JP4076931B2 - Antenna feeder - Google Patents

Description

  The present invention relates to an antenna feeding unit that impedance-matches an antenna and connects it to a cable, and is particularly suitable for application to a film antenna or a glass antenna.

  Conventionally, in order to connect a film antenna to an antenna joint portion of a connection unit, a connector 102 having a springy contact terminal mounted on a substrate 101 as shown in FIGS. The terminal portion 100a is inserted and connected (see Patent Document 1). A coaxial cable 103 is connected to the substrate 101, and a reception signal of the film antenna 100 is derived from the coaxial cable 103. In this configuration, since the terminal portion 100a formed on the film antenna 100 is only a simple power feeding pattern, the matched impedance of the film antenna 100 causes a mismatch in the terminal portion 100a. Similarly, the connector 102 is not a coaxial connector, but is simply a connector 102 for conducting electricity, which causes a further problem of impedance mismatch and loss of signal. Furthermore, the terminal portion 100a is provided with a reinforcing plate 100b so that it can be easily inserted into the connector 102. However, there is a problem that stress concentrates on the boundary portion between the reinforcing plate 100b and the film antenna 100 and breaks easily. It was.

Further, as shown in FIG. 22 and FIG. 23, it has also been conventionally performed that the AV cable 110 extended from the coaxial cable 103 is directly attached to the terminal portion 100a formed on the film antenna 100 (see Patent Document 1). ). Even in such a configuration, impedance mismatch occurs similarly in the terminal portion 100a formed in the film antenna 100, and further, the mismatch occurs due to the extension of the AV cable 110 from the coaxial cable 103, resulting in signal loss. There was a problem that it occurred. In addition, since the AV cable 110a is used, an unstable state in which the impedance characteristic changes greatly due to the routing of the AV cable 110 comes to occur.
The configuration of the antenna power supply unit in which mismatch occurs as described above is also performed in a glass antenna formed on a glass plate, and there is a problem that signal loss occurs.
Japanese Patent No. 3294737

  SUMMARY OF THE INVENTION An object of the present invention is to provide an antenna feeder that does not cause mismatch by connecting lines having characteristic impedance.

In order to achieve the above object, the antenna feeder of the present invention has a coplanar line having a characteristic impedance formed in a terminal portion of a film antenna or a glass antenna, and has a characteristic impedance in a substrate from which a cable is derived. The main feature is the formation of coplanar lines.

  According to the present invention, the terminal portion and the substrate can be matched and connected by polymerizing and fixing the terminal portion of the film antenna or the glass antenna and the substrate from which the cable is led out through the elastic connection plate. become able to. As a result, the reception signal of the film antenna can be led out to the cable without loss. Further, by providing an insertion hole in the terminal portion of the film antenna and inserting it into the protrusion provided in the lower case, it is possible to prevent the film antenna from coming out even when pulled by vibration or strong force.

  A line having a characteristic impedance formed on a terminal portion of a film antenna or a glass antenna and a substrate from which the cable is led for the purpose of providing an antenna feeding portion that leads out a cable without mismatching from a film antenna or a glass antenna It was realized by connecting the gaps through elastic connection plates.

  The configuration of the antenna feeding unit according to the first embodiment of the present invention is shown in FIGS. However, FIG. 1 is an exploded view illustrating the configuration of the antenna power feeding unit according to the first embodiment of the present invention, and FIG. 2 is a top view illustrating the configuration of the antenna power feeding unit according to the first embodiment of the present invention with the upper case removed. FIG. 3 is a sectional view showing a side view of the configuration of the antenna power feeding unit according to the first embodiment of the present invention.

  The antenna feeder 1 according to the first embodiment of the present invention shown in these drawings is an antenna feeder that can electrically connect the coaxial cable 19 without mismatching with the film antenna 10. 15 has a case, and the antenna feeding structure is housed in this case. The film antenna 10 is configured by forming an antenna element 10a and a ground element 10b on a transparent or colored resin film so as to have a predetermined characteristic impedance. The antenna element 10a and the earth element 10b are provided on a film by sticking or vapor-depositing a conductive foil having a predetermined width and a predetermined length. One end of the film antenna 10 is projected to form a terminal portion 10c. For example, a coplanar line having a characteristic impedance of 50Ω is formed at the terminal portion 10c, and an antenna including an antenna element 10a having a characteristic impedance that matches impedance with the coplanar line and an earth element 10b is connected. The terminal portion 10c is formed with a pair of positioning insertion holes 10d and 10e for positioning.

  A coaxial cable 19 having a predetermined characteristic impedance to which the film antenna 10 is connected is connected to the circuit board 14. For example, a pattern of a coplanar line having a characteristic impedance of 50Ω is formed on the front surface of the circuit board 14, and a core wire and a ground portion of a coaxial cable 19 having a characteristic impedance matching impedance are connected to the coplanar line. ing. On the back surface of the circuit board 14, an earth is formed on the entire surface to which the earth portion of the coplanar line is connected. In addition, a pair of positioning insertion holes 14 a are formed at the tip of the circuit board 14.

