) | Frequency-scanned end-fire phased-aray antenna | |
CN110323575B (en) | Dual-polarized strong-coupling ultra-wideband phased array antenna loaded by electromagnetic metamaterial | |
Cruz et al. | Chirped fibre Bragg gratings for phased-array antennas | |
CN109755757B (en) | Broadband coding folding reflective array antenna based on sub-wavelength single-layer reflection unit | |
Dadgarpour et al. | One-and two-dimensional beam-switching antenna for millimeter-wave MIMO applications | |
CN108398842B (en) | Optical phased array chip based on serial optical antenna | |
CN106025530A (en) | S-waveband light-controlled phased array unit antenna | |
CN108336500B (en) | Single-beam double-period surface plasmon side-emitting leaky-wave antenna | |
CN109687155A (en) | A kind of complementation artificial surface phasmon leaky wave frequency scanning antenna | |
CN201383549Y (en) | Multibeam antenna with high radiation efficiency | |
CN113078475A (en) | Reconfigurable multifunctional super surface with electromagnetic wave full-space regulation and control capability | |
CN102723603B (en) | Horn-shaped antenna | |
CN110444895A (en) | Broadband reflection array antenna based on the embedded fluting annulus unit of single layer | |
CN201238075Y (en) | Mono-pulse antenna for feeding by multi-module substrate integration waveguide | |
CN206893802U (en) | A kind of unit line array of X-band Optically controlled microwave four | |
WO1999034480A1 (en) | Photonically controlled, phased array antenna | |
CN108336499B (en) | Single-beam local induced surface plasmon side-emitting leaky-wave antenna | |
CN112952395B (en) | Broadband reflection array antenna based on single-layer clip-shaped unit structure | |
CN103594791A (en) | Metamaterial plate, reflector antenna system and electromagnetic wave reflection regulating method | |
CN115939768A (en) | Gap waveguide slot antenna and angle radar | |
CN102769189B (en) | A kind of horn-lens antenna | |
CN112952396B (en) | Reflective array antenna of slotted square ring unit based on embedded loading concave arm | |
US11245200B1 (en) | Substrate integrated waveguide having space apart radiating elements formed on a substrate and a superstrate including pairs of wings and a reconfigurable metasurface for beam scanning the radiating elements | |
CN102769206B (en) | Horn lens antenna | |
Kalaagi et al. | Design of dual polarized retrodirective metasurfaces |
Legal Events
Date | Code | Title | Description |
---|---|---|---|
GR01 | Patent grant | ||
GR01 | Patent grant | ||
CF01 | Termination of patent right due to non-payment of annual fee | ||
CF01 | Termination of patent right due to non-payment of annual fee |
Granted publication date: 20180116 Termination date: 20190706 |