CN207082633U - A kind of antenna assembly of Step Frequency continuous wave through-wall radar - Google Patents

Abstract

The utility model discloses a kind of antenna assembly of Step Frequency continuous wave through-wall radar, including the transmitting antenna more than two for being used to launch radar signal and multigroup reception antenna for being used to receive radar return, transmitting antenna, reception antenna are arranged in parallel in the upper and lower layer in radar emission face respectively, every group of transmitting antenna, reception antenna include antenna radiation unit and reflection back of the body chamber respectively, antenna radiation unit is arranged in reflection back of the body intracavitary, reflection back of the body chamber is the cuboid chamber structure surrounded by 5 surfaces, and one of surface is with face the defects of partly blocking area.The utility model has that simple in construction, required cost is low, can realize more array elements, while make it that the isolation between dual-mode antenna is high, and the advantages that isolation flexible adjustment, high gain.

Description

A kind of antenna assembly of Step Frequency continuous wave through-wall radar

Technical field

It the utility model is related to Step Frequency continuous wave radar technical field, more particularly to a kind of Step Frequency continuous wave thunder through walls The antenna assembly reached.

Background technology

Through-wall radar is realized to non-transparent medium（Except metal）The canonical system that target acquisition positions in barrier, can The motion and standstill target of behind walls is detected, is positioned, tracked and is imaged；Step Frequency continuous wave radar has orientation essence Degree is high, penetrability is good, and the advantages that strong antijamming capability and strong target difference ability.Step Frequency continuous wave through-wall radar be by Step Frequency continuous wave radar is applied in through-wall radar, launches frequency electromagnetic waves by transmitting antenna, then pass through reception antenna Receive target reflection echo, so as to by LNA, high-pass filter, automatic gain amplification, mixing, intermediate frequency amplification, intermediate frequency filtering, AD samplings, signal transacting etc., finally export target information.

If antenna assembly array element negligible amounts in through-wall radar antenna assembly, number of channels can not meet that energy quickly accumulates The tired demand waited, can reduce the sensibility in practice and azimuth resolution of radar, and then can not meet actual two dimension accordingly Positioning and multiple target detection demand；Isolation between dual-mode antenna be Step Frequency continuous wave radar realize remote probe and The key of detected with high accuracy etc., thus for through-wall radar antenna assembly, it is necessary to meet the more array elements of continuous wave radar antenna assembly Demand, it is also necessary to solve the problems, such as the isolation between dual-mode antenna, while meet Radar Miniaturization demand, if dual-mode antenna Between isolation can not meet system requirements, the energy leakage of radar transmitter will directly affect the sensitivity of receiver and dynamic State scope, while shorten the distance of radar effect, reduce radar performance, in some instances it may even be possible to cause the saturation of receiver, and can not track Detect target.

Antenna assembly in existing Step Frequency continuous wave system through-wall radar, when impedance bandwidth keeps constant, antenna The caliber size of device be with the proportional distribution of array element quantity, i.e. caliber size is bigger, and corresponding array element quantity is more, the same day The timing of caliber size one of line apparatus, the isolation between the array element quantity and dual-mode antenna of antenna assembly are then distributed in inverse ratio, That is array element quantity is more, and the isolation between corresponding dual-mode antenna is lower, to cause antenna assembly to realize sufficiently small radiation Bore, enough array element quantity, while cause have sufficiently large isolation extremely difficult thus existing between dual-mode antenna again Antenna assembly in some Step Frequency continuous wave system through-wall radars, be actually difficult to meet simultaneously the more array elements of scanner unit with And between dual-mode antenna isolation demand.

Utility model content

The technical problems to be solved in the utility model is that：It is new for technical problem existing for prior art, this practicality Type offer one kind is simple in construction, required cost is low, can realize more array elements, while make it that the isolation between dual-mode antenna is high, And the antenna assembly of the Step Frequency continuous wave through-wall radar of isolation flexible adjustment, high gain.

