JP3443897B2 - Loop antenna for circular polarization - Google Patents

Description

Description: BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a circularly polarized loop antenna. 2. Description of the Related Art In recent years, the use of satellite mobile communication has rapidly increased, and the development of a thin, small, lightweight, stable and inexpensive circularly polarized antenna has been promoted. As this type of antenna, a microstrip antenna (MSA) is well known, but an expensive material such as Teflon having a small dielectric loss is required for the substrate due to the operation principle of the microstrip line. On the other hand, various attempts have been made to generate circularly polarized waves using a linear antenna having the simplest configuration. As an example of this, Japanese Patent Application Laid-Open No. 61-252701 (hereinafter referred to as Reference 1) discloses a circularly polarized loop antenna in which a (線路) λ branch line is extended in parallel with a loop antenna conductor. Is disclosed. In addition, the IEICE Journal [82/8 Vol. J65
-B No. 8] (hereinafter referred to as Document 2) includes approximately 1λ
A configuration in which a reactance is loaded on the loop-shaped antenna conductor is disclosed. The principle of generation of circularly polarized waves by these loop antennas is that a current having a traveling wave phase with a substantially constant amplitude is generated in the antenna conductor by impedance or reactance loaded on the antenna conductor. [0005] However, in the circularly polarized wave loop antenna described in the above document 1, the distance between the antenna conductor and the branch line and the circularly polarized wave described in the document 2 are different. In a loop antenna, the position of the loaded reactance from the feeding point (φ = −π / 4) is important for generating circularly polarized waves. If these are not strictly adjusted, the circularly polarized waves can be stably generated. Cannot occur. [0006] Even if it is adjusted, when it is used, for example, in an environment where external vibration is applied, the relative position between the antenna conductor and the branch line or the loaded reactance fluctuates, and the generated circularly polarized wave becomes unstable. In the circularly polarized loop antennas described in Documents 1 and 2, the position of the branch line or the loaded reactance is asymmetric with respect to the loop-shaped antenna conductor, so that the radiation directivity is asymmetric. This is unavoidable, and there is a problem as an antenna for mobile communication. An object of the present invention is to solve the problem of generating a circularly polarized wave, requiring no adjustment, stably generating a circularly polarized wave, and providing symmetrical radiation directivity. [0008] A circularly polarized loop antenna of the present invention is formed by alternately cascading two types of transmission lines having different characteristic impedances to form a loop having a total length of approximately 1λ. And an antenna conductor in which the transmission lines having the same characteristic impedance are symmetrically arranged . [0009] In the present invention, the antenna conductor may further include λ
/ 4 and constitute one of the two types of transmission lines.
A single-wire conductor consisting of a single linear conductor, and the same
By two linear conductors having the same length and the same length and parallel to each other
Configured the parallel two-wire conductors constituting the other of said two transmission lines to have a rectangular shape with the sides, respectively Ri. Each transmission line can be replaced with a microstrip line. In the circularly polarized wave loop antenna of the present invention as well, the transmission lines connected in cascade in a loop have different characteristic impedances, so that reflection occurs in the antenna conductor and the traveling wave current is reduced. And circularly polarized waves can be generated . In the present invention, the transmission line having a large diameter formed of one linear conductor is formed of two parallel linear conductors.
The characteristic impedance is made different by utilizing the fact that it can be replaced by a parallel two-wire conductor. Thus, even without loading a minute岐導body and reactance to the antenna conductor, the characteristic of the circularly polarized wave by the antenna conductor can determine Mel can stably generate a circularly polarized wave. Further, since transmission lines having the same characteristic impedance are arranged symmetrically, the symmetry of radiation directivity can be reliably obtained. [0013] As described above, according to the present invention, according to the present invention, very stable generate circularly polarized waves by racemate Rukoto different transmission line characteristic impedance of the two which constitute the antenna conductor
It can be Rukoto. Moreover, different characteristic impedance