  The coplanar line formed on the terminal portion 10 c of the film antenna 10 and the coplanar line formed on the circuit board 14 are connected by the elastic connection plate 13. The elastic connecting plate 13 is made of a highly elastic elastomer such as silicon rubber. As shown in FIG. 4, the conductive layers 13b and the insulating layers 13c are alternately arranged to form a coplanar line having a characteristic impedance of 50Ω, for example. ing. The conductive layer 13b is formed by orienting metal fine wires with high density in the thickness direction of the elastic connecting plate 13, mixing metal particles or carbon particles into the elastomer, or arranging metal fine wires on the surface of the elastomer at a low pitch. It is comprised by. The insulating layer 13c is made of an insulating elastomer. The elastic connection plate 13 has a pair of positioning insertion holes 13a for positioning.

  The lower case 15 is shaped like a half of a rectangular box, and a pair of protrusions 15a and 15b are formed in the interior thereof. The pair of protrusions 15 a are inserted into the insertion holes 14 a of the circuit board 14, the insertion holes 13 a of the elastic connection plate 13, and the insertion holes 10 d of the terminal portions 10 c of the film antenna 10. Further, a fitting hole 10e in the terminal portion 10c of the film antenna 10 is fitted into the pair of protrusions 15b. On both side surfaces of the long side of the lower case 15, there are formed bearing portions 15c with which the first engagement pieces 16 and the second engagement pieces 17 are respectively engaged so as to be rotatable. Further, one of the remaining side faces is formed with a cable lead-out hole 15d through which the coaxial cable 19 is led out, and a slit opening 15e into which the terminal part 10c of the film antenna 10 is introduced is formed on the opposite side face. Yes. Further, a rectangular insertion hole 15 f into which the rectangular ground conductor 18 is inserted is formed on the lower surface of the lower case 15.

  A pair of fitting recesses 11a and 11b are formed inside the upper case 11 fitted to the lower case 15, respectively. The pair of fitting recesses 11 a are recesses into which the tips of the protrusions 15 a are fitted when fitted into the lower case 15. Further, the pair of fitting recesses 11 b are recesses into which the tips of the protrusions 15 b are fitted when fitted into the lower case 15. Furthermore, a pair of engaging protrusions 11c are formed on both sides of the upper case 11 to engage the first engaging piece 16 and the second engaging piece 17 when fitted to the lower case 15. .

  The first engagement piece 16 and the second engagement piece 17 are formed with shaft portions 16 a and 17 a protruding on both sides, and the shaft portions 16 a and 17 a are formed on both sides of the lower case 15. Each is fitted in a rotatable manner. In addition, engagement claws 16b and 17b are formed at the distal ends of the first engagement piece 16 and the second engagement piece 17 along the axial direction. The engaging claws 16b and 17b rotate the first engaging piece 16 and the second engaging piece 17 fitted to the lower case 15 so that the upper case 11 is fitted to the bearing portion 15c. In this case, the upper case 11 is engaged with the engaging protrusion 11c, whereby the lower case 15 and the upper case 11 are integrated. Thus, the lower case 15 and the upper case 11 can be integrated and separated by a simple operation.

  Here, the assembly procedure of the antenna power feeding unit 1 will be described. First, the circuit board 14 is housed in the lower case 15 while the fitting holes 14a are inserted into the pair of protrusions 15a of the lower case 15. At this time, the coaxial cable 19 is led out from the cable lead-out hole 15d. Next, the elastic connection plate 13 is accommodated in the lower case 15 while fitting the insertion holes 13 a into the pair of protrusions 15 a of the lower case 15 so as to be superimposed on the circuit board 14. Further, the terminal portion of the film antenna 10 is inserted into the pair of protrusions 15a of the lower case 15 so as to be superimposed on the elastic connecting plate 13 and the insertion holes 10e are inserted into the pair of protrusions 15b. 10 c is stored in the lower case 15. At this time, the root of the terminal portion 10c is introduced from the slit opening 15e.

  Next, the insulating washer 12 is housed in the lower case 15 while fitting the insertion holes 12a into the pair of protrusions 15a of the lower case 15 so as to be superimposed on the terminal portion 10c. Then, the upper case 11 is fitted into the lower case 15. At this time, the tips of the pair of protrusions 15a of the lower case 15 are fitted into the fitting recess 11a, and the tips of the pair of projections 15b are fitted into the fitting recess 11b. Further, the first engagement piece 16 and the second engagement piece 17 are rotatably fitted to the bearing portion 15c of the lower case 15 and rotated, and the engagement protrusion 11c of the upper case 11 is engaged with the engagement claw. 16b and 17b are engaged. Thus, the lower case 15 and the upper case 11 are reliably integrated so that the circuit board 14 is sandwiched in a state where the washer 12 and the elastic connection plate 13 are compressed by the upper case 11 and the lower case 15. Become. Then, the antenna feeder 1 is assembled by inserting the ground conductor 18 into the insertion hole 15 f of the lower case 15.

  In the antenna feeding portion 1, the back surface of the elastic connection plate 13 on which the coplanar line is formed is connected in contact with the coplanar line formed on the circuit board 14, and the surface of the elastic connection plate 13 is connected to the terminal portion 10c. It comes in contact with the formed coplanar line. That is, the coplanar line of the circuit board 14 and the coplanar line of the terminal portion 10c are connected by the coplanar line formed on the elastic connecting plate 13, and the film antenna 10 is mismatched via the coplanar line having the characteristic impedance. Without being connected to the coaxial cable 19. The elastic connecting plate 13 is elastic and is sandwiched between the circuit board 14 and the terminal portion 10c so that a compressive stress is applied, so that the electrical connection between the coplanar lines is ensured when sandwiched. Will be able to connect to.