In order to solve the above technical problems, the utility model proposes technical scheme be：

A kind of antenna assembly of Step Frequency continuous wave through-wall radar, including the transmitting more than two for being used to launch radar signal Antenna and multigroup reception antenna for being used to receive radar return, the transmitting antenna, the reception antenna are arranged in parallel respectively Upper and lower layer in radar emission face, transmitting antenna, reception antenna described in every group include antenna radiation unit and the reflection back of the body Chamber, the antenna radiation unit are arranged in the reflection back of the body intracavitary, and the reflection back of the body chamber is the rectangle body cavity surrounded by 5 surfaces Cell structure, and one of surface is with face the defects of partly blocking area.

As further improvement of the utility model：In the reflection back of the body chamber, the transmitting day corresponding to the transmitting antenna The top surface of line reflection back of the body chamber is the reception day corresponding to the reception antenna with the first defect face for partly blocking area The lower surface of line reflection back of the body chamber is with the second defect face for partly blocking area.

As further improvement of the utility model：The opening direction of the reflection back of the body chamber is identical with aerial radiation direction, The transmitting antenna corresponds to the top of the first defect face sensing radar level center line of the transmitting antenna reflection back of the body chamber, institute State the bottom that reception antenna corresponds to the second defect face sensing radar level center line of the reception antenna reflection back of the body chamber.

As further improvement of the utility model：Transmitting antenna described in each group, antenna spoke described in the reception antenna Penetrate unit and be arranged in the reflection back of the body intracavitary according to identical relative position.

As further improvement of the utility model：Cloth is bonded to each other between the transmitting antenna and the reception antenna Put；The lower surface of transmitting antenna reflection back of the body chamber is carried on the back with the reflection of reception antenna described in the reception antenna in the transmitting antenna The top surface of chamber is bonded to each other setting.

As further improvement of the utility model：The antenna radiation unit includes paster radiating element, the paster Radiating element is E type paster radiating elements, and the E types paster radiating element is the rectangle patch with two symmetrical rectangular apertures Piece.

As further improvement of the utility model：The antenna radiation unit also includes floor layer, the paster radiation Unit with the first non-conducting connection component by being fixedly connected on the floor layer.

As further improvement of the utility model：The outer conductor of input connector, institute are fixedly connected with the floor layer State the inner wire connection of the middle wing and input connector of E type paster radiating elements.

As further improvement of the utility model：The antenna radiation unit passes through with the second non-conducting connection Part fixed and arranged is in the reflection back of the body intracavitary.

As further improvement of the utility model：The transmitting antenna, the reception antenna are vertical polarized antenna.

Compared with prior art, the utility model has the advantage of：

1）The antenna assembly of the utility model Step Frequency continuous wave through-wall radar, by setting transmitting antenna more than two And multigroup reception antenna, the MIMO structures that multi-emitting receives more are formed, while each group transmitting antenna, reception antenna include antenna Radiating element and reflection back of the body chamber, antenna radiation unit are arranged in the reflection back of the body intracavitary portion of five face cuboid chamber structures, a side Face enables to the main emittance of antenna to concentrate, and improves antenna gain, reduces the mutual coupling factor between antenna, another aspect energy Enough separate most of electromagnetic wave between dual-mode antenna, and to radiate to the inverse direction of dual-mode antenna；Reflect back of the body chamber simultaneously In a surface be arranged to defect face structure so that dual-mode antenna can by division board reflect electromagnetic wave directly pass through defect face It radiate, influence caused by reflection of electromagnetic wave part between dual-mode antenna is reduced, so as to meet antenna assembly array element While demand, the isolation between dual-mode antenna is greatly improved, and realize wide working band, high gain and minor level It is low, it is easy to implement antenna assembly miniaturization；