By symmetrically arranging the two transmission lines having the following, the symmetry of the radiation directivity is obtained, which is suitable for mobile communication such as an automobile. Further, according to the present invention, since circular polarization is generated only by the rectangular loop-shaped antenna conductor, there is no need to load a branch line or reactance, and adjustment for generating circular polarization is unnecessary. Also, even when used in an environment of external vibration, circularly polarized waves can be stably generated. DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, a circularly polarized loop antenna according to the present invention will be described in detail with reference to the drawings. As shown conceptually in FIG. 1, the circularly polarized loop antenna according to the present invention includes a loop-shaped antenna conductor 10 having a total length of 1λ. The antenna conductor 10 has a characteristic impedance Z
The transmission lines 11 and 12 having a λ / 4 length set to ₀ and the transmission lines ₁ having a λ / 4 length set to a characteristic impedance Z 1.
The transmission lines 3 and 14 are alternately connected to form a square loop, and the transmission lines having the same characteristic impedance are opposed to each other. The feed terminals 1 and 5 of the antenna conductor 10
The intersections of the adjacent transmission lines 11 and 14 are provided open. The circularly polarized loop antenna is shown in FIG.
As shown in (a), the transmission lines 11 to 14 divided by the power supply terminals 1 and 5 and the nodes 2, 3 and 4 can be represented by an equivalent circuit in which the transmission lines are cascaded. The radiation resistance of each transmission line 1
1 to 14 are equivalently distributed. Here, each of the transmission lines 11 to 14 and the equivalently distributed radiation resistance ra form a series circuit and are cascaded series elements. Also, the radiation resistance r distributed equivalently
a is concentrated on both sides of each of the transmission lines 11 to 14 by ra / 2. Hereinafter, based on the equivalent circuit shown in FIG. 2A, conditions for generating the circularly polarized wave by the circularly polarized wave loop antenna will be obtained. In the circuit of FIG. 2A, the voltage V ₁ and the current I
₁ signal is applied to the power supply terminal 1, the voltage V ₅ to the power supply terminal 5, if those transmission as a signal of current I _1,
The condition for the antenna conductor 10 to generate a circularly polarized wave must satisfy the following condition from the terminal condition: V ₁ −V ₅ = V ₀ (1) I ₁ = I ₅ (2) . On the other hand, if the F matrix is used, V ₁ , I ₁ and V
₅ and I ₅ are That is, I ₁ = CV ₅ + DI ₁ Is obtained. [0019] Now, in order to radiate circularly polarized waves in a direction perpendicular to the antenna conductor 10, and a transmission line 13 of the transmission line 11 (or 12) to the characteristic impedance Z ₁ of the characteristic impedance Z ₀ (or 14) The following condition is a necessary condition for the phase difference between the flowing currents I ₁ and I ₂ . However, the upper code indicates left-handed circular polarization, and the lower code indicates right-handed circular polarization. V ₁ and I ₁ and V ₂ and I
₂ is from FIG. According to Equations (6) and (7), ... (8) is obtained. Substituting equation (8) into equation (5) yields: ... (9) Here, since A and C are products of the matrix [F _i ] in FIG. 2B, (Equation 4) ... (10) Now, assuming that ra≪Z ₀ , Z ₁ , ... (11) This approximation holds when the height h of the antenna conductor 10 from the reflector 15 is h≪λ. Thus, equation (9) is given by: ... (12) Therefore, the following circular polarization condition is obtained. [Mathematical formula-see original document] (13) Here, since ra is positive, the lower sign is satisfied when Z ₁ <Z ₀ , the right-handed circularly polarized wave is satisfied, and the upper sign is satisfied when Z ₁ > Z _0. , Left-handed circularly polarized light. This inverse relationship is illustrated in FIG.
It can be seen that this is clearly established from the structural symmetry as shown in (a) and (b). Next, the resistance ra is approximated using the radiation resistance Ra of a normal one-wavelength loop antenna. When Z ₀ = Z ₁ , linear polarization occurs, and the resistance of nodes 2 and 4 becomes 0,
The equivalent circuit shown in FIG. Since the line of λ / 2 can be omitted as impedance, the circuit of FIG. 4A is modified as shown in FIG. It becomes. On the other hand, in the case of H«ramuda, radiation resistance Ra of the one-wavelength loop antenna can be considered schematic, and 2 times the radiation resistance R _d of the half-wave dipole on the reflecting plate 15. Thus, ... (15), and the structure of the antenna conductor 10 can be determined. Next, ginseng circularly polarized wave loop antenna according to the present invention
The considered example shown in FIG. The loop antenna for circular polarization shown in FIG. 5 has linear conductors 16 and 17 having a radius of a ₀ and a length of λ / 4 on a reflector 15 and a length of λ / 4 and a radius of a ₁ (> a ₀ ). The linear conductors 18 and 19 are alternately arranged in a square loop to form an antenna conductor 20. Power is supplied by opening the intersection of adjacent linear conductors. According to such an antenna conductor 20, the linear conductors 16 and 17 having a radius a _{0 and} the linear conductors ₁ having a radius a ₁ are provided.
8, 19 And implements the antenna conductor 10 shown in FIG. FIG. 6 shows an embodiment of the present invention. In another embodiment shown in FIG. 6, a linear conductor having a radius a ₀ shown in FIG. ... (17) can be equivalently replaced with a parallel two-wire conductor having a radius a and a distance d shown in FIG.
