CN100511837C - Antenna device and wireless communication device using same - Google Patents

Abstract

An antenna apparatus (100-116) includes a minute loop antenna (A3) and at least one antenna element (A1, A2). The minute loop antenna (A3) is provided to be electromagnetically close to a dielectric substrate (10) including a grounding conductor (11), has a predetermined number N of turns and a predetermined minute length, operates as a magnetic ideal dipole when a predetermined metal plate (30) is located closely to the antenna apparatus (100-116), and operates as a current antenna when the metal plate (30) is located apart from the antenna apparatus (100-116). The antenna element (A1, A2) is connected to the minute loop antenna (A3), and operates as a current antenna. In the antenna apparatus (100-116), one end of the antenna apparatus (100-116) is connected to a feeding point (Q), and another end of the antenna apparatus (100-116) is connected to the grounding conductor (11) of the dielectric substrate (10).

Description

Antenna assembly and the radio communication device that uses it

Technical field

The present invention relates to be mainly used in radio communication device and comprise the antenna assembly of coil antenna (loop antenna) and the radio communication device of this antenna assembly of use.

Background technology

In the past, coil antenna was used in particular in the portable radio communication device such as mobile phone, and its configuration example is as being disclosed in the prior art document " electronic information communication association compiles; ' antenna engineering handbook '; pp.59～63, ohm company, the 1st edition, distribution on October 30th, 1980 ".The total length of coil antenna generally constitutes with about 1 wavelength, from its CURRENT DISTRIBUTION, can be approximated to be and established the structure of 2 half wavelength dipole antenna (diploe antenna), moves as the axial directional characteristic antenna of ring-type.

At this, be below 0.1 wavelength as if reducing coil antenna, making its total length, the CURRENT DISTRIBUTION of the ring-type of then flowing through lead almost becomes steady state value.The coil antenna of this state especially is called minute loop antenna.The noise electric field of this minute loop antenna is also stronger than miniature dipole antenna, in addition because can its effective depth of simple computation, so can be used as the antenna that magnetic field measuring is used.

This minute loop antenna as the small size antenna that twines 1 circle, for example is widely used in the portable radio communication device such as beep-pager.At this, because the input resistance of minute loop antenna is generally minimum, thus consider to make the multi-turn structure, with the multi-turn minute loop antenna of the rising of realization input resistance.Known minute loop antenna moves as magnetic-current antenna, though metallic plate or human body etc. near the time also can obtain good antenna gain characteristics.

Yet, in the minute loop antenna of prior art, though at conductors such as metallic plate or human bodies near representing good antenna gain characteristics, the problem that when conductor leaves, has antenna gain to reduce when radio device or antenna.

Summary of the invention

The objective of the invention is to: address the above problem a little,, also can obtain the antenna assembly of the antenna gain higher and use its radio communication device than the minute loop antenna of prior art even provide a kind of conductor near antenna and leave.

The antenna assembly that the 1st invention relates to wherein possesses:

Dielectric base plate with earthing conductor;

Minute loop antenna, its electromagnetic ground is adjacent to be arranged on the described dielectric base plate, with the winding times N winding of regulation and tiny length with regulation,, and when leaving, antenna assembly moves near moving as magnetic-current antenna during antenna assembly at the metallic plate of regulation as the electric current antenna at described metallic plate;

Be connected in described minute loop antenna, and as at least 1 antenna element of electric current antenna action; It is characterized in that,

One end of described antenna assembly is connected in distributing point, and the other end of described antenna assembly is connected in the earthing conductor of described dielectric base plate.

In addition, in described antenna assembly, it is characterized in that described at least 1 antenna element is preferably designed for parallel with the face essence of described dielectric base plate.

In addition, in described antenna assembly, it is characterized in that preferably possessing 2 antenna elements.

And then, in described antenna assembly, it is characterized in that preferred described 2 antenna elements are in fact respectively rectilinear forms, are designed to parallel to each other.

Described antenna assembly is characterized in that, preferably also possesses: be connected at least one side of described minute loop antenna and described antenna element, and be used for carrying out with the inductance of described minute loop antenna at least one the 1st capacitor of resonance series.

At this, it is characterized in that described the 1st capacitor preferably inserts the actual central point of described antenna element and connects.In addition, be characterised in that described the 1st capacitor a plurality of capacitor elements that preferably are connected in series form.Replace, be characterised in that, described the 1st capacitor many groups circuit that preferably has been connected in parallel mutually, this circuit a plurality of capacitor elements that have been connected in series form.

In addition, it is characterized in that described antenna assembly preferably also possesses impedance matching circuit, it is connected in described distributing point, and makes the input impedance of described antenna assembly and the characteristic impedance coupling of the feeder cable that is connected described distributing point.

And then, it is characterized in that in described antenna assembly, described minute loop antenna is preferably designed for: in fact the face of its section roller direction and described dielectric base plate intersects vertically.Perhaps, be characterised in that described minute loop antenna is preferably designed for: its section roller direction is in fact parallel with the face of described dielectric base plate.Replace, it is characterized in that, described minute loop antenna is preferably designed for: the face of the described relatively dielectric base plate of its section roller direction, and with the inclination angle inclination of regulation.

Have, it is characterized in that, in described antenna assembly, in fact the winding times N of described minute loop antenna preferably is set at N=(n-1)+0.5 (at this, n is a natural number).At this, be characterised in that in fact the winding times N of described minute loop antenna more preferably is set at N=1.5.

In addition, it is characterized in that described antenna assembly preferably also possesses:

At least one floating conductor with described minute loop antenna and the adjacent setting of described antenna element electro permanent magnetic;

The 1st switching mechanism, it does not connect by optionally switching described floating conductor is connected still with described earthing conductor, thereby the directional characteristic of described antenna assembly or plane of polarization are changed.

At this, it is characterized in that described antenna assembly preferably possesses and is designed in fact orthogonal 2 crossing floating conductors,

Described the 1st switching mechanism does not connect by optionally switching described floating conductor is connected still with described earthing conductor, thereby the directional characteristic of described antenna assembly or at least one side of plane of polarization are changed.

And then, it is characterized in that described antenna assembly preferably also possesses:

The 1st reactance component, it is connected at least one side of described minute loop antenna and described antenna element; With

The 2nd switching mechanism, it passes through optionally to switch described the 1st still not short circuit of reactance component short circuit, thereby makes the variation of resonant frequency of described antenna assembly.

At this, it is characterized in that described the 2nd switching mechanism is preferably included in the high-frequency semiconductor element that has parasitic capacitance when it disconnects,

And further possesses the 1st inductor that is used for the described parasitic capacitance of actual elimination.

In addition, be characterised in that described antenna assembly preferably also possesses:

The 2nd reactance component, it has the end at least one side who is connected described minute loop antenna and described antenna element; With

The 3rd switching mechanism, it still is earth-free by optionally switching described the 2nd reactance component ground connection, thereby makes the variation of resonant frequency of described antenna assembly.

At this, it is characterized in that preferably also possessing at least one side's who is connected to described minute loop antenna and described antenna element the 3rd reactance component.

And then, it is characterized in that in described antenna assembly, preferred described the 3rd switching mechanism is included in the high-frequency semiconductor element that has parasitic capacitance when it disconnects,

Further possesses the 2nd inductor that is used for the described parasitic capacitance of actual elimination.

Have again, it is characterized in that, preferably possess a plurality of described antenna assemblies,

And possessing the 4th switching mechanism, it optionally switches a plurality of antenna assemblies according to the wireless signal that is received by described a plurality of antenna assemblies, is connected to distributing point with the antenna assembly that will select.

At this, it is characterized in that described the 4th switching mechanism is preferably with described unselected antenna assembly ground connection.

In addition, it is characterized in that, in described antenna assembly, preferably described antenna element is formed on the described dielectric base plate that does not form earthing conductor.

At this, it is characterized in that, preferably described minute loop antenna is formed on other the dielectric base plate.

In addition, it is characterized in that in described antenna assembly, preferred described other dielectric base plates have at least one protuberance,

Described dielectric base plate has at least one hole portion chimeric with at least one protuberance of described dielectric base plate,

At least one protuberance by making described other dielectric base plates and at least one hole portion of described dielectric base plate are chimeric, thereby described other dielectric base plates are connected on the described dielectric base plate.

Replace, it is characterized in that, in described antenna assembly, preferred described dielectric base plate has at least one protuberance,

Described other dielectric base plates have at least one protuberance and at least one the chimeric with it hole portion that inserts described dielectric base plate,

At least one the hole portion that inserts described other dielectric base plates by at least one protuberance that makes described dielectric base plate is also chimeric, thereby described dielectric base plate can be connected on described other dielectric base plates.

And then, it is characterized in that described antenna assembly preferably further possesses:

The 1st bonding conductor, it is formed on the described dielectric base plate, and has connected described antenna element; With

The 2nd bonding conductor, it is formed on described other dielectric base plates, and has connected described minute loop antenna;

When having connected described dielectric base plate and described other dielectric base plates, described the 1st bonding conductor and described the 2nd bonding conductor have been electrically connected.

At this, it is characterized in that preferred described the 1st bonding conductor possesses the 1st conductor exposed division, this exposed division is the part of described the 1st bonding conductor, has the 1st area of regulation, is used to connect the welding of described the 2nd bonding conductor,

Described the 2nd bonding conductor possesses the 2nd conductor exposed division, and this exposed division is the part of described the 2nd bonding conductor, has the 2nd area of regulation, is used to connect the welding of the 1st bonding conductor.

The radio communication device that the 2nd invention relates to is characterized in that possessing:

Described antenna assembly; With

Be connected the wireless communication line on the described antenna assembly.

Description of drawings

Fig. 1 is the stereogram of the formation of the antenna assembly 101 that relates to of expression the 1st execution mode of the present invention.

Fig. 2 is the stereogram of the formation of the antenna assembly 102 that relates to of expression the 2nd execution mode of the present invention.

Fig. 3 is the stereogram of the formation of the antenna assembly 103 that relates to of expression the 3rd execution mode of the present invention.

Fig. 4 is the stereogram of expression state during near the antenna assembly 101 of Fig. 1 with metallic plate 30.

Fig. 5 is the circuit diagram of equivalent electric circuit of the antenna assembly 101 of presentation graphs 1.

Fig. 6 is the front view that expression is used for the experimental system of the experiment carried out with the state of Fig. 4.

Fig. 7 is the experimental result of Fig. 6, is the curve chart of expression with respect to the antenna gain of the directions X of 101 the distance D from metallic plate 30 to antenna assembly.

Fig. 8 is the plane graph that expression is used for the formation of the antenna assembly 192 that the 2nd comparative example of experiment of Fig. 6 relates to.

Fig. 9 is the plane graph that expression is used for the formation of the antenna assembly 102 that the 2nd execution mode of experiment of Fig. 6 relates to.

Figure 10 is the plane graph that expression is used for the formation of the antenna assembly 191 that the 1st comparative example of experiment of Fig. 6 relates to.

Figure 11 is the plane graph that expression is used for the formation of the antenna assembly 101 that the 1st execution mode of experiment of Fig. 6 relates to.

Figure 12 is the experimental result of each antenna assembly at Fig. 8 and even Figure 11 when having carried out the experiment of Fig. 6, is the curve chart of expression with respect to the antenna gain of the directions X of the distance D from metallic plate 30 to each antenna assembly.

Figure 13 is the experimental result of the antenna assembly 101 at Figure 11 when having carried out the experiment of Fig. 6, is the curve chart of expression with respect to the antenna gain of the directions X of the distance D from metallic plate 30 to each antenna assembly.

Figure 14 is the experimental result of the antenna assembly 102 at Fig. 9 when having carried out the experiment of Fig. 6, is the curve chart of expression with respect to the antenna gain of the directions X of the distance D from metallic plate 30 to each antenna assembly.

Figure 15 is the experimental result of the antenna assembly 191 at Figure 10 when having carried out the experiment of Fig. 6, is the curve chart of expression with respect to the antenna gain of the directions X of the distance D from metallic plate 30 to each antenna assembly.

Figure 16 is the experimental result of the antenna assembly 192 at Fig. 8 when having carried out the experiment of Fig. 6, is the curve chart of expression with respect to the antenna gain of the directions X of the distance D from metallic plate 30 to each antenna assembly.

Figure 17 is the experimental result of each antenna assembly at Fig. 8 and even Figure 11 when having carried out the experiment of Fig. 6, is the curve chart of expression with respect to the standing wave ratio of input voltage the distributing point of each antenna assembly of the distance D from metallic plate 30 to each antenna assembly (input VSWR).

Figure 18 is the experimental result of the antenna assembly 101 at Fig. 1 when having carried out the experiment of Fig. 6, when being expression with the winding times N of coil antenna A3 as parameter, with respect to the curve chart of the antenna gain of the directions X of distance D from metallic plate 30 to each antenna assembly.