  In addition, the washer 12 or the circuit board 14 is sandwiched, and the film antenna 10 comes out of the antenna feeding portion 1 even if the projections 15a and 15b and the insertion holes 10d and 10e are pulled by vibration or strong force. This can be prevented. The ground conductor 18 inserted into the insertion hole 15f of the lower case 15 is in contact with the grounding portion formed on the back surface of the circuit board 14, and the antenna power feeding portion 1 is attached to the ground such as the vehicle body. At this time, the ground conductor 18 comes into contact with the ground. As a result, the grounding portion of the film antenna 10 can be connected to the ground in the antenna power feeding unit 1, and the film antenna 10 can be operated stably. Furthermore, the ground part formed on the front surface of the circuit board 14 and the ground part formed on the back surface are electrically connected by a through hole or the like. The ground conductor 18 may be elastic.

The electrical characteristics of the antenna feeder 1 according to the first embodiment of the present invention described above are shown in FIGS.
FIG. 5 is a Smith chart showing S11 (reflection coefficient on the input side) in the S parameter, and shows the impedance characteristic on the input side. The input side impedance characteristic shown in FIG. 5 shows an input impedance from 100 MHz to about 1600 MHz, and it can be seen that a good impedance characteristic of about 50Ω is obtained with reference to FIG.
FIG. 6 is a graph showing the frequency characteristic of the S parameter S21 (forward transmission characteristic), showing the transmission loss characteristic from 100 MHz to approximately 1600 MHz. With reference to FIG. 6, the transmission loss is set to approximately 0 dB. I understand that.

FIG. 7 is a Smith chart showing S22 (reflection coefficient on the output side) in the S parameter, and shows the impedance characteristic on the output side. The impedance characteristic on the output side shown in FIG. 7 shows an output impedance from 100 MHz to approximately 1600 MHz, and it can be seen that a favorable impedance characteristic of approximately 50Ω is obtained with reference to FIG.
FIG. 8 is a graph showing the frequency characteristic of the S parameter S22 (reflection coefficient on the output side). The frequency characteristic of the voltage standing wave ratio (VSWR) from 100 MHz to approximately 1600 MHz is shown, see FIG. Then, it can be seen that the VSWR is about 1.6 or less.
From FIG. 5 to FIG. 8, when the antenna feeding unit 1 connects the film antenna 10 having a characteristic impedance of 50Ω on the input side and the coaxial cable 19 having the characteristic impedance of 50Ω on the output side, Impedance matching makes it possible to reduce the transmission loss to almost 0 db. The electrical characteristics shown in FIGS. 5 to 8 are characteristics when the characteristic impedance of the coplanar lines formed on the terminal portion 10c, the elastic connection plate 13 and the circuit board 14 is about 50Ω.

  In the antenna feeding portion 1 according to the first embodiment of the present invention described above, the terminal portions 10c of the film antenna 10 and the coplanar lines formed on the circuit board 14 are connected to each other via the elastic connecting plate 13. However, the elastic connecting plate 13 may be omitted, and the terminal portions 10c of the film antenna 10 and the coplanar lines formed on the circuit board 14 may be directly connected to each other. Further, at least the terminal portion 10c of the film antenna 10 and the circuit board 14 are accommodated in the upper case 11 and the lower case 15, and the upper case 11 is fixed to the lower case 15 so as to compress them from above and below. Instead, at least the terminal portion 10c of the film antenna 10 and the circuit board 14 may be fixed so that the coplanar lines are connected to each other by screwing means or caulking means.

  The configuration of the antenna feeding unit according to the second embodiment of the present invention is shown in FIGS. However, FIG. 9 is an exploded view showing the configuration of the antenna power feeding part of Example 2 of the present invention, and FIG. 10 is a perspective view with the upper case showing the configuration of the antenna power feeding part of Example 2 of the present invention removed. FIG. 11 is a top view with the upper case showing the configuration of the antenna power feeding unit of the second embodiment of the present invention removed, and FIG. 12 is a cross-sectional side view showing the configuration of the antenna feeding unit of the second embodiment of the present invention. FIG.

  The antenna feeding unit 2 according to the second embodiment of the present invention shown in these drawings is an antenna feeding unit capable of electrically connecting the coaxial cable 29 without mismatching with the glass antenna, and includes an upper case 21 and a lower case 25. The antenna feeding structure is housed in the case. Although not shown, the glass antenna 5 is configured by forming an antenna element and a ground element on a glass plate such as a windshield or rear glass of a vehicle body so as to have a predetermined characteristic impedance. The antenna element and the earth element of the glass antenna 5 are provided on a glass plate by sticking or vapor-depositing a conductive foil having a predetermined width and a predetermined length. As shown in FIG. 13, a terminal portion 5 a is formed at one end of the glass antenna 5. The terminal portion 5a is formed of a coplanar line having a characteristic impedance of 50Ω, for example, and a glass antenna 5 made of an earth element and an antenna element having a characteristic impedance that matches impedance with the coplanar line is connected.