The linear conductor 18 and 19 of radius a ₁ shown, replaced respectively parallel two-wire conductors 23, 24 of the distance d, to each other between the end points of the parallel two-wire conductors 23, 24 of the linear conductors 16 and 17 it is obtained by forming an antenna conductor 30 and connected by a single wire conductors 21 and 22 which maintain a radius a _0. Here, the characteristic impedance of the parallel two-wire conductors 23 and 24 is
Are equivalent and its radius a ₀ of 1, 22. Power is supplied by opening the intersection between the parallel two-wire conductor 24 and the single-wire conductor 21. FIG. 8 shows the result of measuring the axial ratio of circularly polarized waves with the antenna conductor 30 of FIG. The vertical axis represents the axial ratio [dB], and the horizontal axis represents the frequency [GHz]. The distance d of the parallel two-wire conductor 23 (or 24) is 1.44 mm and the length L
y is 22.5 mm, the length of the single conductor 21 (or 22) is 37.5 mm as a length Lx to which the distance d is added, and the radius a ₀ is 0.3 mm. [0041] According to FIG. 8, it shall be the subject 1.8 ~2GH
In the frequency range of z , the circularly polarized wave has the best axis at 1.9 GHz.
It can be seen that they can have a ratio . According to this embodiment to achieve such in the present invention, it is possible to generate a circularly polarized wave with only the antenna conductor to the linear conductor of the Ichi径elements, never loading the branch conductor and reactance Therefore, no adjustment is required, and circularly polarized waves can be generated extremely stably without being affected by external vibration or the like. Further, with different characteristic impedance with a combination of a flat row two-wire conductor and a single wire conductor, since the arrangement of these two types of linear conductors on two sides each facing the square loop, the radiation directivity Symmetry is obtained, which is suitable for mobile communication such as an automobile. Furthermore, since it is only necessary to form the linear conductors of the same Ichi径in a loop, it is possible to easily produce by a means integral molding, there is an advantage that the cost can be reduced. The height h between the reflector and the antenna conductor is arbitrary, and the reflector may not be provided. Further, the antenna conductor may be buried in a plate-shaped dielectric.
Moreover, the linear conductors are easy to replace in the microstrip line can be configured as a printed circuit board.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a conceptual diagram illustrating the principle of circularly polarized wave generation of a circularly polarized wave loop antenna according to the present invention, where (a) is a plan view showing only an antenna conductor, and (b). FIG. 2A is an equivalent circuit diagram of the entire circularly polarized wave loop antenna of FIG. 1, and FIG. 2B is an equivalent circuit diagram of one block. FIG. 3 is an explanatory diagram showing that a right-handed circularly polarized wave (a) and a left-handed circularly polarized wave (b) are obtained by disposing transmission lines having different characteristic impedances according to the present invention. FIG. 4 is an equivalent circuit diagram for approximating the radiation resistance of the circular polarization loop antenna from the radiation resistance of a normal loop antenna having a uniform characteristic impedance. FIG. 5 is a perspective view showing a reference example of the present invention. FIG. 6 is a perspective view showing another embodiment embodying the present invention. FIG. 7 is an explanatory diagram showing a process of deriving the embodiment of FIG. 6; 8 is a measurement diagram of axial ratio characteristics in the embodiment of FIG. [Description of Signs] 1,5: Feeding terminals, 2, 3, 4, ... Nodes, 10: Antenna conductors, 11, 12, Transmission lines, 13, 14, ... Transmission lines,
15: Reflector, 16, 17: Linear conductor, 18, 19: Linear conductor, 20: Antenna conductor, 21, 22: Single line conductor,
23, 24 ... parallel two-wire conductor, Z _0, Z ₁ ... characteristic impedance.

──────────────────────────────────────────────────続 き Continuation of the front page (56) References JP-A-61-252701 (JP, A) JP-A-54-69366 (JP, A) JP-A-54-62642 (JP, U) 3558 (JP, B1) Takashi Nakamura et al., Circularly Polarized Compound Loop Antenna, IEICE Technical Report, Japan, IEICE, October 21, 1993, Vol. 93, NO. 280 (A.P93-73-85), P.E. 71-77 (58) Field surveyed (Int. Cl. ⁷ , DB name) H01Q 7/00 H01Q 1/24

Claims (1)

(57) [Claims 1] Two types of transmission lines having different characteristic impedances are alternately cascaded to form a loop having a total length of approximately 1λ (where λ is a wavelength) and the same characteristic impedance. An antenna conductor formed by symmetrically arranging the transmission lines.
The antenna conductor has a length of λ / 4 and has a length of λ / 4.
Single line consisting of one linear conductor that constitutes one of the transmission lines
The conductor and the single-wire conductor have the same diameter and the same length, and
The two types of transmission lines, which are constituted by two linear conductors
The parallel two-wire conductors that make up the other side of the road are sides
A circularly polarized loop antenna , having a square shape .