Figure 19 is the antenna assembly 101 that is used for being illustrated in Fig. 1, twines the schematic front view of the action of times N=1.5 o'clock.

Figure 20 is the schematic front view of operate condition on apparent in the action of expression Figure 19.

Figure 21 is the antenna assembly 101 that is used for being illustrated in Fig. 1, twines the schematic front view of the action of times N=2 o'clock.

Figure 22 is in the action of expression Figure 21, the schematic front view of the operate condition on apparent.

Figure 23 is the effect of the element width of the antenna element A2 of the expression antenna assembly 101 that makes Fig. 1 when increasing, and expression is with respect to the curve chart of the antenna gain of the directions X of the distance D from metallic plate 30 to each antenna assembly.

Figure 24 is the element width of the antenna element A2 of the expression antenna assembly 101 that makes Fig. 1 when increasing, with respect to the curve chart of the antenna gain of the directions X of the distance D from metallic plate 30 to each antenna assembly.

Figure 25 is the element width of the antenna element A2 of the expression antenna assembly 101 that makes Fig. 1 when increasing, i.e. the curve chart with respect to the antenna gain of the directions X of the distance D from metallic plate 30 to each antenna assembly in the antenna assembly 101 of Fig. 1.

Figure 26 is the stereogram of the formation of the antenna assembly 104 that relates to of expression the 4th execution mode of the present invention.

Figure 27 is the stereogram of the formation of the antenna assembly 105 that relates to of expression the 5th execution mode of the present invention.

Figure 28 is the stereogram of formation of the antenna assembly 105A that relates to of variation of expression the 5th execution mode of the present invention.

Figure 29 is the stereogram of the formation of the antenna assembly 106 that relates to of expression the 6th execution mode of the present invention.

Figure 30 is the stereogram of the formation of the antenna assembly 107 that relates to of expression the 7th execution mode of the present invention.

Figure 31 is the stereogram of the formation of the antenna assembly 108 that relates to of expression the 8th execution mode of the present invention.

Figure 32 is expression: in the antenna assembly 108 of Figure 31, when capacitor C1 is connected to the middle position Q0 of antenna element A1, with respect to the curve chart of the gain antenna of 108 distance D from metallic plate 30 to antenna assembly.

Figure 33 is expression: in the antenna assembly 108 of Figure 31, when capacitor C1 is connected to the distributing point Q side end Q1 of antenna element A1, with respect to the curve chart of the gain antenna of 108 distance D from metallic plate 30 to antenna assembly.

Figure 34 is expression: in the antenna assembly 108 of Figure 31, when capacitor C1 is connected to the coil antenna A3 side end Q2 of antenna element A1, with respect to the curve chart of the gain antenna of 108 distance D from metallic plate 30 to antenna assembly.

Figure 35 is the stereogram of formation of the antenna assembly 104A that relates to of the 1st variation of expression the 4th execution mode of the present invention.

Figure 36 is the stereogram of formation of the antenna assembly 104B that relates to of the 2nd variation of expression the 4th execution mode of the present invention.

Figure 37 is the stereogram of the formation of the antenna assembly 109 that relates to of expression the 9th execution mode of the present invention.

Figure 38 is the stereogram of the formation of the antenna assembly 110 that relates to of expression the 10th execution mode of the present invention.

Figure 39 is the stereogram of the formation of the antenna assembly 111 that relates to of expression the 11st execution mode of the present invention.

Figure 40 is the stereogram of the formation of the antenna assembly 112 that relates to of expression the 12nd execution mode of the present invention.

Figure 41 is the circuit diagram of circuit of the 1st embodiment 51-1 of frequency switching circuit 51 of the antenna assembly 109,111 of expression Figure 37 and Figure 39.

Figure 42 is the circuit diagram of circuit of the 2nd embodiment 51-2 of frequency switching circuit 51 of the antenna assembly 109,111 of expression Figure 37 and Figure 39.

Figure 43 is the circuit diagram of circuit of the 3rd embodiment 51-3 of frequency switching circuit 51 of the antenna assembly 109,111 of expression Figure 37 and Figure 39.

Figure 44 is the circuit diagram of circuit of the 4th embodiment 51-4 of frequency switching circuit 51 of the antenna assembly 109,111 of expression Figure 37 and Figure 39.

Figure 45 is the circuit diagram of circuit of the 1st embodiment 52-1 of frequency switching circuit 52 of the antenna assembly 110,112 of expression Figure 38 and Figure 40.

Figure 46 is the circuit diagram of circuit of the 2nd embodiment 52-2 of frequency switching circuit 52 of the antenna assembly 110,112 of expression Figure 38 and Figure 40.

Figure 47 is the circuit diagram of circuit of the 3rd embodiment 52-3 of frequency switching circuit 52 of the antenna assembly 110,112 of expression Figure 38 and Figure 40.

Figure 48 is the circuit diagram of circuit of the 4th embodiment 52-4 of frequency switching circuit 52 of the antenna assembly 110,112 of expression Figure 38 and Figure 40.

Figure 49 is the circuit diagram of circuit of the 5th embodiment 52-5 of frequency switching circuit 52 of the antenna assembly 110,112 of expression Figure 38 and Figure 40.

Figure 50 is the circuit diagram of circuit of the 6th embodiment 52-6 of frequency switching circuit 52 of the antenna assembly 110,112 of expression Figure 38 and Figure 40.

Figure 51 is the stereogram of the formation of the antenna assembly 113 that relates to of expression the 13rd execution mode of the present invention.

Figure 52 is the stereogram of the formation of the antenna assembly 114 that relates to of expression the 14th execution mode of the present invention.

Figure 53 is the stereogram of the formation of the antenna assembly 115 that relates to of expression the 15th execution mode of the present invention.

Figure 54 is the stereogram of structure of dorsal part of the antenna assembly 115 of expression Figure 53.

Figure 55 is the stereogram of detailed content of the chimeric connecting portion of substrate of expression Figure 54.

Figure 56 is the stereogram of the formation of the antenna assembly 116 that relates to of expression the 16th execution mode of the present invention.

Embodiment

Below, with reference to accompanying drawing, preferred implementation of the present invention is elaborated.And, pay identical mark for same parts, and detailed.

(the 1st execution mode)

Fig. 1 is the stereogram of formation of the antenna assembly 101 of expression the 1st execution mode of the present invention.In Fig. 1, the antenna assembly 101 that the 1st execution mode relates to is characterised in that it constitutes possesses: 2 antenna element A1, A2 being actually linearity and configuration in fact parallel to each other; Insertion is connected between these antenna element A1, the A2, and antenna element A1, A2 are provided with in vertical direction relatively, have the rectangle minute loop antenna A3 of winding times N=1.5; And insertion is connected the capacitor C1 between antenna element A1 and the distributing point Q.

In Fig. 1, the marginal end portion of upper left side longitudinally of the dielectric base plate 10 that formation earthing conductor 11 forms on the whole back side is provided with distributing point Q, distributing point Q constitutes the capacitor C1 of series resonant circuit together via the inductance with minute loop antenna, is connected to the end of antenna element A1.The other end of antenna element A1 connects the end of antenna element A2 via minute loop antenna A3, the other end of antenna element A2 connects earthing conductor 11 back ground connection via being filled into along the via conductors 13 in the through hole of thickness direction perforation dielectric base plate 10.In addition, distributing point Q is via impedance matching electricity consumption container C 2 and via conductors 12, connect earthing conductor 11 back ground connection, simultaneously distributing point Q through be formed on the dielectric base plate 10, feeder cable 25 such as for example microstrip, be connected to form the circulator (circulator) 23 of the wireless communication line 20 on dielectric base plate 10.At this, impedance matching electricity consumption container C 2 usefulness are so that the characteristic impedance coupling of input impedance when distributing point Q observes antenna assembly 101 and feeder cable 25.In addition, via conductors 12 is same with via conductors 13, is the conductor that is filled in along in the through hole of thickness direction perforation dielectric base plate 10.And as shown in Figure 1, the direction that the face of relative dielectric base plate 10 is vertical is made as directions X; As dielectric base plate 10 vertically, will be made as the Z direction towards the direction of antenna assembly 101 from dielectric base plate 10; As described relatively directions X and the vertical direction of Z direction, the Width of dielectric base plate 10 is made as the Y direction.

And,, can adopt glass epoxy substrate, teflon (registered trade mark) substrate, phenol substrate, multilager base plate etc. as dielectric base plate 10.

In the antenna assembly 101 of Fig. 1, the antenna element A1, the A2 that form with the linearity lead have length H respectively, are parallel to each other, are configured to extend along the Z direction.In addition, minute loop antenna A3, the direction of principal axis of its ring-type is parallel with the Z direction, the ring plain that is configured to minute loop antenna A3 is vertical with respect to the face of antenna element A1, A2 or dielectric base plate 10.In addition, minute loop antenna A3 has winding times N=1.5, and has the rectangular shape of wide w and high h, thus, have regulation the total length length L (=3w+4h).At this, the total length length L is more than 0.01 λ with respect to the wavelength X of the frequency of the radio signal of using in the wireless communication line 20 described later, is set at: below 0.5 λ, below preferred 0.2 λ, more preferably below 0.1 λ, thus, constitute minute loop antenna A3.And the outside dimension of minute loop antenna A3 (length on one side of rectangle or circular diameter) is more than 0.01 λ, is set at below 0.2 λ, below preferred 0.1 λ, more preferably below 0.03 λ.

And then, in wireless communication line 20, the radio signal that is received by antenna assembly 101 is through distributing point Q and after being imported into circulator 23, be imported in the wireless receiving circuit 21, implement processing such as high frequency amplification, frequency translation and demodulation, take out data such as voice signal, picture signal or data-signal.The action of controller 24 control wireless receiving circuits 21 and wireless transmission circuit 22.Wireless transmission circuit 22 is according to the data such as voice signal, picture signal or data-signal that should send, radio carrier is modulated, the radio carrier of modulating is carried out after electric power amplifies, output to antenna assembly 101 through circulator 23 and distributing point Q, make this radio signal from antenna assembly 101 emissions.In addition, controller 24 connects the external device (ED) of regulation via not shown interface circuit, launch the radio signal that comprises from the data of external device (ED) by antenna assembly 101, will output to external device (ED) by the data that wireless signal comprised that antenna assembly 101 receives on the other hand.

In the antenna assembly 101 that constitutes as mentioned above, possess:

(a) has the dielectric base plate 10 of earthing conductor 11;

(b) minute loop antenna A3, it is as reference Fig. 4 and even Fig. 7 etc. are described in detail, in the mode that produces electromagnetic coupled with earthing conductor 11 (promptly, when will in minute loop antenna A3, flow through high-frequency signal by the coil-induced electromagnetic field of the minute loop antenna A3 earthed conductor 11 actual modes that apply that connect), with the adjacent setting of dielectric base plate 10 electro permanent magnetic, at the metallic plate 30 of Fig. 4 during, as the magnetic-current antenna of main beam and move with directional characteristic parallel with the direction of vertical metal plate 30 near antenna assembly 101; Move as the electric current antenna during at metallic plate 30 in addition away from antenna assembly 101;

(c) 2 antenna element A1, A2, it moves as have the electric current antenna (being also referred to as the transmission line antenna) of the main beam of directional characteristic on the direction longitudinally perpendicular to the lead of antenna element A1, A2; Wherein

(d) end of antenna element A1 is connected in wireless communication line 20 via distributing point Q, and the end of antenna element A2 is connected to bonding conductor 11 and ground connection, and antenna assembly 101 becomes the unbalanced type antenna thus.

Like this, by constituting antenna assembly 101, thereby compare with the minute loop antenna of prior art, in perpendicular polarization (as shown in Figure 4, the upright polarization that is made as the Z direction when perpendicular to the ground of dielectric base plate 10 is become perpendicular polarization, below same) (as shown in Figure 4, the upright polarization that is made as the Y direction when perpendicular to the ground of dielectric base plate 10 is become horizontal polarization with horizontal polarization, below same) synthetic directional characteristic in, can obtain high antenna gain.Particularly, no matter with reference to Fig. 4 and metallic plate described later 30 near the situation of antenna assembly 101, even from metallic plate 30 away from situation under, also can obtain very high antenna gain.

The antenna assembly 101 of Gou Chenging as mentioned above, wireless communication line 20 is accommodated in the framework of regulation on dielectric base plate 10, constitutes radio communication device.Constitute for this, even also be same in the following embodiments.