  A coaxial cable 29 having a predetermined characteristic impedance to which the glass antenna 5 is connected is connected to the circuit board 24. For example, a coplanar line pattern having a characteristic impedance of 50Ω is formed on the front surface of the circuit board 24, and a core wire and a ground portion of a coaxial cable 29 having a characteristic impedance matching impedance are connected to the coplanar line. ing. On the back surface of the circuit board 24, a ground to which the ground portion of the coplanar line is connected is formed on the entire surface. Further, a pair of positioning insertion holes 24 a are formed at the tip of the circuit board 14.

  For example, a coplanar line having a characteristic impedance of 50Ω formed on the terminal part 20b of the terminal fitting 20 having a U-shaped cross section is connected to the coplanar line formed on the terminal part 5a of the glass antenna 5. In this case, the coplanar line formed on the planar main body portion 20a on the lower surface of the terminal portion 20b of the terminal fitting 20 is connected to the terminal portion 5a of the glass antenna 5 by soldering or the like. Further, in the terminal portion 20b of the U-shaped terminal fitting 20, a coplanar line is formed from the main body portion 20a on the lower surface to the upper surface via the side surface, and a pair of positioning insertion holes for positioning are provided in the terminal portion 20b. 20c and 20d are formed. The coplanar line formed on the upper surface of the terminal portion 20 b and the coplanar line formed on the circuit board 24 are connected by the elastic connection plate 23. The elastic connecting plate 23 is made of a highly elastic elastomer such as silicon rubber and has the same configuration as the elastic connecting plate 13 shown in FIG. That is, the coplanar line having a characteristic impedance of 50Ω, for example, is configured by alternately arranging the conductive layers 23b and the insulating layers 23c. For the conductive layer 23b, the fine metal wires are oriented with high density in the thickness direction of the elastic connecting plate 23, the metal particles or the carbon particles are mixed in the elastomer, or the fine metal wires are arranged on the surface of the elastomer at a low pitch. It is comprised by. The insulating layer 23c is made of an insulating elastomer. The elastic connection plate 23 is formed with a pair of positioning insertion holes 23a for positioning.

  The lower case 25 is shaped like a half of a rectangular box, and a pair of protrusions 25a and 25b are formed in the interior thereof. The pair of protrusions 25 a are inserted into the insertion holes 24 a of the circuit board 24, the insertion holes 23 a of the elastic connection plate 23, and the insertion holes 20 c of the terminal fitting 20. Further, the fitting insertion hole 20d in the terminal portion 20b of the terminal fitting 20 is fitted into the pair of protrusions 25b. On both side surfaces of the long side of the lower case 25, bearing portions 25c are formed, on which the first engagement pieces 26 and the second engagement pieces 27 are engaged respectively. One of the remaining side surfaces is formed with a cable outlet hole 25d through which the coaxial cable 29 is led out, and a slit opening 25e into which the terminal portion 20b of the terminal fitting 20 is introduced is formed on the opposite side surface. Yes. Further, a rectangular insertion hole 25f into which a rectangular ground conductor 28 is inserted is formed on the lower surface of the lower case 25.

  A pair of fitting recesses 21a and 21b are formed in the upper case 21 fitted to the lower case 25, respectively. The pair of fitting recesses 21 a are recesses into which the tips of the protrusions 25 a are fitted when fitted into the lower case 25. The pair of fitting recesses 21b are recesses into which the tips of the projections 25b are fitted when fitted into the lower case 25. Furthermore, a pair of engagement protrusions 21c are formed on both sides of the upper case 21 so that the first engagement piece 26 and the second engagement piece 27 are engaged when the lower case 25 is fitted. .

  The first engagement piece 26 and the second engagement piece 27 are formed with shaft portions 26 a and 27 a protruding on both sides, and the shaft portions 26 a and 27 a are formed on both sides of the lower case 25. Each is fitted in a rotatable manner. Engaging claws 26b and 27b are formed at the distal ends of the first engaging piece 26 and the second engaging piece 27 along the axial direction. The engaging claws 26b and 27b rotate the first engaging piece 26 and the second engaging piece 27 which are fitted to the lower case 25 so that the upper case 21 is fitted to the bearing portion 25c. When this occurs, the engaging protrusion 21c of the upper case 21 is engaged, whereby the lower case 25 and the upper case 21 are integrated. Thus, the lower case 25 and the upper case 21 can be integrated and separated by a simple operation.

  Here, the assembly procedure of the antenna power feeding unit 2 will be described. First, the circuit board 24 is accommodated in the lower case 25 while the insertion holes 24a are inserted into the pair of protrusions 25a of the lower case 25. At this time, the coaxial cable 29 is led out from the cable lead-out hole 25d. Next, the elastic connection plate 23 is accommodated in the lower case 25 while fitting the insertion holes 23 a into the pair of protrusions 25 a of the lower case 25 so as to be superimposed on the circuit board 24. Further, the insertion hole 20c is inserted into the pair of protrusions 25a of the lower case 25 and the insertion hole 20d is inserted into the pair of protrusions 25b so that the upper surface of the terminal portion 20b is superimposed on the elastic connection plate 23. The terminal portion 20 b of the terminal fitting 20 is accommodated in the lower case 25. At this time, the upper surface of the terminal portion 20b is introduced from the slit opening 25e.