2）The utility model Step Frequency continuous wave through-wall radar antenna assembly, by setting two groups respectively on radiating surface top Above transmitting antenna, while multigroup reception antenna is set in radiating surface bottom, azimuth plane angle information and footpath can be obtained simultaneously Actual target locations information can be calculated to range information, and then according to azimuth plane angle and radial distance information, so as to Target two-dimensional localization is realized, dual-mode antenna is based on MIMO structures, and multi-channel data synthesis can improve identification of the radar to target Ability and multi-sources distinguishing ability；

3）The utility model Step Frequency continuous wave through-wall radar antenna assembly, arrange transmitting antenna by reflecting back of the body chamber, connect Receive antenna, size, structure and the direction of adjustment defect face truncation part etc., you can easily to adjust isolation between transmitting and receiving antenna And gain, adjustment antenna are reflecting the position in carrying on the back chamber, can also easily adjust directional diagram, impedance bandwidth and the antenna of antenna Between isolation；

4）The utility model Step Frequency continuous wave through-wall radar antenna assembly, further antenna radiation unit connect by second Fitting fixed and arranged reflection carry on the back chamber so that antenna radiation unit with reflection the back of the body chamber be electrically isolated, can reduce antenna assembly due to The caused surface wave crosstalk of ground connection, isolates with making dual-mode antenna, further improves the isolation between dual-mode antenna；

5）The utility model Step Frequency continuous wave through-wall radar antenna assembly, between further transmitting antenna and reception antenna By being bonded to each other arrangement, the volume of antenna assembly can be effectively reduced, with reference to the setting of reflection back of the body chamber, small size can be realized While antenna assembly, increase the isolation between dual-mode antenna.

Brief description of the drawings

Fig. 1 is the structural representation of the antenna assembly of the present embodiment Step Frequency continuous wave through-wall radar.

Fig. 2 be the present embodiment Step Frequency continuous wave through-wall radar antenna assembly in one group of transmitting antenna structural representation Figure.

Fig. 3 be the present embodiment Step Frequency continuous wave through-wall radar antenna assembly in one group of reception antenna structural representation Figure.

Fig. 4 is the effect diagram after the transmitting antenna reflection back of the body each unfolded surface of chamber in the present embodiment.

Fig. 5 is the overlooking the structure diagram of transmitting antenna and transmitting antenna reflection back of the body chamber in the present embodiment.

Fig. 6 is the antenna pattern of the transmitting antenna obtained in the utility model specific embodiment.

Fig. 7 is the antenna pattern of the reception antenna obtained in the utility model specific embodiment.

Fig. 8 is the isolation Dependence Results schematic diagram of the dual-mode antenna obtained in the utility model specific embodiment.

Marginal data：1st, transmitting antenna；2nd, reception antenna；3rd, antenna radiation unit；31st, paster radiating element；311st, in Between the wing；32nd, floor layer；4th, reflection back of the body chamber；41st, transmitting antenna reflection back of the body chamber；411st, the first defect face；42nd, reception antenna reflects Carry on the back chamber；421st, the second defect face；5th, the first connector；6th, input connector；61st, outer conductor；62nd, inner wire；7th, the second connection Part.

Embodiment

The utility model is further described below in conjunction with Figure of description and specific preferred embodiment, but not because This and limit the scope of protection of the utility model.

As shown in Figures 1 to 3, the antenna assembly of the present embodiment Step Frequency continuous wave through-wall radar specifically includes more than two （Specially two groups）For launching the transmitting antenna 1 of radar signal and multigroup（Specially four groups）For receiving radar return Reception antenna 2, transmitting antenna 1, reception antenna 2 are arranged in parallel in the upper and lower layer in radar emission face respectively, each group transmitting antenna 1, The structure of reception antenna 2 is identical, and every group of transmitting antenna 1, reception antenna 2 include antenna radiation unit 3 and reflection back of the body chamber 4, Antenna radiation unit 3 is arranged in reflection back of the body chamber 4, and reflection back of the body chamber 4 is the cuboid chamber structure surrounded by 5 surfaces, and its In surface be with face the defects of partly blocking area；Eight are equivalent to by two groups of transmitting antennas 1 and four groups of reception antennas 2 Individual data channel, realize the overlap-add procedure of multi-group data passage.Certainly in other embodiments, transmitting antenna 1 can also basis Actual demand is arranged to more than three groups, and reception antenna 2 can also be arranged to other multigroup forms according to the actual requirements.