In the 1st above execution mode, though that use is 2 antenna element A1, A2, the present invention is not limited to this, as long as possess at least one antenna element A1 or A2.In addition, though minute loop antenna A3 is a rectangle, the present invention is not limited to this, can be other shapes such as circle, ellipse or polygon yet.At this, the ring of minute loop antenna A3 can be a helical coil shape, also can be the circumvolution loop-shaped.And then the winding times N of minute loop antenna A3 is not limited to 1.5, is described in detail as the back, also can be other winding number of times.In addition, though that use is capacitor C1, the present invention is not limited to this, can not use capacitor C1 yet and constitutes antenna assembly 101.Have again, though what use is impedance matching electricity consumption container C 2, the present invention is not limited to this, can replace it yet, use impedance matching with inductor or as the impedance matching circuit of the combinational circuit of capacitor and inductor, when not needing impedance matching circuit, also can not design.Above variation is even also can be suitable for for execution mode shown below or its variation.

Next, the determining method to the capacitance of the capacitor C1 of antenna assembly 101 describes following.

In the antenna assembly 101 of Fig. 1, for wireless transmission circuit 22 or distributing point Q, the inductance of capacitor C1 and minute loop antenna A3 is connected in series, and capacitor C1 is set at the reactance of basic this inductance of elimination.And the other end of minute loop antenna A3 is connected earthing conductor 11.At this,, reduce the electric capacity of capacitor C1, promptly increase its reactance, so at the inductance of minute loop antenna A3 and the big high frequency voltage amplitude of tie point generation of capacitor C1 owing to be set at the inductance that increases minute loop antenna A3, promptly increase its reactance.At this, big high frequency voltage amplitude in the reason that this tie point produces is: the impedance Z the during resonance of general LC resonant circuit with Z=L/ (RC)=Q ω L (at this, R=Rl+Rc, Rl are emission resistance, and Rc is a loss resistance, Q is quality factor) represent, when this LC resonant circuit is supplied with identical electric power, proportional with inductance L, the voltage amplitude amplitude variation is big, in addition by increasing inductance L and reduce capacitance C, thereby resonant resistance increases.And the relative free space of the inductance of minute loop antenna A3 is in electric field and magnetic field coupling, and free space has emission resistance relatively.Therefore, if produce big high frequency voltage amplitude at described tie point, then the emission energy quantitative change to free space is big, can obtain good antenna gain.

In certain embodiment of inventor test, move as the antenna assembly 101 of 429MHz frequency band, because the electric capacity of capacitor C1 is 1pF, so the absolute value of its impedance | the Z| increase is 371 Ω.By roughly with the absolute value of the impedance of capacitor C1 | Z| is set at more than 200 Ω, thereby can obtain high antenna gain.And, if the electric capacity of decision capacitor C1 then according to the condition of resonance frequency, can determine the size of minute loop antenna A3 substantially uniquely.

And, by must be also littler, thereby can make the absolute value of impedance than the foregoing description with the capacitor design of capacitor C1 | Z| becomes very large value, but in the antenna assembly 101 of reality, because the influences of parasitic capacitance etc. stably obtain identical resonance frequency and become difficult.Though roughly think: as the absolute value of impedance | the scope of Z| is to realize easily about 200 Ω～2000 Ω, also can be set to surpass above-mentioned scope.In addition, if further increase the absolute value of the impedance of capacitor C1 | Z|, then the reason that antenna gain improves be, can increase the inductance value of corresponding minute loop antenna A3.

Because constituting, the antenna assembly 101 that the 1st execution mode that constitutes as mentioned above relates to possesses: 2 antenna element A1, A2 and minute loop antenna A3, so structure is very simple, and can be with small-sized light-duty the manufacturing, and low cost of manufacture.

(the 2nd execution mode)

Fig. 2 is the stereogram of the formation of the antenna assembly 102 that relates to of expression the 2nd execution mode of the present invention.In Fig. 2, the antenna assembly 102 that the 2nd execution mode relates to, compare with the antenna assembly 101 that the 1st execution mode relates to, it is characterized in that, be made as the annulate shaft direction of minute loop antenna A3 parallel with directions X, that is, in fact ring plain and 2 antenna element A1, the A2 with minute loop antenna A3 are configured in the same plane.In the antenna assembly 102 of above formation, the annulate shaft direction of minute loop antenna A3 is parallel with directions X, as being described in detail, especially under the situation of having left metallic plate 30, minute loop antenna A3 can increase the antenna gain (with reference to Figure 14) of perpendicular polarization as electric current antenna effective action.

(the 3rd execution mode)

Fig. 3 is the stereogram of the formation of the related antenna assembly 103 of expression the 3rd execution mode of the present invention.In Fig. 3, the antenna assembly 103 that the 3rd execution mode relates to, compare with the antenna assembly 101 that the 1st execution mode relates to, it is characterized in that, disposed minute loop antenna A3, so that with the axle between the tie point of minute loop antenna A3 and each antenna element A1, A2 is the center, the annulate shaft direction that makes minute loop antenna A3 is from only the tilt tiltangle (0＜θ＜90 °) of regulation of Z direction.In the antenna assembly 103 that constitutes as described above, move with the combination of antenna assembly 102 as antenna assembly 101, have the motion characteristic of antenna assembly 101 and the motion characteristic of antenna assembly 102.Therefore, the directional characteristic of the defective of these antenna device 101,102 can be obtained remedying, the antenna gain of comprehensive perpendicular polarization and perpendicular polarization can be increased.

The experiment of the antenna assembly that execution mode relates to and experimental result thereof

Fig. 4 is the stereogram of the state of expression metallic plate 30 during near the antenna assembly 101 of Fig. 1.In Fig. 4, with dielectric base plate 10 upright be made as perpendicular to the ground, with the earthing conductor 11 at the back side that is formed at dielectric base plate 10 relative with metallic plate to mode disposing dielectric base plate 10.At this, the distance between earthing conductor 11 and the metallic plate 30 is made as D.Here, when antenna assembly 101 when metallic plate 30 leaves, become the similarly current mode action of unipole antenna (monopole antenna) of having carried out top loading (toploading) with coil portion by minute loop antenna A3, by by earthing conductor 11 exciting currents, thereby become the E1 of Z direction to the electric field polarization face of directions X radiation.On the other hand, metallic plate 30 is during near dielectric base plate 10, and the magnetic current M of the coil portion by minute loop antenna A3 becomes with the minute loop antenna that has encouraged magnetic current M ' on the surface of metallic plate 30 and is listed as similar magnetic current type action, and plane of polarization becomes the E2 of Y direction.That is, expression is according to the characteristic that has or not to come action of switch current type and magnetic current type to move of metallic plate 30.

Fig. 5 is the circuit diagram of equivalent electric circuit of the antenna assembly 101 of presentation graphs 1.In the equivalent electric circuit of Fig. 5, be connected impedance matching electricity consumption container C 2 as between the distributing point Q of the input of antenna assembly 101 and the earthing conductor 11, distributing point Q connects earthing conductor 11 via following circuit element.

(a) the capacitor C1 that uses of resonance series;

(b) the loss resistance R of antenna element A1 _CA1

(c) the radiation resistance R of antenna element A1 _RA1

(d) inductance L of antenna element A1 _A1

(e) the radiation resistance R of minute loop antenna A3 _Rloop

(f) the loss resistance R of minute loop antenna A3 _Cloop

(g) induced voltage e;

(h) inductance L of minute loop antenna A3 _Loop

(i) inductance L of antenna element A2 _A2

(j) the radiation resistance R of antenna element A2 _RA2

(k) the loss resistance R of antenna element A2 _CA2

At this, represent the radiation resistance R of antenna assembly 101 integral body with following formula _rWith loss resistance R _C

R _r＝R _rA1+R _rA2+R _rloop (1)

R _C＝R _CA1+R _CA2+R _Cloop (2)

If the electric current that will flow through is made as I, then represent to radiate electric power P with following formula in the antenna assembly 101 of Fig. 5 _rAnd loss electric power P _C

P _r＝(1/2)I ²R _r (3)

P _C＝(1/2)I ²R _C (4)

At this, represent to be input to the input electric power P of antenna assembly 101 with following formula _In

P _in＝P _r+P _C (5)

Therefore, the emission efficiency η that represents antenna assembly 101 with following formula.

η＝P _r/P _in＝R _r/(R _r+R _C)(6)

Therefore, can use action and the characteristic of above formula to antenna assembly 101.

Fig. 6 is expression is used for the experimental system of the experiment carried out under the state of Fig. 4 a front view.As shown in Figure 6, make and be formed on the dielectric base plate 10 and the antenna assembly 101 that is connected with external oscillator 22A is toward or away from metallic plate 30 with distance D, when the distance D that makes this moment has changed, use is positioned at the distance of 1.5m at directions X from antenna assembly 101 beginnings, and the sleeve-dipole antenna (sleeveantenna) 31 that longitudinally is parallel with the Z direction, having measured with half wavelength dipole antenna (dipole) is the antenna gain [dBd] of the directions X in benchmark when gain.At this, measuring frequency is 429MHz, and dielectric base plate 10 is of a size of 29 * 63mm, the length H=10mm of antenna element A1, A2, the height h=8mm of minute loop antenna A3, width w=29mm.Each element A1, A2 of antenna assembly 101, A3 make the copper cash bending of 0.8mm φ, and the electric capacity of capacitor C1 is 1pF.

Fig. 7 is the experimental result of Fig. 6, is the curve chart of expression with respect to the antenna gain of the directions X of 101 the distance D from metallic plate 30 to antenna assembly.As can be seen from Figure 7: when metallic plate 30 left from antenna assembly 101, perpendicular polarization composition (Z-direction) increased, and the radiation that the electric current I 1 of flowing through in the earthing conductor 11 of dielectric base plate 10 is produced becomes mastery.Then, near below the D=4cm, then the perpendicular polarization composition sharply reduces as if metallic plate 30, and opposite horizontal polarization composition (Y direction) increases.At this moment, the coil portion of minute loop antenna A3 moves as magnetic current.At this moment, as can be known: in the composite character of having synthesized perpendicular polarization composition and horizontal polarization composition, the change in gain that is produced by the distance D of distance metallic plate 30 is little.Therefore, antenna assembly 101 near under the situation of metallic plate 30, leaving the antenna gain more than the antenna gain that can obtain stipulating under the situation of metallic plate 30.

Fig. 8 is the plane graph that expression is used for the formation of the antenna assembly 192 that the 2nd comparative example of experiment of Fig. 6 relates to.As shown in Figure 8, the antenna assembly 192 that the 2nd comparative example relates to does not possess antenna element A1, A2, only is made of the minute loop antenna A3 parallel with the face of dielectric base plate 10.And dielectric base plate 10 is of a size of 19mm * 27mm, in Fig. 9 and even Figure 11 too.

Fig. 9 is the plane graph that expression is used for the formation of the antenna assembly 102 that the 2nd execution mode of experiment of Fig. 6 relates to.As shown in Figure 9, the antenna assembly 102 that the 2nd execution mode relates to is same with Fig. 2, is made of antenna element A1, A2 and the minute loop antenna A3 parallel with the face of dielectric base plate 10.

Figure 10 is the plane graph that expression is used for the formation of the antenna assembly 191 that the 1st comparative example of experiment of Fig. 6 relates to.As shown in figure 10, the antenna assembly 191 that the 1st comparative example relates to does not possess antenna element A1, A2, only is made of the minute loop antenna A3 vertical with the face of dielectric base plate 10.

Figure 11 is the plane graph that expression is used for the formation of the antenna assembly 101 that the 1st execution mode of experiment of Fig. 6 relates to.As shown in figure 11, the antenna assembly 101 that the 1st execution mode relates to is same with Fig. 1, is made of antenna element A1, A2 and the minute loop antenna A3 vertical with the face of dielectric base plate 10.

And in Fig. 8 and even Figure 11, the size of the antenna assembly 101,102,191,192 that is used to test as shown in the figure.

Figure 12 is the experimental result of each antenna assembly at Fig. 8 and even Figure 11 when having carried out the experiment of Fig. 6, is the curve chart of the antenna gain of the relative directions X of the distance D of expression till from metallic plate 30 to each antenna assembly.As can be seen from Figure 12: possessed the antenna assembly 101,102 of antenna element A1, A2, compared, when metallic plate 30 separates, can obtain bigger antenna gain with the antenna assembly 191,192 that does not possess antenna element A1, A2.In addition, the antenna assembly 101,191 that on the face of dielectric base plate 10, has possessed vertical minute loop antenna A3, compare with the antenna assembly 102,192 of the minute loop antenna A3 that on the face of dielectric base plate 10, has possessed level, near metallic plate 30 time, can obtain bigger antenna gain.Therefore,, on the face of dielectric base plate 10, possess vertical minute loop antenna A3 by when possessing antenna element A1, A2, thus leave from metallic plate 30 and two kinds of situations near metallic plate 30 under, can obtain bigger antenna gain.