  Next, the insulating washer 12 is housed in the lower case 25 while fitting the insertion holes 22a into the pair of protrusions 25a of the lower case 25 so as to be superimposed on the terminal portion 20b. Then, the upper case 21 is fitted into the lower case 25. At this time, the tips of the pair of protrusions 25a of the lower case 25 are fitted into the fitting recess 21a, and the tips of the pair of projections 25b are fitted into the fitting recess 21b. Further, the first engagement piece 26 and the second engagement piece 27 are fitted to the bearing portion 25c of the lower case 25 so as to be rotatable, and the engagement protrusion 21c of the upper case 21 is engaged with the engagement claw. 26b and 27b are engaged. Thereby, the lower case 25 and the upper case 21 are reliably integrated, and the circuit board 24 is sandwiched in a state where the washer 22 and the elastic connection plate 23 are compressed by the upper case 21 and the lower case 25. Become. Then, the antenna power feeding unit 2 is assembled by inserting the ground conductor portion 28 into the insertion hole 25f of the lower case 25.

  In this antenna feeding portion 2, the back surface of the elastic connection plate 23 on which the coplanar line is formed is connected in contact with the coplanar line formed on the circuit board 24, and the surface of the elastic connection plate 23 is connected to the terminal portion 20b. It comes in contact with the formed coplanar line. That is, the coplanar line formed on the elastic connecting plate 23 connects the coplanar line of the circuit board 24 to the coplanar line of the terminal portion 20b of the terminal fitting 20, and the lower surface of the terminal portion 20b of the terminal fitting 20 is a glass antenna. By soldering to the terminal portion 5a, the glass antenna 5 is connected to the coaxial cable 29 through the coplanar line having characteristic impedance without mismatching.

  In addition, the washer 22 or the circuit board 24 is sandwiched, and the terminal fitting 20 is pulled out from the antenna feeding portion 2 even if the projections 25a and 25b and the fitting insertion holes 20c and 20d are pulled by vibration or strong force. This can be prevented. The elastic connecting plate 23 has elasticity and is sandwiched between the circuit board 24 and the terminal portion 20b so that a compressive stress is applied, so that the electrical connection between the coplanar lines is ensured when sandwiched. Will be able to connect to. Note that the ground conductor portion 28 inserted into the insertion hole 25f of the lower case 25 is in contact with the ground portion formed on the back surface of the circuit board 24, and the antenna feeding portion 2 is attached to the ground such as the vehicle body. At this time, the ground conductor 28 comes into contact with the ground. As a result, the grounding portion of the glass antenna 5 can be connected to the ground in the antenna power feeding unit 2, and the glass antenna 5 can be operated stably. The ground part formed on the front surface of the circuit board 24 and the ground part formed on the back surface are electrically connected by a through hole or the like. Further, the ground conductor 28 may be elastic.

  The electrical characteristics of the antenna feeder 2 according to the second embodiment of the present invention described above are substantially the same as those of the antenna feeder 1 according to the first embodiment of the present invention shown in FIGS. That is, when the characteristic impedance of the coplanar lines formed on the terminal portion 20b, the elastic connection plate 23 and the circuit board 24 is approximately 50Ω, the impedance characteristics on the input side and the output side from 100 MHz to approximately 1600 MHz are approximately A good impedance characteristic of 50Ω is obtained, and the transmission loss is almost 0 dB. Also, the VSWR from 100 MHz to approximately 1600 MHz is a good VSWR of about 1.6 or less. As described above, the antenna feeder 2 according to the second embodiment of the present invention is connected to the glass antenna 5 having a characteristic impedance of 50Ω on the input side and the coaxial cable 29 having the characteristic impedance of 50Ω on the output side. , The transmission loss can be reduced to approximately 0 db by impedance matching.

  In the antenna feeding unit 2 according to the second embodiment of the present invention described above, the terminal 20b of the terminal fitting 20 and the coplanar lines formed on the circuit board 24 are connected to each other via the elastic connecting plate 23. However, the elastic connecting plate 23 may be omitted, and the terminal portions 20b of the terminal fitting 20 and the coplanar lines formed on the circuit board 24 may be directly connected to each other. Further, at least the terminal portion 20b of the terminal fitting 20 and the circuit board 24 are accommodated in the upper case 21 and the lower case 25, and the upper case 21 is fixed to the lower case 25 so as to compress them from above and below. Instead, at least the terminal portion 20b of the terminal fitting 20 and the circuit board 24 may be fixed so that the coplanar lines are connected by screwing means or caulking means.

  The configuration of the antenna feeding unit according to the third embodiment of the present invention is shown in FIGS. 15 is an exploded view illustrating the configuration of the antenna feeding unit according to the third embodiment of the present invention, and FIG. 16 is a diagram illustrating the configuration of the circuit board in the antenna feeding unit according to the third embodiment of the present invention. 17 is a perspective view with the upper case showing the configuration of the antenna power feeding part of Example 3 of the present invention removed, and FIG. 18 is a top view with the upper case showing the structure of the antenna power feeding part of Example 3 of the present invention removed. FIG. 19 is a cross-sectional view showing a side view of the configuration of the antenna power feeding unit according to the third embodiment of the present invention.