The present embodiment forms what multi-emitting received more by setting two groups of transmitting antenna 1 and multigroup reception antenna 2 MIMO structures, while each group transmitting antenna 1, reception antenna 2 include antenna radiation unit 3 and reflection back of the body chamber 4, aerial radiation list Member 3 is arranged in inside the reflection back of the body chamber 4 of five face cuboid chamber structures, is surrounded antenna by reflection back of the body chamber 4, is reflected back of the body chamber 4 its In surface be with face the defects of partly blocking area, can be while antenna assembly array element demand be met, greatly The isolation between dual-mode antenna is improved, and realizes that wide working band, high gain and minor level are low.

The present embodiment is made by the way that transmitting antenna 1, reception antenna 2 are arranged inside reflection back of the body chamber 4 by reflection back of the body chamber 4 Division board between dual-mode antenna, on the one hand enable to the main emittance of antenna to concentrate, improve antenna gain, reduce The mutual coupling factor between antenna, aerial radiation face is on the other hand higher than by division board between reflecting the back of the body dual-mode antenna of chamber 4, received Electromagnetic wave between hair antenna can largely be separated, and be radiated to the inverse direction of dual-mode antenna；Reflect simultaneously in back of the body chamber 4 One surface is arranged to defect face structure so that the electromagnetic wave that division board reflects can directly be passed through defect face spoke by dual-mode antenna It is shot out, influence caused by reflection of electromagnetic wave part between dual-mode antenna is reduced, so as to combine antenna-reflected between dual-mode antenna Ground isolation, one side defect reflection structure, while disclosure satisfy that antenna assembly array element demand, greatly between raising dual-mode antenna Isolation, and be easy to implement the miniaturization of antenna assembly.

The present embodiment Step Frequency continuous wave through-wall radar antenna assembly, it is more than two by being set respectively on radiating surface top Transmitting antenna 1, while multigroup reception antenna 2 is set in radiating surface bottom, azimuth plane angle information and radial direction can be obtained simultaneously Range information, and then actual target locations information can be calculated according to azimuth plane angle and radial distance information, so as to real Existing target two-dimensional localization, dual-mode antenna are based on MIMO structures, radar can be improved to target after multi-channel data overlap-add procedure Recognition capability and multi-sources distinguishing ability.

As shown in figure 1, the specific two groups of transmitting antennas 1 of the present embodiment are arranged in parallel, and split respectively in radar emission face Upper strata, multigroup 2 parallel distribution of reception antenna, and the lower floor in radar emission face is arranged in, transmitting antenna 1 and reception antenna 2 close In radar emission face, vertical plane is symmetrical.

In the present embodiment, in reflection back of the body chamber 4, the top surface of the transmitting antenna reflection back of the body chamber 41 corresponding to transmitting antenna 1 For with the first defect face 411 for partly blocking area, the bottom table of the reception antenna reflection back of the body chamber 42 corresponding to reception antenna 2 Face is with the second defect face 421 for partly blocking area.By the way that reflection corresponding to dual-mode antenna is carried on the back into relative position in chamber 4 Surface is arranged to defect face structure, and the electromagnetic wave for enabling to dual-mode antenna to be reflected by center division board in reflection cavity 3 is directly logical Cross the defects of corresponding surface radiation to go out, the isolation between dual-mode antenna can be greatly improved, while ensure whole antenna side To map migration control within the specific limits.