Figure 13 is the experimental result of the antenna assembly 101 at Figure 11 when having carried out the experiment of Fig. 6, is expression with respect to the curve chart of the antenna gain of the directions X of the distance D till from metallic plate 30 to each antenna assembly.Figure 14 is the experimental result of the antenna assembly 102 at Fig. 9 when having carried out the experiment of Fig. 6, is expression with respect to the curve chart of the antenna gain of the directions X of the distance D till from metallic plate 30 to each antenna assembly.Figure 15 is the experimental result of the antenna assembly 191 at Figure 10 when having carried out the experiment of Fig. 6, is expression with respect to the curve chart of the antenna gain of the directions X of the distance D till from metallic plate 30 to each antenna assembly.Figure 16 is the experimental result of the antenna assembly 192 at Fig. 8 when having carried out the experiment of Fig. 6, is expression with respect to the curve chart of the antenna gain of the directions X of the distance D till from metallic plate 30 to each antenna assembly.

These Figure 13 and even Figure 16 are to be illustrated in each antenna assembly 101,102,191,192 curve chart of the variation of the polarization composition of antenna gain.From Figure 13 and even Figure 16 as can be known: the antenna assembly 101,102 that has possessed antenna element A1, A2, compare with the antenna assembly 191,192 that does not possess antenna element A1, A2, when metallic plate 30 leaves, increase by making the perpendicular polarization composition, thereby can obtain bigger antenna gain.In addition, the antenna assembly 101,191 that on the face of dielectric base plate 10, has possessed vertical minute loop antenna A3, compare with the antenna assembly 102,192 of the minute loop antenna A3 that on the face of dielectric base plate 10, has possessed level, near metallic plate 30 time, by the horizontal polarization composition is increased, thereby can obtain bigger antenna gain.

Then, the coil axes direction to minute loop antenna A3 below describes.As shown in Figure 1, the coil axes direction of minute loop antenna A3 is preferably set to parallel with the longitudinally of dielectric base plate 10.Thus, as shown in Figure 2, also can with the coil axes direction setting of minute loop antenna A3 be and dielectric base plate 10 quadratures, under this situation, owing to can utilize antenna element A1, A2 make minute loop antenna A3 from earthing conductor 11 away from, so can obtain bigger antenna gain.And, not having under the approaching situation at metallic plate 30, the antenna assembly 102 of Fig. 2 can obtain big gain than the antenna assembly 101 of Fig. 1 certainly.In addition, in the antenna assembly 102 of Fig. 2, relatively dielectric base plate 10 is vertical, when metallic plate 30 is positioned at the both ends of minute loop antenna A3, and can be to the direction radiation electric wave opposite with metallic plate 30.Therefore, even we can say that near the place ahead of radio communication device and when having metallic plate 30, it also is little that gain reduces.

Figure 17 is the experimental result of each antenna assembly at Fig. 8 and even Figure 11 when having carried out the experiment of Fig. 6, is the curve chart of expression with respect to the standing wave ratio of input voltage the distributing point of each antenna assembly of the distance D from metallic plate 30 to each antenna assembly (hereinafter referred to as input VSWR).As can be seen from Figure 17: on the face of dielectric base plate 10, possessed in the antenna assembly 101,191 of vertical minute loop antenna A3, the deterioration of input VSWR during near metallic plate 30 diminishes, and then in the antenna assembly 101 that has possessed antenna element A1, A2, its deterioration further diminishes.

Figure 18 is the experimental result of the antenna assembly 101 at Fig. 1 when having carried out the experiment of Fig. 6, when being expression with the winding times N of coil antenna A3 as parameter, with respect to the curve chart of the antenna gain of the directions X of distance D from metallic plate 30 to each antenna assembly.As can be seen from Figure 18: near the antenna gain during metallic plate 30 twining times N=1.5 o'clock maximum.At this reason, below with reference to Figure 19 and even Figure 22 of action of expression antenna assembly 101, investigate.

Figure 19 is the antenna assembly 101 that is used for being illustrated in Fig. 1, twine the schematic front view of the action of times N=1.5 o'clock.Figure 20 is in the action of expression Figure 19, the schematic front view of the operate condition on apparent.Figure 21 is the antenna assembly 101 that is used for being illustrated in Fig. 1, twine the schematic front view of the action of times N=2 o'clock.Figure 22 is in the action of expression Figure 21, the schematic front view of the operate condition on apparent.

In Figure 19, the horizontal direction high-frequency current I11, I12, the I13 that flow through in 1.5 turn coil of minute loop antenna A3 are shown.At this,, size basic identical cancel out each other opposite with electric current I 13 directions owing to electric current I 12, so minute loop antenna A3 is on apparent, the magnetic-current antenna of the big loop of forming as the electric current I 11 ' that possesses on apparent that mirror image A3 ' by electric current I shown in Figure 20 11 and magnetic current caused moves.On the other hand, be made as at the coil with minute loop antenna A3 under the situations of 2 circles, as shown in figure 21, because electric current I 11 cancels out each other with electric current I 14 with electric current I 13, electric current I 12, so as shown in figure 22, the electric current I 11 on apparent diminishes, and antenna gain reduces significantly.Like this, twine times N by coil and be made as roughly 1.5 circles, thereby can take into account higher antenna gain and miniaturization minute loop antenna A3.

And, in execution mode,, not that 1.5 circles are also passable accurately though the coil winding times N of minute loop antenna A3 is made as roughly 1.5 circles.Particularly, so long as the scope of 1.2 circles～1.8 circles just can obtain bigger antenna gain.In addition, even the coil winding times N of minute loop antenna A3 is made as roughly 0.5 circle or roughly 2.5 circles, also can obtain good characteristic.Especially, roughly 2.5 the circle in, with roughly 1.5 the circle compare, can further seek the miniaturization of antenna.And,, by being made as roughly N=(n-1)+0.5 (, n is a natural number) here, thereby can obtain big antenna gain for the winding times N of minute loop antenna A3.Specifically be also to be set at roughly 0.5 circle, roughly 1.5 circles, roughly 2.5 circles, roughly 3.5 circles, 4.5 circles etc. roughly.

Figure 23 be the element width of the antenna element A2 of the expression antenna assembly 101 that makes Fig. 1 when increasing (antenna assembly this state under is made as 101G, and 101G represents in Figure 23) effect, represent curve chart with respect to the antenna gain of the directions X of distance D from metallic plate 30 to each antenna assembly.Figure 24 is the element width of the antenna element A2 of the expression antenna assembly 101 that makes Fig. 1 when increasing, with respect to the curve chart of the antenna gain of the directions X of the distance D from metallic plate 30 to each antenna assembly.Figure 25 is the element width of the antenna element A2 of the expression antenna assembly 101 that makes Fig. 1 when increasing, i.e. the curve chart with respect to the antenna gain of the directions X of the distance D from metallic plate 30 to each antenna assembly in the antenna assembly 101 of Fig. 1.

At this, the experiment of Figure 23 and even Figure 25 is in the antenna assembly 107 of Figure 30 described later, the width of the band conductor of antenna element A2 is increased to carry out behind width only about half of of dielectric base plate 10.Among the antenna assembly 101G under this state, make the antenna element A2 on right side be almost the state of earthing conductor, think with the situation of removing antenna element A2 be equivalent.That is, as can be seen from Figure 23: have the antenna gain of the antenna assembly 101 of antenna element A2, compare very high with the antenna gain of the antenna assembly 101G of the comparative example that does not have antenna element A2.

As described above, the antenna assembly 101 according to the 1st execution mode relates to if reduce apart from the distance D of metallic plate 30, then by switching to the action of magnetic current type from the current mode action, gains thereby can obtain good radiation all the time.People of the present invention will adopt the wireless module of the radio communication device of this antenna assembly 101 to be built in each equipment of white metal household appliances, the result who has carried out evaluating characteristics is, as the maximum antenna gain in the directional characteristic measurement, in refrigerator, can obtain-10dBd, in air regulator, can obtain-the good antenna gain of 11dBd.

And then, below describe at the coil size of minute loop antenna A3 and the relation of twining the length of times N and antenna element A1, A2.By these relation of suitable adjustment, can change according to having or not of metallic plate 30 hardly thereby become input VSWR, obtain the balance of these relations.According to the inventor's experiment, can think this be because: though approaching by metallic plate 30, the inductance of antenna element A1, A2 reduces, the cause that the inductance of the coil of minute loop antenna A3 increases.As its basis, measured: under the situation of the winding times N at minute loop antenna A3 few (N=0.5 or 1), change to a high side with respect to approaching, resonance frequency, under the situation of twining times N many (1.5 times or 2 times), change to a low side by metallic plate 30.

(the 4th execution mode)

Figure 26 is the stereogram of the formation of the antenna assembly 104 that relates to of expression the 4th execution mode of the present invention.In Figure 26, the antenna assembly 104 that the 4th execution mode relates to is compared following aspect difference with the antenna assembly 101 that the 1st execution mode of Fig. 1 relates to.

(1) constitutes antenna element A1, A2 by the band conductor that uses printed circuit method on dielectric base plate 10, to form Copper Foil respectively.And, do not form earthing conductor 11 at the back side of the end, inside edge of the dielectric base plate 10 that is formed with antenna element A1, A2.

(2) will be vertical and have a dielectric base plate 14 of the width actual identical with dielectric base plate 10 with dielectric base plate 10, for example on the end, inside edge of the upright longitudinally that is located at dielectric base plate 10 such as the stickup by bonding agent.

(3) constitute minute loop antenna A3 by the band conductor that adopts printed circuit method on above-mentioned dielectric base plate 14, to form Copper Foil.And, near the ground connection side of minute loop antenna A3 end, form via conductors 15 by in the through hole that connects dielectric base plate 14 along thickness direction, filling conductor, near the ground connection side of minute loop antenna A3 end is via via conductors 15, and connects antenna element A2 via the band conductor 15s that is formed at dielectric base plate 14 back sides.

(4) capacitor C1 is near distributing point Q, but is connected as shown in figure 26 on the substantial middle point of antenna element A1.And, be described in detail action effect in the back with reference to Figure 32 and even Figure 34.

At this,, for example can adopt substrate arbitrarily such as glass epoxy substrate, teflon (registered trade mark) substrate, ceramic substrate, paper phenol substrate, multilager base plate as dielectric base plate 14.

In the present embodiment, because adopt the band conductor to form antenna element A1, A2 and minute loop antenna A3, so can adopt printed circuit method to make with high dimensional accuracy.In the band conductor of the Copper Foil on general glass epoxy substrate, the deviation of the band conductor width during as volume production, can obtain ± 30 μ m are with interior degree.Therefore, can dwindle the deviation of the impedance of the antenna assembly that has adopted the band conductor.In addition, capacitor C1 for example can be made of chip capacitor, and this also has the high accuracy product to sell.For example, be that capacitance error is ± 0.1pF in the high accuracy product of several pF at electric capacity.

Therefore, these band conductors by adopting antenna assembly 104 and capacitor (capacitor) C1 of chip capacitor (chipcondenser), thereby the deviation of resonance frequency that can suppressing antenna device 104.In addition, owing to assembled antenna structure on the dielectric base plate 10 of the tellite that wireless communication line 20 is installed in conduct,, can improve dimensional accuracy so almost do not assemble the place.And, because the deviation of the resonance frequency of antenna assembly 104 is little, so can omit the adjustment stroke of the resonance frequency when making.In addition, as antenna assembly 104, owing to do not need dielectric base plate 10,14 works in addition, so can seek miniaturization, the cost degradation of device.

And then width is than the band conductor of the Copper Foil of (being about 0.5～2mm with conductor width for example) of broad, and alternating-current resistance is little, as the Q value of the coil of minute loop antenna A3, can obtain 100 front and back or more than it.In addition, in the chip capacitor of capacitor C1,, be capacitor more than 100 so can easily obtain the Q value because electric capacity is about 0.5～10pF.Therefore, can realize that loss is little, the antenna assembly of high-gain 104.In addition, in this antenna assembly 104, owing on dielectric base plate 14, formed the band conductor of minute loop antenna A3, so exist in the advantage that the degree of freedom is arranged on the insertion position of the capacitor C1 that is installed on this substrate as tellite.

In the above embodiment, though be formed with the band conductor of minute loop antenna A3 on dielectric base plate 14, the present invention is not limited to this, for example as shown in Figure 1, can adopt the conductor of the coiled type of minute loop antenna A3 yet.

(the 5th execution mode)

Figure 27 is the stereogram of the formation of the antenna assembly 105 that relates to of expression the 5th execution mode of the present invention.In Figure 27, the antenna assembly 105 that the 5th execution mode relates to is compared following aspect difference with the antenna assembly 104 that the 4th execution mode of Figure 26 relates to.

(1),, and forms floating conductor 11A in mode with earthing conductor 11 electric insulations with the earthing conductor 11 predetermined distance d of the longitudinally of dielectric base plates 10 at interval at the back side of the end, inside edge of the dielectric base plate 10 that is formed with antenna element A1, A2.At this, floating conductor 11A with the adjacent formation of mode of antenna element A1, A2 and minute loop antenna A3 electromagnetic coupled.