  The antenna feeding unit 3 according to the third embodiment of the present invention shown in these drawings is an antenna feeding unit that can electrically connect the coaxial cable 39 without mismatching with the glass antenna. The antenna feeding structure is housed in the case. Although not shown, the glass antenna 6 is configured by forming an antenna element and a ground element so as to have a predetermined characteristic impedance on a glass plate such as a windshield or rear glass of a vehicle body. The antenna element and the earth element of the glass antenna 6 are provided on a glass plate by sticking or vapor-depositing a conductive foil having a predetermined width and a predetermined length. As shown in FIG. 14, one end of the glass antenna 6 is projected to form a terminal portion 6a. The terminal portion 6a is composed of, for example, a coplanar line having a characteristic impedance of 50Ω, and a glass antenna 6 composed of an antenna element having a characteristic impedance that matches impedance with the coplanar line and a ground element is connected.

  A coaxial cable 39 having a predetermined characteristic impedance to which the glass antenna 6 is connected is connected to the circuit board 34. For example, a coplanar line pattern having a characteristic impedance of 50Ω is formed on the front surface of the circuit board 34, and a core wire and a ground portion of a coaxial cable 39 having a characteristic impedance matching impedance are connected to the coplanar line. ing. A coplanar line is formed on the back surface of the circuit board 34 in the same manner as the front surface, and the coplanar lines on the front surface and the back surface are connected to each other by a through hole or the like.

  The elastic connection plate 33 is connected to the coplanar line formed on the terminal portion 6 a of the glass antenna 6. The elastic connecting plate 33 is made of an elastic elastomer such as silicon rubber and has the same configuration as the elastic connecting plate 13 shown in FIG. That is, a coplanar line having a characteristic impedance of, for example, 50Ω is configured by alternately arranging the conductive layers 33b and the insulating layers 33c. For the conductive layer 33b, the fine metal wires are oriented with high density in the thickness direction of the elastic connecting plate 33, the metal particles or carbon particles are mixed in the elastomer, or the fine metal wires are arranged at a low pitch on the surface of the elastomer. It is comprised by. The insulating layer 33c is made of an insulating elastomer. The elastic connection plate 33 is inserted into a first insertion hole 35a formed in a lower case 35 described later.

  The lower case 35 is shaped like a semi-rectangular box, and a lower surface of the lower case 35 has a first insertion hole 35a into which the elastic connection plate 33 is inserted and a second insertion hole into which the ground conductor 38 is inserted. 35e is formed. On both side surfaces of the long side of the lower case 35, bearing portions 35b and 35c are formed, on which the first engagement piece 36 and the second engagement piece 37 are rotatably engaged, respectively. One of the remaining side surfaces is formed with a cable lead-out hole 35d through which the coaxial cable 39 is led out. The first engagement piece 36 and the second engagement piece 37 formed on the lower case 35 are formed with shaft portions 36a and 37a projecting on both sides, and the shaft portions 36a and 37a are formed on both sides of the lower case 35. The bearing portions 35b and 35c are formed so as to be rotatable. Engaging claws 36b and 37b are formed at the distal ends of the first engaging piece 36 and the second engaging piece 37 along the axial direction.

  On both sides of the upper case 31 fitted to the lower case 35, a pair of engagement protrusions to which the first engagement piece 36 and the second engagement piece 37 are engaged when fitted to the lower case 35. A portion 31c is formed. When the upper case 31 is fitted to the lower case 35 and the first engagement piece 36 and the second engagement piece 37 that are rotatably fitted to the bearing portions 35b and 35c are rotated, The engaging claws 36b and 37b come to engage with the engaging protrusion 31c of the upper case 31, so that the lower case 35 and the upper case 31 are integrated. Thus, the lower case 35 and the upper case 31 can be integrated and separated by a simple operation.

  Here, the assembly procedure of the antenna power feeding unit 3 will be described. First, the elastic connection plate 33 is inserted into the first fitting insertion hole 35a of the lower case. Next, the circuit board 24 is accommodated in the lower case 35. Then, the upper case 31 is fitted to the lower case 35, and the first engagement piece 36 and the second engagement piece 37 are fitted and rotated to the bearing portions 35b and 35c of the lower case 35, The engaging claws 36 b and 37 b are engaged with the engaging protrusions 31 c of the upper case 31. As a result, the lower case 35 and the upper case 31 are reliably integrated, and the circuit board 34 is sandwiched in the case composed of the upper case 31 and the lower case 35. Further, the antenna power feeding portion 3 is assembled by inserting the ground conductor portion 38 into the second insertion hole 35 e of the lower case 35.