The opening direction of reflection back of the body chamber 4 is identical with aerial radiation direction in the present embodiment, 1 corresponding transmitting antenna of transmitting antenna Point to the top of radar level center line, the corresponding reception antenna reflection of reception antenna 2 in first defect face 411 of reflection back of the body chamber 41 Point to the bottom of radar level center line in the second defect face 421 for carrying on the back chamber 42.As shown in Figure 2,4, the present embodiment transmitting antenna Lower surface, the side surface of reflection back of the body chamber 41 are complete rectangular configuration, and top surface is defect face and part is blocked Rectangle, corresponding top surface area are less than bottom surface area；As shown in Figure 3,4, the present embodiment reception antenna reflection back of the body chamber 42 Top, side be complete rectangular configuration, lower surface is defect face and is the rectangle that part is blocked, corresponding lower surface face Product is less than top surface area.

The big I that area is blocked in defect face is set according to the actual requirements, by adjusting the big of defect face truncation part It is small, or further size, structure and direction by adjusting defect face etc., can further improve isolation between transmitting and receiving antenna and Gain.It is corresponding to increase isolation between antenna wherein when increasing the size in defect face, while the gain of antenna is reduced, And can increase 3dB beam angles and greatest irradiation direction skew will also increase；Otherwise reduce the size in defect face, then antenna Isolation will reduce, while gain increase, and beam angle will reduce and the skew of greatest irradiation direction will reduce is actual In can the actual demand of combine antenna device correspondence system the size in defect face is set.

In the present embodiment, antenna radiation unit 3 is arranged according to identical relative position in each group transmitting antenna 1, reception antenna 2 In reflection back of the body chamber 4, i.e., antenna radiation unit 3 is consistent with the relative position of reflection back of the body chamber 4.The present embodiment antenna radiation unit 3 Specific to be arranged in the reflection back of the body inner horizontal position centre of chamber 4, i.e. center, antenna radiation unit 3 is carried on the back in reflection in chamber 4 Position can also be set according to the actual requirements, by adjusting position of the antenna in chamber 4 is carried on the back in reflection, can adjust the direction of antenna Isolation between figure, impedance bandwidth and antenna.

In the present embodiment, arrangement, i.e. transmitting antenna in transmitting antenna 1 are bonded to each other between transmitting antenna 1 and reception antenna 2 The lower surface of reflection back of the body chamber 41 and the top surface of reception antenna reflection back of the body chamber 42 in reception antenna 2 are bonded to each other setting.Hair Penetrate between antenna 1 and reception antenna 2 by being bonded to each other arrangement, the volume of antenna assembly can be effectively reduced, with reference to above-mentioned anti- The setting of back of the body chamber 4 is penetrated, while small sized antenna device can be realized, ensures the isolation between dual-mode antenna.

In the present embodiment, antenna radiation unit 3 includes paster radiating element 31, paster in transmitting antenna 1, reception antenna 2 Radiating element 31 is specially E type paster radiating elements, and E type pasters radiating element is the rectangle with two symmetrical rectangular apertures Paster, the i.e. adjustable E type paster radiating elements of relative position by adjusting connector and the middle wing 311.

In the present embodiment, transmitting antenna 1, reception antenna 2 are vertical polarized antenna, i.e. transmitting antenna and reception antenna Polarised direction is consistent, is vertical polarized antenna by setting dual-mode antenna, and dual-mode antenna uses MIMO structures, multichannel number Recognition capability and multi-sources distinguishing ability of the radar to target can be improved according to synthesis.

In the present embodiment, antenna radiation unit 3 also includes floor layer 32, and paster radiating element 31 passes through the first connector 5 It is fixedly connected on floor layer 32, the first connector 5 can specifically use nylon stud or other attachment structures.Pass through regulating floor Spacing between layer 32 and paster radiating element 31, you can easily to adjust the resonant frequency of antenna and impedance bandwidth, wherein When increasing radiating element within the specific limits and the distance between reflectingly, the resonant frequency between respective antenna is inclined to low frequency Move, impedance bandwidth reduction, otherwise resonant frequency increases to high frequency offset, impedance bandwidth.