(2) between earthing conductor 11 and floating conductor 11A, for example be connected switch SW 1 as the mechanical contacts switch.

In the antenna assembly 105 that constitutes as described above, be switched on or switched off by switch SW 1 is switched to, thereby the ground state via dielectric base plate 10 of antenna element A1, A2 is changed.That is when switch SW 1 disconnects, be the state of floating from the earthing potential electricity,, so the influence that the potential change of the band conductor of the band conductor of the minute loop antenna A3 of formation antenna assembly 105 and antenna element A1, A2 is caused is little owing to floating conductor 11A is earth-free.At this moment, become with Fig. 7 in the antenna gain characteristics of the characteristic close represented as the perpendicular polarization composition.On the other hand, when switch SW 1 is connected, because floating conductor 11A is connected with earthing conductor 11 via switch SW 1 and ground connection, thus become and be equivalent to metallic plate among Fig. 7 30 approaching the close antenna gain characteristics of horizontal polarization composition the during rear side of dielectric base plate 10.That is, the connection by switch SW 1 disconnects, the directional characteristic of radiation direction that can switch antenna device 105 and the direction of plane of polarization.Particularly plane of polarization almost changes with 90 degree, thus, can obtain diversity effect (diversity effect), can improve the communication performance of wireless communication line 20 significantly.

In the antenna assembly 105 that the 5th above execution mode relates to, floating conductor 11A is the part among adjacent antenna element A1, the A2 and forming only also.In addition, also floating conductor 11A can be formed on the inner layer surface of the dielectric base plate 10 that forms by multilager base plate.In addition, can be without the band conductor on the dielectric base plate 10,14, and form antenna element A1, A2 and the minute loop antenna A3 that constitutes antenna assembly 105 with lead.

Figure 28 is the stereogram of formation of the antenna assembly 105A that relates to of variation of expression the 5th execution mode of the present invention.In Figure 28, the antenna assembly 105A that the variation of the 5th execution mode relates to compares following aspect difference with the antenna assembly 105 that the 5th execution mode relates to.

(1) constitutes switch SW 1 with high-frequency semiconductor diode D1.

(2) two ends of high-frequency semiconductor diode D1 stop the connection on-off controller 40 with inductor 41,42 via high frequency respectively.

At this, 2 reverse bias voltages that on-off controller 40 will be used for high-frequency semiconductor diode D1 is switched to respectively the regulation of connecting and disconnecting are applied to high-frequency semiconductor diode D1, the directional characteristic of radiation direction that thus, can switch antenna device 105 and the direction of plane of polarization.According to present embodiment, can constitute antenna assembly 105A with very simple structure, be small-sized light weight, and can make low cost of manufacture.

(the 6th execution mode)

Figure 29 is the stereogram of the formation of the antenna assembly 106 that relates to of expression the 6th execution mode of the present invention.In Figure 29, the antenna assembly 106 that the 6th execution mode relates to is compared following aspect difference with the antenna assembly 105 that the 5th execution mode of Figure 27 relates to.

(1) will be near the antenna element A1 of left lateral sides of dielectric base plate 10 inboard, form floating conductor 30A and the dielectric base plate 14b that constitutes, paste the left lateral sides of paying and being arranged on dielectric base plate 10 in mode with dielectric base plate 10,14 quadratures.At this, floating conductor 30A with the adjacent formation of mode of antenna element A1, A2 and minute loop antenna A3 electromagnetic coupled.

(2) floating conductor 30A for example via the mechanical contacts switch or with the switch SW 2 that the high-frequency semiconductor diode constitutes, is connected in earthing conductor 11 grade and ground connection.

According to present embodiment, two floating conductor 11A, 30A are set, by so that the mode of at least one ground connection among each floating conductor 11A, 30A is connected cut-off switch SW1, SW2 respectively, thereby can switch the directional characteristic or the plane of polarization of the electric wave of the radio signal of being received and dispatched.For example, by connecting switch SW 1, thereby as the metallic plate 30 of Fig. 7 near the time shown in, the horizontal polarization of Y direction becomes to be divided into mastery, the horizontal polarization composition when metallic plate 30 leaves (Y direction) becomes mastery to the radiation of directions X.In addition, by connection switch SW 2, thereby the floating conductor 30A that becomes earthing conductor becomes reflecting plate, and horizontal polarization composition (directions X) increases to the radiation of Y direction.Therefore, when metallic plate 30 leaves, owing to two floating conductor 11A, 30A mutually orthogonal, so the main beam direction is changed about 90 degree.

In the above embodiment, though have the 1st group of circuit of floating conductor 11A and switch SW 1 and the 2nd group of circuit of floating conductor 30A and switch SW 2 simultaneously, the present invention is not limited to this, can possess at least one group circuit yet.

(the 7th execution mode)

Figure 30 is the stereogram of the formation of the antenna assembly 107 that relates to of expression the 7th execution mode of the present invention.In Figure 30, the antenna assembly 107 that the 7th execution mode relates to is compared following aspect difference with the antenna assembly 102 that the 2nd execution mode of Fig. 2 relates to.

(1) by adopting printed circuit method, on dielectric base plate 10, forms the band conductor of Copper Foil respectively, thereby constitute antenna element A1, A2 and minute loop antenna A3.And, on the back side of the end, inside edge of the dielectric base plate 10 that is formed with these antenna element A1, A2 and minute loop antenna A3, do not form earthing conductor 11.

(2) near the end the ground connection side of minute loop antenna A3, form via conductors 16 by fill conductor in the through hole that connects dielectric base plate 10 along thickness direction, near the end the ground connection side of minute loop antenna A3 connects shape and is being formed on the band conductor 16s at dielectric base plate 10 back sides via via conductors 16.Near as via conductors 16 and established from via conductors 16 folders on the position of band conductor of minute loop antenna A3, form via conductors 17 by in the through hole that connects dielectric base plate 10 along thickness direction, filling conductor, band conductor 16s is via this via conductors 17, is connected on the end of band conductor of antenna element A2.

(3) capacitor C1 is connected on the actual central point Q0 of antenna element A1,, carries out detailed narration in the back with reference to Figure 32 and even Figure 34 about its action effect.

In the present embodiment, owing to adopt the band conductor to form antenna element A1, A2 and minute loop antenna A3, so can adopt printed circuit method to make with high dimensional accuracy, though have the same effect of antenna assembly that the 4th execution mode with Figure 26 relates to 104, the antenna assembly 102 that relates to as the 2nd execution mode of the elemental motion of antenna assembly and Fig. 2 is same.

(the 8th execution mode)

Figure 31 is the stereogram of the formation of the antenna assembly 108 that relates to of expression the 8th execution mode of the present invention.In Figure 31, the antenna assembly 108 that the 8th execution mode relates to is compared with the antenna assembly 101 that the 1st execution mode of Fig. 1 relates to, and it is characterized in that, capacitor C1 is connected on the actual central point Q0 of antenna element A1.In following content, describe at the best insertion position of capacitor C1 on antenna element A1.

Figure 32 is expression: in the antenna assembly 108 of Figure 31, when capacitor C1 is connected to the middle position Q0 of antenna element A1, with respect to the curve chart of the antenna gain of the directions X of 108 distance D from metallic plate 30 to antenna assembly.Figure 33 is expression: in the antenna assembly 108 of Figure 31, when capacitor C1 is connected to the distributing point Q side end Q1 of antenna element A1, with respect to the curve chart of the antenna gain of the directions X of 108 distance D from metallic plate 30 to antenna assembly.Figure 34 is expression: in the antenna assembly 108 of Figure 31, when capacitor C1 is connected to the coil antenna A3 side end Q2 of antenna element A1, with respect to the curve chart of the antenna gain of the directions X of 108 distance D from metallic plate 30 to antenna assembly.

As can be seen from Figure 32: because when capacitor C1 is connected to the central point Q0 of antenna element A1, when metallic plate 30 leaves, antenna assembly 108 has the radioactive nature that is similar to unipole antenna, if metallic plate 30 is approaching, the radioactive nature that then has the coil antenna that is similar to general magnetic-current antenna is not so can obtain good antenna gain characteristics according to the distance of metallic plate 30 yet.In addition, as shown in figure 33, when being connected to capacitor C1 near the distributing point Q because the horizontal polarization composition is smaller, so particularly metallic plate 30 near the time generation antenna gain reduction.And then as shown in figure 34, when capacitor C1 was connected to an end of minute loop antenna A3 side, the perpendicular polarization composition was smaller, the reduction that produces antenna gain when metallic plate 30 leaves.Therefore, be connected near the actual central point Q0 of antenna element A1, thereby also can not remain good antenna gain according to the position of metallic plate 30 by capacitor C1 is inserted.

In the above embodiment, though capacitor C1 is inserted central point Q0, its both ends Q1, the Q2 that is connected to antenna element A1, the present invention is not limited to this, can be inserted into any centre position of antenna element A1.In addition, capacitor C1 can be inserted the optional position that is connected to antenna element A2 or minute loop antenna A3.And then, capacitor C1 is disperseed with a plurality of capacitors, a plurality of capacitors after disperseing are disperseed to insert at least one any a plurality of positions that are connected among antenna element A1, A2 and the minute loop antenna A3, also be fine.

(variation of the 4th execution mode)

Figure 35 is the stereogram of formation of the antenna assembly 104A that relates to of the 1st variation of expression the 4th execution mode of the present invention.In Figure 35, the antenna assembly 104A that the 1st variation of the 4th execution mode relates to compares with the antenna assembly 104 that the 4th execution mode of Figure 26 relates to, and it is characterized in that, replace the capacitor C1 of Figure 26, two capacitor C1-1, C1-2 that are connected in series are connected on the antenna element A1.Thus, as follows, can reduce the manufacture deviation of the resonance frequency of antenna assembly 104A.

In the antenna assembly 104A that present embodiment relates to, for example adopt capacitor C1-1, the C1-2 of the smaller capacitive of 1pF.At electric capacity is in the high-precision ceramic stacked die capacitor of sale of 0.5pF～10pF, and capacitance error is with the absolute value regulation, rather than ratio.Capacitance deviation is equivalent to ± and 10%.At this, if electric capacity departs from 10%, then the resonance frequency of antenna assembly 104A depart from ± 4.9%.In the antenna assembly 104A that present embodiment relates to, can obtain VSWR＜2.Because percentage bandwidth is about 10%, almost do not have so make surplus.Therefore, in the present embodiment, capacitor C1-1, the C1-2 of two 2pF that for example are connected in series can obtain combined capacity 1pF.Because the capacitance error of capacitor C1-1, the C1-2 of 2pF is ± 0.1pF, so the error of combined capacity is ± 5%, resonance frequency is suppressed to ± 2.5% deviation.Thus, even do not carry out the adjustment of resonance frequency during fabrication, also can improve the rate of finished products of product.

In the above embodiment, be connected in series with 2 capacitor C1-1, C1-2, but the present invention is not limited to this, a plurality of capacitors also can be connected in series.

Figure 36 is the stereogram of formation of the antenna assembly 104B that relates to of the 2nd variation of expression the 4th execution mode of the present invention.In Figure 36, the antenna assembly 104B that the 1st variation of the 4th execution mode relates to, compare with the antenna assembly 104 that the 4th execution mode of Figure 26 relates to, it is characterized in that, the capacitor C1 that replaces Figure 26, two capacitor C1-1, C1-2 being connected in series and two capacitor C1-3, the C1-4 that are connected in series are connected in parallel, and should the parallel connection element circuitry be connected on the antenna element A1.Thus, as follows, can reduce the manufacture deviation of the resonance frequency of antenna assembly 104B, can reduce the loss of the high-frequency signal that capacitor causes.

Under the situation of two capacitors that has been connected in series, owing to become the form that the alternating-current resistance composition of capacitor part is connected in series, so the situation of lossy increase, antenna gain reduction.Therefore, in the present embodiment, for example adopt capacitor C1-1 and even the C1-4 of 4 1pF, be connected in parallel 2 groups formation of per two structures that are connected in series.At this, the alternating-current resistance composition of supposing each capacitor C1-1 and even C1-4 is 1 Ω, and the combined resistance when then being connected in series 2 capacitors is 2 Ω, but as mentioned above, the combined resistance when having connected 4 capacitors is 1 Ω.Therefore, become half loss when being connected in series 2 capacitors.

Then, consider capacitance error.For example if connect 2 capacitors that electric capacity is 2pF ± 0.1pF, then capacitance deviation is ± 5%.On the other hand, if connect 4 capacitors that electric capacity is 1pF ± 0.1pF in above-mentioned formation, then capacitance deviation be ± 10%, also looks deterioration when thinking than 2 series connection at a glance.Yet, because in fact to be similar to the median be the distribution of the regular distribution at center to the deviation profile representation class of each capacitor C1-1 and even C1-4, it doesn't matter mutually, so deviation amplitude roughly is accommodated in during with 4 formation capacitors ± 5% in, become deviation amplitude much at one with 2 formation capacitors the time.That is, in 4 formations of capacitor, on one side capacitance deviation is suppressed the loss composition to be suppressed at half on one side for equal substantially with 2 formations.