  The antenna feeding portion 3 assembled in this way is fixed on the glass plate with a double-sided tape or the like by aligning the elastic connecting plate 33 and the terminal portion 6a of the glass antenna 6. Accordingly, the back surface of the elastic connection plate 33 on which the coplanar line is formed is connected in contact with the coplanar line formed on the terminal portion 6 a of the glass antenna 6, and the surface of the elastic connection plate 33 is the back surface of the circuit board 34. It comes into contact with the coplanar line formed on the cable. That is, the coplanar line formed on the elastic connection plate 33 connects the coplanar line formed on the circuit board 34 and the coplanar line formed on the terminal portion 6a of the glass antenna 6 so that the glass antenna 6 has a characteristic impedance. It is connected to the coaxial cable 39 through the coplanar line having

  The elastic connecting plate 33 has elasticity and a compressive stress is applied by the circuit board 34, so that the coplanar lines can be reliably electrically connected. The ground conductor 38 inserted in the second insertion hole 35e of the lower case 35 is in contact with the ground portion of the coplanar line formed on the back surface of the circuit board 34, and the antenna feeder 3 is connected to the vehicle body or the like. When attached to the ground, the ground conductor 38 comes into contact with the ground. As a result, the grounding portion of the glass antenna 6 can be connected to the ground in the antenna power feeding portion 3, and the glass antenna 6 can be stably operated. The coplanar lines formed on the front surface and the back surface of the circuit board 34 are electrically connected by a through hole or the like. Further, the ground conductor 38 may be elastic.

  The electrical characteristics of the antenna feeding unit 3 according to the second embodiment of the present invention described above are substantially the same as those of the antenna feeding unit 1 according to the first embodiment of the present invention shown in FIGS. That is, when the characteristic impedance of the coplanar lines formed on the elastic connecting plate 33 and the circuit board 34 is about 50Ω, the impedance characteristics on the input side and the output side from 100 MHz to about 1600 MHz are good impedances of about 50Ω. The transmission loss is almost 0 dB. Also, the VSWR from 100 MHz to approximately 1600 MHz is a good VSWR of about 1.6 or less. As described above, the antenna feeder 3 according to the third embodiment of the present invention is connected to the glass antenna 6 whose characteristic impedance is 50Ω on the input side and the coaxial cable 39 whose characteristic impedance is 50Ω on the output side. , The transmission loss can be reduced to 0 db by impedance matching.

  In the antenna feeding unit 3 according to the third embodiment of the present invention described above, the elastic connection plate 33 and the circuit board 34 are accommodated in the upper case 31 and the lower case 35. Instead, the elastic connection plate 33 and the circuit are provided. The substrate 34 may be fixed so that the coplanar lines are connected to each other by screwing means or caulking means.

  In the above description, the antenna feeding portion of the film antenna or the glass antenna used for the vehicle is described. However, the present invention is not limited to the antenna feeding portion of the film antenna or the glass antenna used for the vehicle. The present invention can be applied to an antenna feeding portion of an antenna formed on the substrate.

1 is an exploded view illustrating a configuration of an antenna power feeding unit according to a first embodiment of the present invention. It is the top view which removed the upper case which shows the structure of the antenna electric power feeding part of Example 1 of this invention. It is a figure which shows the side view which shows the structure of the antenna electric power feeding part of Example 1 of this invention with sectional drawing. It is a figure which shows the structure of the elastic connection board concerning the antenna electric power feeding part of Example 1 of this invention. It is a Smith chart which shows S11 (reflection coefficient on the input side) in S parameter concerning the antenna electric power feeding part of Example 1 of this invention. It is a graph which shows the frequency characteristic of S21 (forward transmission characteristic) of S parameter concerning the antenna electric power feeding part of Example 1 of this invention. It is a Smith chart which shows S22 (reflection coefficient of an output side) in S parameter concerning the antenna electric power feeding part of Example 1 of this invention. It is a graph which shows the frequency characteristic of S22 (output side reflection coefficient) of S parameter concerning the antenna electric power feeding part of Example 1 of this invention. It is an exploded assembly figure which shows the structure of the antenna electric power feeding part of Example 2 of this invention. It is the perspective view which removed the upper case which shows the structure of the antenna electric power feeding part of Example 2 of this invention. It is the top view which removed the upper case which shows the structure of the antenna electric power feeding part of Example 2 of this invention. It is a figure which shows the side view which shows the structure of the antenna electric power feeding part of Example 2 of this invention with sectional drawing. It is a figure which shows the structure of the terminal part of the glass antenna concerning the antenna electric power feeding part of Example 2 of this invention. It is a figure which shows the structure of the terminal part of the glass antenna concerning the antenna electric power feeding part of Example 2 of this invention. It is an exploded assembly figure which shows the structure of the antenna electric power feeding part of Example 3 of this invention. It is a figure which shows the structure of the circuit board concerning the antenna electric power feeding part of Example 3 of this invention. It is the perspective view which removed the upper case which shows the structure of the antenna electric power feeding part of Example 3 of this invention. It is the top view which removed the upper case which shows the structure of the antenna electric power feeding part of Example 3 of this invention. It is a figure which shows the side view which shows the structure of the antenna electric power feeding part of Example 3 of this invention with sectional drawing. It is a top view which shows the structure of the conventional antenna electric power feeding part in a film antenna. It is a side view which shows the structure of the conventional antenna electric power feeding part in a film antenna. It is a top view which shows the structure of the other conventional antenna electric power feeding part in a film antenna. It is a side view which shows the structure of the other conventional antenna electric power feeding part in a film antenna.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Antenna electric power feeding part 2 Antenna electric power feeding part 3 Antenna electric power feeding part 5 Glass antenna 5a Terminal part 6 Glass antenna 6a Terminal part 10 Film antenna 10a Antenna element 10b Earth element 10c Terminal part 10d Fitting insertion hole 10e Fitting insertion hole 11 Upper case 11a Fitting Concave part 11b Fitting concave part 11c Engaging protrusion part 12 Washer 12a Fitting insertion hole 13 Elastic connecting plate 13a Fitting insertion hole 13b Resin plate 13c Conductor bar 14 Circuit board 14a Fitting insertion hole 15 Lower case 15a Protruding part 15b Protruding part 15c Bearing part 15d Cable outlet hole 15e Slit opening 15f Insertion hole 16 First engagement piece 16a, 17a Shaft part 16b, 17b Engagement claw 17 Second engagement piece 18 Ground conductor part 19 Coaxial cable 20 Terminal fitting 20a Main body part 20b Terminal Part 20c Insertion hole 20 Fitting hole 21 Upper case 21a Fitting recess 21b Fitting recess 21c Engaging protrusion 22 Washer 22a Fitting insertion hole 23 Elastic connection plate 23a Fitting insertion hole 24 Circuit board 24a Fitting insertion hole 25 Lower case 25a Projection 25b Projection 25c Bearing portion 25d Cable lead-out hole 25e Slit opening portion 25f Insertion hole 26 First engagement piece 26a, 27a Shaft portion 26b, 27b Engagement claw 27 Second engagement piece 28 Ground conductor portion 29 Coaxial cable 31 Upper case 31c Engagement Joint protrusion 33 Elastic connection plate 34 Circuit board 35 Lower case 35a Insertion hole 35b, 35c Bearing part 35d Cable lead-out hole 35e Insertion hole 36 First engagement piece 36a, 37a Shaft part 36b, 37b Engagement claw 37 Second Engagement piece 38 Ground conductor 39 Coaxial cable 100 Film antenna 100a Terminal 1 0b reinforcing plate 101 substrate 102 connector 103 coaxial cable 110 cable 110a cable