As shown in Figure 1,5, the present embodiment paster radiating element 31 is located on dielectric-slab 112, antenna radiation unit 3 specifically by 1 E type pasters radiating element, floor layer 312 and air chamber composition, E type paster radiating elements pass through with non-conducting the A connection piece 5 is fixed on floor layer 32, and the outer conductor 61 of input connector 6, the radiation of E types paster are fixedly connected with floor layer 32 The middle wing 311 of unit is connected with the inner wire 62 of input connector 6, inner wire 62 specifically penetrate floor layer 32 and air chamber with The middle wing 311 of E type paster radiating elements connects, and by the feed position of the wing 311 among changing, can adjust antenna impedance With characteristic.

In the present embodiment, antenna radiation unit 3 with the non-conducting fixed and arranged of the second connector 7 in reflection by carrying on the back Chamber 4 so that antenna radiation unit 3 is electrically isolated with reflection back of the body chamber 4, can reduce surface of the antenna assembly caused by ground connects Wave train is disturbed, and is isolated with making dual-mode antenna, further improves the isolation between dual-mode antenna.Second connector 7 can specifically use Nylon stud, nylon are the same as jack-post or other non-conducting connecting-piece structures.

It is illustrated in figure 6 the transmitting antenna obtained using the above-mentioned Step Frequency continuous wave through-wall radar antenna assembly of the present embodiment 1 antenna pattern, wherein solid line represent horizontal plane radiation pattern, and dotted line represents the antenna pattern of vertical plane.From Fig. 5 Understand, using above-mentioned Step Frequency continuous wave through-wall radar antenna assembly, antenna pattern 3dB ripple of the transmitting antenna 1 in horizontal plane For beam width up to 76.4deg, minor level is less than -13.2dB, and the antenna pattern 3dB beam angles of vertical plane are reachable 53.1deg, minor level are less than -17.1dB.

It is illustrated in figure 7 the reception antenna obtained using the above-mentioned Step Frequency continuous wave through-wall radar antenna assembly of the present embodiment 2 antenna pattern, wherein solid line represent horizontal plane radiation pattern, and dotted line represents the antenna pattern of vertical plane.Can from Fig. 6 Know, can in the antenna pattern 3dB beam angles of horizontal plane using above-mentioned Step Frequency continuous wave through-wall radar antenna assembly 76.2deg, minor level are less than -16.4dB, and the antenna pattern 3dB beam angles of vertical plane are small up to 55deg, minor level In -18dB.As shown in Figure 5,6, using the above-mentioned Step Frequency continuous wave through-wall radar antenna assembly of the present embodiment, antenna can be caused Working band is wide, high gain, while minor level is low.

Be illustrated in figure 8 obtained using the above-mentioned Step Frequency continuous wave through-wall radar antenna assembly of the present embodiment it is closest Dual-mode antenna between isolation curve, wherein transverse axis represent frequency range, the longitudinal axis represent isolation.As shown in Figure 7, use Above-mentioned Step Frequency continuous wave through-wall radar antenna assembly, the isolation scope between dual-mode antenna is up to 38-55dB so that whole Isolation is more than 38dB in frequency band range, effectively reduces the saturation of receiver caused by straight coupling between antenna, increases and wear The dynamic range of wall radar receiver, so as to improve the detectivity of radar.

Above-mentioned simply preferred embodiment of the present utility model, not makees any formal limitation to the utility model.Though Right the utility model is disclosed above with preferred embodiment, but is not limited to the utility model.Therefore, it is every without departing from The content of technical solutions of the utility model, any simply repaiied to made for any of the above embodiments according to the utility model technical spirit Change, equivalent variations and modification, all should fall in the range of technical solutions of the utility model protection.