In the above embodiment, though the structure after per two capacitors in series connection is connected in parallel to two groups, the present invention is not limited to this, the structure of a plurality of capacitors that have been connected in series can be connected in parallel at many groups yet.

(the 9th execution mode)

Figure 37 is the stereogram of the formation of the antenna assembly 109 that relates to of expression the 9th execution mode of the present invention.In Figure 37, the antenna assembly 109 that the 9th execution mode relates to, compare with the antenna assembly 107 that the 7th execution mode of Figure 30 relates to, it is characterized in that, on an end of the ground connection side of antenna element A2, connected frequency switching circuit 51, about the detailed content of this frequency switching circuit 51, be described in detail in the back with reference to Figure 41 and even Figure 44.

(the 10th execution mode)

Figure 38 is the stereogram of the formation of the antenna assembly 110 that relates to of expression the 10th execution mode of the present invention.In Figure 38, the antenna assembly 110 that the 10th execution mode relates to, compare with the antenna assembly 107 that the 7th execution mode of Figure 30 relates to, it is characterized in that, on the actual central point A2m of end of the ground connection side of antenna element A2 and antenna element A2, connected frequency switching circuit 52, about the detailed content of this frequency switching circuit 52, be described in detail in the back with reference to Figure 45 and even Figure 50.

(the 11st execution mode)

Figure 39 is the stereogram of the formation of the antenna assembly 111 that relates to of expression the 11st execution mode of the present invention.In Figure 39, the antenna assembly 111 that the 11st execution mode relates to, compare with the antenna assembly 104 that the 4th execution mode of Figure 26 relates to, it is characterized in that, on an end of the ground connection side of antenna element A2, connected frequency switching circuit 51, about the detailed content of this frequency switching circuit 51, be described in detail in the back with reference to Figure 41 and even Figure 44.

(the 12nd execution mode)

Figure 40 is the stereogram of the formation of the antenna assembly 112 that relates to of expression the 12nd execution mode of the present invention.In Figure 40, the antenna assembly 112 that the 12nd execution mode relates to, compare with the antenna assembly 104 that the 4th execution mode of Figure 26 relates to, it is characterized in that, on the actual central point A2m of end of the ground connection side of antenna element A2 and antenna element A2, connected frequency switching circuit 52, about the detailed content of this frequency switching circuit 52, be described in detail in the back with reference to Figure 45 and even Figure 50.

The embodiment of frequency switching circuit

Figure 41 is the circuit diagram of circuit of the 1st embodiment 51-1 of frequency switching circuit 51 of the antenna assembly 109,111 of expression Figure 37 and Figure 39.In Figure 41, an end of the ground connection side of antenna element A2 is via capacitor C3 ground connection, simultaneously via switch SW 3 ground connection.At this, the electric capacity that connects the capacitor C1 of antenna element A1 for example is made as about 10pF, when the electric capacity of capacitor C3 for example was made as about 1pF, the combined capacity of capacitor C1, C3 during cut-off switch SW3 was littler than the electric capacity of capacitor C3.Therefore, when connecting switch SW 3, can make the resonance frequency of antenna assembly reduce for example about 5%.That is, by switch SW3 is connected disconnection, thus resonance frequency that can the selectivity switch antenna device.

Figure 42 is the circuit diagram of circuit of the 2nd embodiment 51-2 of frequency switching circuit 51 of the antenna assembly 109,111 of expression Figure 37 and Figure 39.In Figure 42, replace the capacitor C3 of Figure 41 and adopt inductor L1, under any situation of Figure 41 and Figure 42, can insert reactance component.In the present embodiment, come shorts inductor L1 by connecting switch SW 3, thereby the inductance value of antenna assembly diminishes, and can improve resonance frequency.For example, be set at 10% o'clock of inductance value of minute loop antenna A3 in inductance value,, resonance frequency only roughly can be changed 5% by the switching of switch SW 3 with inductor L1.

Figure 43 is the circuit diagram of circuit of the 3rd embodiment 51-3 of frequency switching circuit 51 of the antenna assembly 109,111 of expression Figure 37 and Figure 39.In Figure 43, in the circuit of Figure 41, it is characterized in that, be connected inductor L2 side by side with switch SW 3.At this, the inductance value of inductor L2 is preferably set to: its parasitic capacitance when serving as disconnection with parallel resonance counteracting switch SW 3, when constituting switch SW 3 with the high-frequency semiconductor diode.In the present embodiment, the electric capacity of capacitor C3 for example is about 2pF, approximately adopts 68Nh as the inductance value of inductor L2.Thus, for example in the 429MHz frequency band, the influence of its parasitic capacitance in the time of can eliminating switch SW 3.Thus, when switch SW 3 disconnects, because the effect of its parasitic capacitance, so can solve the problem that resonance frequency departs from than design load.

Figure 44 is the circuit diagram of circuit of the 4th embodiment 51-4 of frequency switching circuit 51 of the antenna assembly 109,111 of expression Figure 37 and Figure 39.In Figure 44, it is characterized in that, in the circuit of Figure 42, appended inductor L2, have same action effect with above-mentioned the 3rd embodiment 51-3.

Figure 45 is the circuit diagram of circuit of the 1st embodiment 52-1 of frequency switching circuit 52 of the antenna assembly 110,112 of expression Figure 38 and Figure 40.In Figure 45, the end ground connection of antenna element A2, the actual central point A2m of antenna element A2 is via capacitor C4 and switch SW 4 ground connection.At this, antenna element comprises the inductance composition of high frequency.If connect switch SW 4, the variation of resonant frequency of antenna assembly then, but according to the difference of the electric capacity of capacitor C4, the direction difference of frequency change.

In the antenna assembly that people of the present invention try, be made as about 1pF at electric capacity with capacitor C1, the electric capacity of capacitor C4 is made as under the situation of about 10pF, resonance frequency is switched to 429MHz and 426MHz.At this, if connect switch SW 4, then resonance frequency raises.This be because: become the form that makes the central point A2m short circuit ground connection of antenna element A2 by capacitor C4, the cause that in fact inductance value of minute loop antenna A3 reduces.

At this,, thereby can adjust the variable quantity of the resonance frequency when having connected switch SW 4 by the position of the tie point A2m among the suitable selection antenna element A2 and the capacitance of capacitor C4.That is, if the tie point A2m among the antenna element A2 is configured in the position of the leaving minute loop antenna A3 position of ground connection (promptly near), then the inductance composition of this antenna assembly increases, and the variation of resonant frequency when having connected switch SW 4 is big.In addition, if increase the capacitance of capacitor C4, the resonance frequency when then having connected switch SW 4 is big.

Figure 46 is the circuit diagram of circuit of the 2nd embodiment 52-2 of frequency switching circuit 52 of the antenna assembly 110,112 of expression Figure 38 and Figure 40.In Figure 46, it is characterized in that, replace the capacitor C4 of Figure 45, and connected inductor L2, can insert reactance component in any case at Figure 45 and Figure 46.Illustrate in the present embodiment: antenna element A2 comprises the inductance composition of high frequency, if connect switch SW 4, then resonance frequency becomes big situation.This be because: be connected inductor L2 in parallel with the inductance composition of antenna element A2, the above-mentioned inductance composition when disconnecting with switch SW 4 is compared the cause that inductance composition during connection and the combination inductance value of inductor L2 diminish.And, for example compare with the inductance value of above-mentioned inductor composition, if the inductance value of inductor L2 is chosen as about 10 times, then can make resonance frequency only change a little.

Figure 47 is the circuit diagram of circuit of the 3rd embodiment 52-3 of frequency switching circuit 52 of the antenna assembly 110,112 of expression Figure 38 and Figure 40.In Figure 47, it is characterized in that, via the ground connection side one end ground connection of capacitor C5 with the antenna element A2 of the circuit of Figure 45.In the present embodiment, resonance frequency when switch SW 4 disconnects is decided by each capacitance of each inductance value, capacitor C1 and the C5 of antenna element A1, A2 and the inductance value of minute loop antenna A3, but the resonance frequency when switch SW 4 is connected on this basis, decided by the capacitance of capacitor C4.At this, by connecting cut-off switch SW4, thereby can make the variation of resonant frequency of antenna assembly.

Figure 48 is the circuit diagram of circuit of the 4th embodiment 52-4 of frequency switching circuit 52 of the antenna assembly 110,112 of expression Figure 38 and Figure 40.In Figure 48, it is characterized in that, via the ground connection side one end ground connection of inductor L3, can insert reactance component in any case at Figure 47 and Figure 48 with the antenna element A2 of the circuit of Figure 46.In the present embodiment, resonance frequency when switch SW 4 disconnects is decided by each inductance value of antenna element A1, A2, the capacitance of capacitor C1, the inductance value of inductor L3 and the inductance value of minute loop antenna A3, but the resonance frequency when switch SW 4 is connected on this basis, decided by the capacitance of capacitor C4.At this, by connecting cut-off switch SW4, thereby can make the variation of resonant frequency of antenna assembly.

Figure 49 is the circuit diagram of circuit of the 5th embodiment 52-5 of frequency switching circuit 52 of the antenna assembly 110,112 of expression Figure 38 and Figure 40.In Figure 49, it is characterized in that, be connected inductor L2 in parallel with the switch SW 4 of the circuit of Figure 47.At this, the inductance value of inductor L2 is preferably set to: its parasitic capacitance when serving as disconnection with parallel resonance counteracting switch SW 4, when constituting switch SW 4 with the high-frequency semiconductor diode.In the present embodiment, the parasitic capacitance of switch SW 4 for example is about 2pF, approximately adopts 68Nh as the inductance value of inductor L2.Thus, for example in the frequency band of 429MHz, can in fact eliminate the influence of the parasitic capacitance of switch SW 4.Thus, when switch SW 4 disconnects, because the effect of its parasitic capacitance, so can solve the problem that resonance frequency departs from than design load.

Figure 50 is the circuit diagram of circuit of the 6th embodiment 52-6 of frequency switching circuit 52 of the antenna assembly 110,112 of expression Figure 38 and Figure 40.In Figure 50, it is characterized in that, be connected inductor L2 in parallel with the switch SW 4 of the circuit of Figure 48.Thus, identical with the embodiment of Figure 49, can in fact eliminate the influence of the parasitic capacitance of switch SW 4.

And, even in the circuit of Figure 45 and Figure 46, also the be connected in parallel inductor L2 of influence of the parasitic capacitance when being used to eliminate switch SW 4 and disconnecting of switch SW 4 relatively.

Though uses the frequency band of the frequency switching circuit 51,52 in the above execution mode to adopt as purpose to enlarge, under the many situations of resonance deviation, match in order to make resonance frequency and desired frequency, also can be with the purpose employing of frequency adjustment.

In the above embodiment, frequency switching circuit 51 is inserted between antenna element A2 and the ground connection, but the present invention is not limited to this, as long as connect minute loop antenna A3 and antenna element A1, A2 at least one, and the switch SW 3 that connects the reactance component of insertion that short circuit in parallel is appended gets final product.

In the above embodiment, the point that connects each reactance component with frequency switching circuit 52, be the central point A2m of antenna element A2 or the ground connection side end of antenna element A2, but the present invention is not limited to this, as long as connect at least one of minute loop antenna A3 and antenna element A1, A2, and the switch SW 4 that connects the reactance component of insertion that short circuit in parallel is appended gets final product.

(the 13rd execution mode)

Figure 51 is the stereogram of the formation of the antenna assembly 113 that relates to of expression the 13rd execution mode of the present invention.The antenna assembly 113 that the 13rd execution mode relates to is compared following aspect difference with the antenna assembly 104 that the 4th execution mode of Figure 26 relates to.

(1) on inboard surface, the left side of dielectric base plate 10, adopts printed circuit method, formed respectively antenna element A1a, the A2a that the band conductor by the Copper Foil of actual rectilinear form constitutes in mode with antenna element A1, A2 quadrature.And, do not form earthing conductor 11 at the back side of the left inside portion of the dielectric base plate 10 that is formed with antenna element A1a, A2a.In addition, the ground connection side end of antenna element A2a connects earthing conductor 11 and ground connection via being filled into along the via conductors 13a in the through hole of thickness direction perforation dielectric base plate 10.

(2) in the left inside portion of the longitudinally of dielectric base plate 10, the upright relative dielectric base plate 10 and 14 vertical and have a dielectric base plate 14a of the width identical of having established with dielectric base plate 14 essence.At this, the Width of dielectric base plate 14a is parallel with the longitudinally of dielectric base plate 10.