Claims (13)

An antenna feeder that can connect a cable with impedance matching to a film antenna,
A terminal portion where a coplanar line having characteristic impedance in the film antenna is formed and a substrate from which a cable on which the coplanar line having characteristic impedance is formed are overlapped so that the coplanar lines are connected to each other. An antenna feeding portion characterized in that the antenna feeding portion is fixed. Claim 1, said substrate and said terminal portion, characterized in that the connecting coplanar line which connects between the coplanar line is fixed polymerized to via an elastic connection plate being formed with having a characteristic impedance The antenna feeding unit described.   The substrate, the elastic connection plate, and the terminal portion are sandwiched and housed in a case composed of a lower case and an upper case, and formed on the substrate, the elastic connection plate, and the terminal portion. The antenna feeding portion according to claim 2, wherein a protrusion that is inserted into the positioning insertion hole is formed in the lower case. The conductor connecting the ground portion of the line to the ground is inserted into an insertion hole provided in the lower case, and is exposed on the lower surface of the lower case. 3. The antenna feeding unit according to 3 . An antenna feeder that can connect a cable with impedance matching to an antenna formed on an insulating plate,
A line having a characteristic impedance is formed from the upper surface of the U-shaped terminal fitting to the lower surface through the side surface, and the line formed on the lower surface of the terminal fitting is formed in the terminal portion of the antenna. The lines are connected to each other by being superposed on a line having a characteristic impedance, and the line formed on the upper surface of the terminal fitting is formed on the substrate from which the cable is derived. An antenna feeding unit, wherein the antenna feeding unit is superposed on a line having an impedance and fixed so that the lines are connected to each other. Said substrate and said terminal portion, of claim 5, wherein a connection line for connecting the line is fixed polymerized to via an elastic connection plate being formed with having a characteristic impedance Antenna feed section. 6. The antenna feeder according to claim 5, wherein the line is a coplanar line. The substrate, the elastic connection plate, the terminal portion, and the upper side of the terminal metal fitting are sandwiched and housed in a case composed of a lower case and an upper case, the substrate, the elastic connection plate, 7. The antenna according to claim 6 , wherein a protrusion that is inserted into a positioning insertion hole formed on the terminal portion and an upper side of the terminal fitting is formed on the lower case. Power supply unit. The conductor connecting the ground portion of the line to the ground is inserted into an insertion hole provided in the lower case, and is exposed on the lower surface of the lower case. 8. The antenna feeding unit according to 8 . An antenna feeder that can connect a cable with impedance matching to an antenna formed on an insulating plate,
An elastic connecting plate on which a connection line having characteristic impedance is formed can be connected to a terminal portion where a line having characteristic impedance in the glass antenna is formed, and the line having characteristic impedance is connected to the front surface and the back surface. The board from which the cable formed in the cable is led is superposed and fixed to the elastic connection plate, and the line in the antenna and the line in the board can be connected by the connection line. The antenna power feeding part. The antenna feeder according to claim 10, wherein the line and the connection line are coplanar lines. The substrate is housed in a case made up of a lower case and an upper case, and the elastic connection plate is inserted into a first insertion hole provided in the lower case, so that the lower surface of the lower case The antenna feeding portion according to claim 10 , wherein the antenna feeding portion is provided so as to be exposed. A conductor that connects the ground portion of the line on the substrate to the ground is inserted into a second insertion hole provided in the lower case, and is exposed on the lower surface of the lower case. The antenna feeding unit according to claim 12 , wherein the antenna feeding unit is characterized in that:

Images