Claims (10)

1. A kind of 1. antenna assembly of Step Frequency continuous wave through-wall radar, it is characterised in that：It is used to launch radar including more than two The transmitting antenna of signal（1）And multigroup reception antenna for being used to receive radar return（2）, the transmitting antenna（1）, described connect Receive antenna（2）It is arranged in parallel respectively in the upper and lower layer in radar emission face, transmitting antenna described in every group（1）, reception antenna（2） Including antenna radiation unit（3）And reflection back of the body chamber（4）, the antenna radiation unit（3）It is arranged in the reflection back of the body chamber（4） It is interior, the reflection back of the body chamber（4）For the cuboid chamber structure surrounded by 5 surfaces, and one of surface is to be cut with part The defects of basal area face.
2. 2. the antenna assembly of Step Frequency continuous wave through-wall radar according to claim 1, it is characterised in that：The reflection back of the body Chamber（4）In, the transmitting antenna（1）Corresponding transmitting antenna reflection back of the body chamber（41）Top surface be with part truncation surface The first long-pending defect face（411）, the reception antenna（2）Corresponding reception antenna reflection back of the body chamber（42）Lower surface for tool There is the second defect face that area is blocked in part（421）.
3. 3. the antenna assembly of Step Frequency continuous wave through-wall radar according to claim 2, it is characterised in that：The reflection back of the body Chamber（4）Opening direction it is identical with aerial radiation direction, the transmitting antenna（1）The corresponding transmitting antenna reflection back of the body chamber（41） The first defect face（411）Point to the top of radar level center line, the reception antenna（2）The corresponding reception antenna is anti- Penetrate back of the body chamber（42）The second defect face（421）Point to the bottom of radar level center line.
4. 4. the antenna assembly of Step Frequency continuous wave through-wall radar according to claim 3, it is characterised in that：Hair described in each group Penetrate antenna（1）, the reception antenna（2）Described in antenna radiation unit（3）The reflection is arranged according to identical relative position Carry on the back chamber（4）It is interior.
5. 5. the antenna assembly of the Step Frequency continuous wave through-wall radar according to any one in Claims 1 to 4, its feature exist In：The transmitting antenna（1）With the reception antenna（2）Between be bonded to each other arrangement；The transmitting antenna（1）Middle transmitting antenna Reflection back of the body chamber（41）Lower surface and the reception antenna（2）Described in reception antenna reflection the back of the body chamber（42）Top surface phase Mutually fitting is set.
6. 6. the antenna assembly of the Step Frequency continuous wave through-wall radar according to any one in Claims 1 to 4, its feature exist In：The antenna radiation unit（3）Including paster radiating element（31）, the paster radiating element（31）Radiated for E types paster Unit, the E types paster radiating element are the rectangular patch with two symmetrical rectangular apertures.
7. 7. the antenna assembly of Step Frequency continuous wave through-wall radar according to claim 6, it is characterised in that：The antenna spoke Penetrate unit（3）Also include floor layer（32）, the paster radiating element（31）By with the first non-conducting connector（5） It is fixedly connected on the floor layer（32）On.
8. 8. the antenna assembly of Step Frequency continuous wave through-wall radar according to claim 7, it is characterised in that：The floor layer （32）On be fixedly connected with input connector（6）Outer conductor（61）, the middle wing of the E types paster radiating element（311）With it is defeated Enter connector（6）Inner wire（62）Connection.
9. 9. the antenna assembly of the Step Frequency continuous wave through-wall radar according to any one in Claims 1 to 4, its feature exist In：The antenna radiation unit（3）By with the second non-conducting connector（7）Fixed and arranged is in the reflection back of the body chamber （4）It is interior.
10. 10. the antenna assembly of the Step Frequency continuous wave through-wall radar according to any one in Claims 1 to 4, its feature It is：The transmitting antenna（1）, the reception antenna（2）For vertical polarized antenna.