(3) constituted minute loop antenna A3a by the band conductor that adopts printed circuit method on above-mentioned dielectric base plate 14a, to form Copper Foil.And, on near the end the ground connection side of minute loop antenna A3a, form via conductors 15a by in the through hole that connects dielectric base plate 14a along thickness direction, filling conductor, and be connected with antenna element A2a via the band conductor 15as at the back side that is formed at dielectric base plate 14a.

(4) capacitor C1a is being connected near the distributing point Q, but preferably shown in Figure 51, is connected on the substantial middle point of antenna element A1a.

(5) the distributing point Q side end of antenna element A1 connects the contact a of switch SW 5 and the contact b of switch SW 6, and the distributing point Q side end of antenna element A1a connects the contact b of switch SW 5 and the contact a of switch SW 6.The common terminal of switch SW 5 connects distributing point Q, the common terminal ground connection of switch SW 6.These switch SW 5 and SW6 interlock are for example by the control of the controller 24 (with reference to Fig. 1) in the wireless communication line 20.

In above such antenna assembly that constitutes 113, have the minute loop antenna A3 that has annulate shaft direction mutually orthogonal respectively and the antenna element A1 of A3a and mutually orthogonal, A2 and A1a, 2 antenna 113A of A2a, 113B, by controller 24 (with reference to Fig. 1), when for example the level of the radio signal that is received by antenna 113B in the level ratio of the radio signal that is received by antenna 113A is also big, switch SW 5 is switched to contact a side, simultaneously switch SW 6 is switched to contact b side, under opposite situation, switch SW 5 is switched to contact b side, simultaneously switch SW 6 is switched to contact a side.Thus, select to have and be connected to wireless communication line 20 (antenna is become antenna in the use) behind the antenna of bigger incoming level, and will not be connected to the untapped antenna ground of wireless communication line 20.At this, by with untapped antenna ground, thereby can prevent because of this untapped antenna influence, cause using in the operating characteristics deterioration of antenna.

Because these two antenna 113A, 113B have the directional characteristic and the polarizability of mutually orthogonal, so can obtain route diversity effect and polarization diversity effect.For example, wait within the family in the many environment of wall,, can obtain the route diversity effect by switching directional characteristic owing to have reception in a plurality of directions by multipath.In addition, under situation, use two antenna 113A, 113B of polarization characteristic, can obtain the polarization diversity effect with mutually orthogonal near metallic plate 30.And then according to the distance of distance metallic plate 30, directional characteristic and plane of polarization change, but because the directional characteristic of each antenna 113A, 113B or the variation of plane of polarization mutually orthogonal ground, so can remain diversity effect.

In the above embodiment, constitute antenna assembly 113, also can possess a plurality of same antennas, optionally switch with switch SW 5 though possess 2 antenna 113A, 113B.

(the 14th execution mode)

Figure 52 is the stereogram of the formation of the antenna assembly 114 that relates to of expression the 14th execution mode of the present invention.The antenna assembly 114 that the 14th execution mode relates to is compared following aspect difference with the antenna assembly 107 that the 7th execution mode of Figure 30 relates to.

(1) on the surface in the left side of dielectric base plate 10, adopt printed circuit method, formed respectively antenna element A1a, the A2a that the band conductor by the Copper Foil of actual rectilinear form constitutes in mode with antenna element A1, A2 quadrature.And, do not form earthing conductor 11 at the back side of the left side of the dielectric base plate 10 that is formed with antenna element A1a, A2a.In addition, the ground connection side end of antenna element A2a connects earthing conductor 11 and ground connection via being filled into along the via conductors 13a in the through hole of thickness direction perforation dielectric base plate 10.

(2) form minute loop antenna A3a by the band conductor that adopts printed circuit method on the surface of the left side edge end of above-mentioned dielectric base plate 10, to form Copper Foil.And, on near the end the ground connection side of minute loop antenna A3a, form via conductors 16a by in the through hole that connects dielectric base plate 10 along thickness direction, filling conductor, near as via conductors 16a and established from via conductors 16a folder on the position of band conductor of minute loop antenna A3a, form via conductors 17a in addition by in the through hole that connects dielectric base plate 10 along thickness direction, filling conductor.At this, near the end the ground connection side of minute loop antenna A3a via via conductors 16a, be formed at dielectric base plate 10 the back side band conductor 16as, via conductors 17a and be connected with antenna element A2a.

(3) capacitor C1a is being connected near the distributing point Q, but preferably shown in Figure 52, is connected on the substantial middle point of antenna element A1a.

(4) the distributing point Q side end of antenna element A1 connects the contact a of switch SW 5, and the distributing point Q side end of antenna element A1a connects the contact b of switch SW 5.The common terminal of switch SW 5 connects distributing point Q.

In above such antenna assembly that constitutes 114, possessed the antenna element A1, the A2 that have annulate shaft direction minute loop antenna A3 parallel to each other and A3a and mutually orthogonal respectively and 2 antenna 114A, the 114B of A1a, A2a, by by the controller 24 (with reference to Fig. 1) in the wireless communication line 20, the switch SW 5 of control, when for example the level of the radio signal that is received by antenna 114B in the level ratio of the radio signal that is received by antenna 114A is also big, switch SW 5 is switched to contact a side, under opposite situation, switch SW 5 is switched to contact b side.Because these two antenna 113A, 113B have mutually different directional characteristic and polarization characteristic, so can obtain route diversity effect and polarization diversity effect.

In the present embodiment, particularly under the situation of metallic plate 30 near dielectric base plate 10, though antenna gain reduces, but owing on 1 piece of dielectric base plate 10, can constitute the diversity antenna that has possessed two antenna 114A, 114B, so have the formation favourable to slimming, the miniaturization of the radio communication device that possesses antenna assembly 114.Towards to being suitable for of portable radio communication device even being suitable for to the radio communication device of subtend configuration metallic plate 30 not.

In the above embodiment, constitute antenna assembly 113, also can possess a plurality of same antennas, optionally switch with switch SW 5 though possess 2 antenna 113A, 113B.

(the 15th execution mode)

Figure 53 is the stereogram of the formation of the antenna assembly 115 that relates to of expression the 15th execution mode of the present invention.Figure 54 is the stereogram of structure of inboard of the antenna assembly 115 of expression Figure 53.Figure 55 is the stereogram of detailed content of the chimeric connecting portion of substrate of expression Figure 54.

The antenna assembly 115 that the 15th execution mode relates to, compare with the antenna assembly 104 that the 4th execution mode of Figure 26 relates to, it is characterized in that, possesses the chimeric connecting portion of substrate, it is with dielectric base plate 14 is upright when being located on the dielectric base plate 10, make with the protuberance 61,62 of lower surface from dielectric base plate 14 to the outstanding mode of short transverse that be formed at chimericly with the hole portion 71,72 of the end, inside edge that is formed at dielectric base plate 10 respectively, below it is described in detail.

In Figure 53 and Figure 54, on the end, inside edge of dielectric base plate 10, form the rectangular opening portion 71,72 that connects dielectric base plate 10 along thickness direction, on the other hand on the lower surface of dielectric base plate 14, form respectively cylindrical projection 61,62 with the chimeric rectangle of above-mentioned hole portion 71,72.

At this, till near the position of the hole portion 71 of dielectric base plate 10, the band conductor of antenna element A1 prolongs and forms, near position this hole portion 71, form via conductors 73 by fill conductor in the through hole that connects dielectric base plate 10 along thickness direction, the end of antenna element A1 is connected with the bonding conductor 81 at the back side of dielectric base plate 10 via this via conductors 73.This bonding conductor 81 is in the middle of hole portion 71 is clamped in, and is formed at the both sides of the hole portion 71 on the longitudinally of dielectric base plate 10.In bonding conductor 81, with clamping hole portion 71 only, its central portion has the mode that the conductor of the conductor exposed division 81p of regulation area exposes, other parts form resist layer (not shown)s, only each conductor exposed division 81p can weld.

In addition, till near the position of the hole portion 72 of dielectric base plate 10, the band conductor of antenna element A2 prolongs and forms, near position this hole portion 72, form via conductors 74 by fill conductor in the through hole that connects dielectric base plate 10 along thickness direction, the end of antenna element A2 is connected with the bonding conductor 82 at the back side of dielectric base plate 10 via this via conductors 74.This bonding conductor 82 is in the middle of hole portion 72 is clamped in, and is formed at the both sides of the hole portion 72 on the longitudinally of dielectric base plate 10.In bonding conductor 82, with clamping hole portion 72 only, its central portion has the mode that the conductor of the conductor exposed division 82p of regulation area exposes, other parts form resist layer (not shown)s, only each conductor exposed division 82p can weld.

On the other hand, in the antenna element A1 of dielectric base plate 14, A2 side the 1st (and will be called the 2nd face of dielectric base plate 14) with the face of the 1st parallel opposition side, form the band conductor 15At of minute loop antenna A3, one end and the antenna element A1, the A2 side that are formed at protuberance 61 the 1st (and, will be called the 2nd of protuberance 61 with the face of the 1st parallel opposition side.In addition, define the 1st and the 2nd too for protuberance 62.) on rectangle bonding conductor 63 connect, and the other end is connected to the band conductor 15As of the minute loop antenna A3 on the 2nd that is formed at dielectric base plate 14 via by filling the via conductors 15A that conductor forms to the through hole of the thickness direction that connects dielectric base plate 14.The end of its band conductor 15As is connected to the bonding conductor 64 on the 2nd that is formed at this protuberance 62 after extending to the 2nd of protuberance 62.

And then, the bonding conductor 63 of rectangle is formed on the 1st and the 2nd two sides of protuberance 61, be formed on bonding conductor 63 on this two side in the formation zone of this bonding conductor 63, the via conductors 63c that forms via filling conductor to the through hole that connects dielectric base plate 14 along thickness direction, be connected to each other, simultaneously has the mode that the conductor of the conductor exposed division 63p of regulation area exposes with its a part of central portion only, other parts form the resist layer (not shown), and only each conductor exposed division 63p can weld.In addition, the bonding conductor 64 of rectangle is formed on the 1st and the 2nd two sides of protuberance 62, be formed on bonding conductor 64 on this two side in the formation zone of this bonding conductor 64, the via conductors 64c that forms via filling conductor to the through hole that connects dielectric base plate 14 along thickness direction, be connected to each other, simultaneously has the mode that the conductor of the conductor exposed division 64p of regulation area exposes with its a part of central portion only, other parts form the resist layer (not shown), and only each conductor exposed division 64p can weld.

And, the protuberance 61,62 that makes dielectric base plate 14 respectively with the hole portion 71,72 of dielectric base plate 10 chimeric after, for example use scolding tin 82ph (with reference to Figure 55) to be connected electrically in respectively on conductor exposed division 81p, the 82p of dielectric base plate 10 sides by conductor exposed division 63p, the 64p of welding with protuberance 61,62.Thus, dielectric base plate 10 is fixedlyed connected with dielectric base plate 14.

Have again,, for example can adopt baseplate material arbitrarily such as glass epoxy substrate, paper phenol substrate, ceramic substrate, teflon (registered trade mark) substrate as dielectric base plate 10,14.In addition, 2 dielectric base plates 10,14 can change baseplate material.For example, the glass epoxy substrate (FR4) that dielectric base plate 10 adopts fine pattern to form, dielectric base plate 14 can adopt cheap paper phenol substrate etc.

In the above embodiment, the thickness that dielectric base plate 10,14 has regulation utilizes the structure of the chimeric connecting portion of substrate between protuberance 61,62 and the hole portion 71,72, can firmly fix mutually.In addition, protuberance 61,62 and hole portion 71,72 can easily make with the data processing method or the punching process method of dielectric base plate 10,14.And, because utilize the band conductor to form the inscape of antenna assembly 115, thus the deviation of each circuit key element value can be suppressed, the deviation of resonance frequency that can suppressing antenna device 115, the frequency that can omit when making is adjusted operation.

And then, in bonding conductor 63,64,81,82, weld after being respectively formed at conductor exposed division 63p that its central portion has predetermined surface, 64p, 81p, 82p.At this, when in bonding conductor 63,64,71,72, flowing through high-frequency signal, because of skin effect flows through bigger high-frequency current at each periphery, but by not with this periphery as the conductor exposed division, not as welding region, thereby suppress the deviation of coming the resonance frequency of suppressing antenna device with the electric capacity that causes by adhesion amount and variation inductance amount for minimum with scolding tin.

In the above embodiment, make two protuberances 61,62 chimeric with 2 hole portions 71,72 respectively, but the present invention is not limited to this, can makes at least one protuberance yet with chimeric corresponding to its at least one hole portion.

(the 16th execution mode)

Figure 56 is the stereogram of the formation of the antenna assembly 116 that relates to of expression the 16th execution mode of the present invention.The antenna assembly 116 that the 16th execution mode relates to is compared with the antenna assembly 115 that the 15th execution mode of Figure 53 relates to, and it is characterized in that, and is as described below, the chimeric syndeton difference of substrate.

In Figure 56, dielectric base plate 10 has the cylindrical projection 201,202 of the rectangle outstanding from its longitudinally end face along longitudinally, and on the other hand, dielectric base plate 14 has along the hole portion 211,212 of the rectangle of its thickness direction perforation.At this, on the two sides of the thickness direction of protuberance 201,202, form the bonding conductor 203,204 of rectangle respectively, each bonding conductor 203,204 on two sides is electrically connected by via conductors 203c, 204c respectively.In addition, on the central portion of the end face side of each bonding conductor 203,204 on two sides, form same conductor exposed division 203p, the 204p of conductor exposed division 63p, 64p, 81p, 82p respectively with the 15th execution mode.

In addition, form the band conductor 15As of minute loop antenna A3 on a face of dielectric base plate 14, the one end is connected to form near the bonding conductor 213 hole portion 211, and its other end is connected to form near the bonding conductor 214 hole portion 212.At this, in the middle of bonding conductor 213,214 is clamped in hole portion 211,212 respectively, have the short transverse both sides that are formed on dielectric base plate 14 and conductor exposed division 213p, the 214p same with conductor exposed division 63p, 64p, 81p, the 82p of the 15th execution mode.

In the above embodiment, insert respectively by protuberance 201,202 in the hole portion 211,212 of dielectric base plate 14 dielectric base plate 10, utilize welding that conductor exposed division 203p, 204p are connected on conductor exposed division 213p, the 214p, thereby dielectric base plate 10 can be securely fixed on the dielectric base plate 14.The antenna assembly 116 that present embodiment relates to has the same action effect of the antenna assembly that relates to the 15th execution mode 115.

In addition, according to present embodiment, owing to make the formation that dielectric base plate 14 is inserted in the dielectric base plate 10, so the shape of the band conductor of minute loop antenna A3 is increased than the 15th execution mode.Particularly, be accommodated under the situation about using in the resin box body, have the so big advantage of thickness direction that dielectric base plate 14 is increased to the resin box body at the antenna assembly 116 that present embodiment is related to.

In the above embodiment, make two protuberances 201,202 chimeric with 2 hole portions 211,212 respectively, but the present invention is not limited to this, can makes at least one protuberance yet with chimeric corresponding to its at least one hole portion.

(industrial utilizability)

As described above, according to the present invention, can provide a kind of no matter with conductor near antenna also Be away from antenna, compare with the minute loop antenna of prior art, can obtain high antenna gain It line apparatus and the radio communication device that uses it.

Therefore, the sky line apparatus that the present invention relates to is not had as pager, mobile phone etc. are portable Line communication device or built-in or be installed on radio communication device in the white metal household appliances etc. It line apparatus can extensively be suitable for. In addition, as being arranged on gas meter, ammeter, running water The sky line apparatus of the automatic measurement mechanism in the table etc. uses, and also is fine.

Claims (29)

1. antenna assembly possesses:

Dielectric base plate with the face that has earthing conductor;

Minute loop antenna, it is designed to the contiguous described dielectric base plate in electro permanent magnetic ground, twine and have the miniature length of regulation with the winding times N of regulation, at the metallic plate of regulation near flowing through magnetic current and move to intersect the mode of minute loop antenna during antenna assembly as magnetic-current antenna

At least 1 antenna element connects described minute loop antenna, pushes up loading by described minute loop antenna at described metallic plate when described antenna assembly leaves, and flows through electric current and move as the electric current antenna in described minute loop antenna and described earthing conductor; It is characterized in that, wherein

Described antenna assembly also possesses at least one side who connects described minute loop antenna and described antenna element, and is used for carrying out with the inductance of described minute loop antenna and described antenna element at least one the 1st capacitor of resonance series;

One end of described antenna assembly is connected in distributing point, and the other end of described antenna assembly is connected in the earthing conductor of described dielectric base plate and ground connection;

Described antenna assembly is in the magnetic-current antenna action as described minute loop antenna when the described antenna assembly of described metallic plate, and when described metallic plate leaves described antenna assembly as the electric current antenna action of at least one antenna element.

2. antenna assembly according to claim 1 is characterized in that, described at least 1 antenna element is designed to parallel with the face of described dielectric base plate.

3. antenna assembly according to claim 1 and 2 is characterized in that, possesses 2 antenna elements.

4. antenna assembly according to claim 3 is characterized in that, described 2 antenna elements are respectively rectilinear forms, and are designed to parallel to each other.

5. antenna assembly according to claim 1 is characterized in that, described the 1st capacitor inserts the central point of described antenna element and connects.

6. antenna assembly according to claim 1 is characterized in that, described the 1st capacitor a plurality of capacitor elements that are connected in series form.

7. antenna assembly according to claim 1 is characterized in that, described the 1st capacitor has many group circuit,

Described many group circuit are connected in parallel mutually,

Described many group circuit, a plurality of capacitor elements that have been connected in series respectively form.

8. antenna assembly according to claim 1 is characterized in that this antenna assembly also possesses impedance matching circuit, and it connects described distributing point, and makes the input impedance of described antenna assembly and the characteristic impedance coupling of the feeder cable that is connected described distributing point.

9. antenna assembly according to claim 1 is characterized in that, described minute loop antenna is designed to: the face of its section roller direction and described dielectric base plate intersects vertically.

10. antenna assembly according to claim 1 is characterized in that, described minute loop antenna is designed to: its section roller direction is parallel with the face of described dielectric base plate.

11. antenna assembly according to claim 1 is characterized in that, described minute loop antenna is designed to: the face of the described relatively dielectric base plate of its section roller direction, and with the inclination angle inclination of regulation.

12. antenna assembly according to claim 1 is characterized in that, the winding times N of described minute loop antenna is set at N=(n-1)+0.5, and wherein n is a natural number.

13. antenna assembly according to claim 12 is characterized in that, the winding times N of described minute loop antenna is set at N=1.5.

14. antenna assembly according to claim 1 is characterized in that,

This antenna assembly also possesses:

At least one floating conductor with described minute loop antenna and the adjacent setting of described antenna element electro permanent magnetic;

The 1st switching mechanism, it is connected described floating conductor or do not connect with described earthing conductor by optionally switching, thereby the directional characteristic of described antenna assembly or plane of polarization are changed.

15. antenna assembly according to claim 14 is characterized in that,

This antenna assembly possesses and is designed to orthogonal 2 crossing floating conductors,

Described the 1st switching mechanism is connected described floating conductor or do not connect with described earthing conductor by optionally switching, thereby the directional characteristic of described antenna assembly or at least one side of plane of polarization are changed.

16. antenna assembly according to claim 1 is characterized in that,

This antenna assembly also possesses:

The 1st reactance component, it is connected at least one side of described minute loop antenna and described antenna element; With

The 2nd switching mechanism, it passes through optionally to switch described the 1st reactance component short circuit or not short circuit, thereby makes the variation of resonant frequency of described antenna assembly.

17. antenna assembly according to claim 16 is characterized in that,

Described the 2nd switching mechanism is included in the high-frequency semiconductor element that has parasitic capacitance when it disconnects,

This antenna assembly further possesses the 1st inductor that is used to eliminate described parasitic capacitance.

18. antenna assembly according to claim 1 is characterized in that,

This antenna assembly also possesses:

The 2nd reactance component, it has the end at least one side who is connected described minute loop antenna and described antenna element; With

The 3rd switching mechanism, it passes through optionally to switch described the 2nd reactance component ground connection or earth-free, thereby makes the variation of resonant frequency of described antenna assembly.

19. antenna assembly according to claim 18 is characterized in that, this antenna assembly also possesses at least one side's who is connected to described minute loop antenna and described antenna element the 3rd reactance component.

20. antenna assembly according to claim 19 is characterized in that,

Described the 3rd switching mechanism is included in the high-frequency semiconductor element that has parasitic capacitance when it disconnects,

This antenna assembly further possesses the 2nd inductor that is used to eliminate described parasitic capacitance.

21. an antenna assembly is characterized in that,

Possess a plurality of antenna elements,

And possesses the 4th switching mechanism, it is according to the wireless signal that is received by described a plurality of antenna elements, optionally switch, make to select an antenna element among a plurality of antenna elements and do not select other antenna element, be connected to distributing point with the end that does not have ground connection of an antenna element will selecting;

Described antenna element comprises:

Dielectric base plate with earthing conductor;

Minute loop antenna, it is designed to the contiguous described dielectric base plate in electro permanent magnetic ground, twine and have the miniature length of regulation with the winding times N of regulation, at the metallic plate of regulation near flowing through magnetic current and move to intersect the mode of minute loop antenna during antenna element as magnetic-current antenna

At least 1 antenna element connects described minute loop antenna, pushes up loading by described minute loop antenna at described metallic plate when described antenna element leaves, and flows through electric current and move as the electric current antenna in described minute loop antenna and described earthing conductor; With

Connect at least one side of described minute loop antenna and described antenna element, and be used for carrying out at least one the 1st capacitor of resonance series with the inductance of described minute loop antenna and described antenna element;

One end of described antenna element connects distributing point, and the other end of described antenna element connects the earthing conductor of described dielectric base plate;

Described antenna element is in the magnetic-current antenna action as described minute loop antenna when the described antenna element of described metallic plate, and when described metallic plate leaves described antenna element as the electric current antenna action of at least one antenna element.

22. antenna assembly according to claim 21 is characterized in that, described the 4th switching mechanism is with a unearthed end ground connection of unselected antenna element.

23. antenna assembly according to claim 1 is characterized in that, described dielectric base plate also has the face that does not form earthing conductor,

With described antenna element, be formed on the face that does not form earthing conductor of described dielectric base plate.

24. antenna assembly according to claim 23 is characterized in that, described antenna assembly also possesses other dielectric base plate,

Described minute loop antenna is formed on described other the dielectric base plate.

25. antenna assembly according to claim 24 is characterized in that,

Described other dielectric base plates have at least one protuberance,

Described dielectric base plate has at least one hole portion chimeric with at least one protuberance of described dielectric base plate,

At least one protuberance by making described other dielectric base plates and at least one hole portion of described dielectric base plate are chimeric, thereby described other dielectric base plates are connected on the described dielectric base plate.

26. antenna assembly according to claim 25 is characterized in that,

Described dielectric base plate has at least one protuberance,

Described other dielectric base plates have at least one protuberance and at least one the chimeric with it hole portion that inserts described dielectric base plate,

At least one the hole portion that inserts described other dielectric base plates by at least one protuberance that makes described dielectric base plate is also chimeric, thereby described dielectric base plate can be connected on described other dielectric base plates.

27. antenna assembly according to claim 25 is characterized in that, this antenna assembly further possesses:

The 1st bonding conductor, it is formed on the described dielectric base plate, and has connected described antenna element; With

The 2nd bonding conductor, it is formed on described other dielectric base plates, and has connected described minute loop antenna;

When having connected described dielectric base plate and described other dielectric base plates, described the 1st bonding conductor and described the 2nd bonding conductor have been electrically connected.

28. antenna assembly according to claim 27 is characterized in that,

Described the 1st bonding conductor possesses the 1st conductor exposed division, and this exposed division is the part of described the 1st bonding conductor, has the 1st area of regulation, is used to connect the welding of described the 2nd bonding conductor,

Described the 2nd bonding conductor possesses the 2nd conductor exposed division, and this exposed division is the part of described the 2nd bonding conductor, has the 2nd area of regulation, is used to connect the welding of the 1st bonding conductor.

29. a radio communication device is characterized in that possessing:

Antenna assembly; With

Be connected the wireless communication line on the described antenna assembly;

Described antenna assembly comprises:

Dielectric base plate with the face that has earthing conductor;

Minute loop antenna, it is designed to the contiguous described dielectric base plate in electro permanent magnetic ground, twine and have the miniature length of regulation with the winding times N of regulation, at the metallic plate of regulation near flowing through magnetic current and move to intersect the mode of minute loop antenna during antenna assembly as magnetic-current antenna

At least 1 antenna element connects described minute loop antenna, pushes up loading by described minute loop antenna at described metallic plate when described antenna assembly leaves, and flows through electric current and move as the electric current antenna in described minute loop antenna and described earthing conductor; With

Connect at least one side of described minute loop antenna and described antenna element, and be used for carrying out at least one the 1st capacitor of resonance series with the inductance of described minute loop antenna and described antenna element;

One end of described antenna assembly connects distributing point, and the other end of described antenna assembly connects the earthing conductor of described dielectric base plate and ground connection;

Described antenna assembly is in the magnetic-current antenna action as described minute loop antenna when the described antenna assembly of described metallic plate, and when described metallic plate leaves described antenna assembly as the electric current antenna action of at least one antenna element.

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