JP4962106B2 - Antenna cable - Google Patents

Description

  The present invention relates to an antenna cable that is detachably connected to a mobile terminal such as a mobile phone and an external antenna.

  For example, a mobile phone is equipped with a camera function, various information terminal functions, and the like as well as a call function as a standard, and is positioned as a general mobile terminal device from a simple call means. The mobile phone is also equipped with a function as a receiving terminal for digital radio broadcasting, FM broadcasting, or terrestrial digital television broadcasting, for example, and is also used in a mode in which a broadcast music program received by connecting an earphone code is enjoyed. The

  In portable terminals, an earphone cord is provided with an antenna function, and so-called earphone antennas are used to improve the broadcast program reception characteristics by wideband characteristics. However, in such an earphone antenna, there is a problem that a high frequency characteristic is remarkably deteriorated when a part of the earphone cord touches the human body in a usage state. For example, as disclosed in Patent Documents 1 to 3, there is a problem with the human body. Measures are taken to prevent influence by using a coaxial cable at the contact site.

  Patent Document 1 is based on the applicant of the present application, and constitutes a sleeve antenna structure in which an inner conductor of a coaxial cable drawn from a portable terminal is extended from an end of an outer conductor and is excited by the drawn inner conductor and outer conductor. Audio signals and high frequency signals (hereinafter referred to as RF signals) are superimposed and transmitted. Patent Document 2 discloses that at least one signal line is connected to a broadcast receiving circuit via an audio signal line by connecting to an earphone connector portion of a portable terminal, and the signal line is halfway (3 from the connection end). A high-frequency cutting circuit that cuts off the RF signal is provided at the (4λ position), and the tip portion that often comes into contact with the human body is cut as an antenna line. Further, in Patent Document 3, an earphone cord and a portable terminal are connected by a coaxial cable having a remote controller (intermediate part: remote controller) configured as an antenna line, and a first high-frequency attenuation element and a second are connected inside the remote controller. A high-frequency cutting circuit is configured with a high-frequency attenuating element, and the tip portion is cut as an antenna line to reduce the influence of the human body.

Japanese Patent Laid-Open No. 2005-64742 JP 2006-25392 A Japanese Patent No. 3851339

  In the conventional earphone antenna, as described above, by providing a high-frequency cutting circuit that cuts off or attenuates the RF component by connecting an element such as an inductor that increases the high-frequency impedance to the audio signal line in series in the middle of the cable, The RF characteristics are improved by avoiding the influence of the human body. However, the conventional earphone antenna has a problem that the audio characteristic is deteriorated because an element such as an inductor of the high frequency cutting circuit has a DC resistance.

  That is, in the high frequency cutting circuit, an inductor having an impedance as high as possible in a predetermined frequency band is used to cut off the RF component in the transmission line. In the high-frequency cutting circuit, the impedance of the series inductance is expressed by Z = j2πfL, and the larger the value of L, the larger the impedance becomes, so that the RF component can be cut off and the RF signal transmission efficiency is improved. On the other hand, the high frequency cutting circuit has a problem that the transmission resistance of the audio signal transmitted through the audio signal line is lowered because the conductor resistance value increases and the DC resistance increases as the inductance increases. It was.

  In the conventional earphone antenna, as described above, the high-frequency cutting circuit provided in the middle of the cable is configured by mounting an inductor on a wiring board, for example, and a coaxial cable or an earphone cord is connected to the wiring board. Therefore, the conventional earphone antenna has a problem that a large relay portion is formed in the middle, the cord is not routed, and the usability is reduced and the cost is increased.

  In the earphone antennas disclosed in Patent Literature 2 and Patent Literature 3, a plurality of parallel litz wires for transmitting audio signals independently from each other are used as signal lines of a coaxial cable, and each of these parallel litz wires is an RF signal line. Are combined into one signal line. Therefore, in the earphone antenna, a high-frequency cutting circuit is provided for an audio R channel signal line and an L channel signal line other than the RF signal transmission line (for example, a ground line). Become.

  Further, in such an earphone antenna, a full length of a sufficient length cannot be effectively used as an antenna element by cutting a portion where there is much contact with the human body with a high frequency cutting circuit. In the earphone antenna, since a high-frequency cutting circuit is provided at a position where an RF signal in a predetermined band resonates, there is a problem that the antenna characteristics of the RF signal in a lower frequency band than that of the RF signal are greatly deteriorated. . When the earphone antenna is configured for, for example, a digital radio broadcast band (190 MHz), the reception characteristics of the FM radio broadcast band (70 MHz to 100 MHz), which is a low frequency band, are deteriorated, and is set for the FM radio broadcast band. However, the length of the coaxial cable becomes large. In other words, the conventional earphone antenna performs transmission by superimposing an audio signal and an RF signal, but has antenna characteristics that can efficiently receive RF signals of different frequency bands. Absent.

  Accordingly, an object of the present invention is to provide an antenna cable with a simple structure and a low-cost structure that reduces the influence of the human body and achieves an efficient antenna characteristic and achieves a wide band.

An antenna cable according to the present invention that achieves the above-described object includes a first connection portion that is detachably connected to a portable terminal, a second connection portion that is detachably connected to an antenna element, and From the high-frequency filter provided in the first connection portion, and a coaxial cable having a predetermined length whose one end side is connected to the first connection portion including the high-frequency filter and whose other end side is connected to the second connection portion. A first antenna having a resonance characteristic with respect to a first high-frequency signal based on a first reference frequency is constituted by the ground sheath of the coaxial cable, and the antenna element connected to the signal line of the coaxial cable and the signal line and, the longer the total length than the first antenna, a resonance characteristic to the second high-frequency signal than the first reference frequency based on the second reference frequency of the low band Second An antenna, said first connecting portion including the high frequency filter, the signal line pattern and a ground line pattern are connected to the signal line and ground line of the coaxial cable, and is connected to the ground line pattern that A grounding sheath of the coaxial cable constituting the first antenna is connected to the shielded wire pattern, and the high-frequency filter is disposed with respect to the signal wire and the ground wire of the coaxial cable, When the second antenna is configured, the first high-frequency signal component received by the second antenna is cut to prevent transmission to the portable terminal connected to the first connection unit, and the second antenna The second high-frequency signal received in step 1 is transmitted to the portable terminal .

  The antenna cable is a first high-frequency signal including a harmonic signal (nλ1, n = 1.2,...) Together with a high-frequency signal having a first reference frequency λ1 of, for example, 1 / 4λ1 and 1 / 2λ1, and a second reference frequency. λ2 is a second high-frequency signal including harmonic signals (nλ2, n = 1.2,...) together with high-frequency signals of, for example, 1 / 4λ2 and 1 / 2λ2 in a lower band than the first reference frequency. Resonance characteristics with respect to the high-frequency signal and the second high-frequency signal.

  The antenna cable constitutes a high frequency filter by a parallel resonance circuit of an inductor and a capacitor provided at the connection portion of the signal line of the coaxial cable connected to the high frequency connection end of the first connection portion and the ground sheath.

  The antenna cable has at least two high-frequency filters including a first high-frequency filter connected to the signal line of the first connection portion and the coaxial cable, and a second high-frequency filter connected to the ground sheath of the coaxial cable. Is provided. The antenna cable is used by selecting one of a low-pass filter, a high-pass filter, a band-pass filter, and a band-pass blocking filter as two high-frequency filters.

  Further, the antenna cable includes a pair of left and right earphones, a pair of left and right signal lines each having one of these earphones and a ground line, and a second end of the earphone cord. It is comprised by the earphone antenna comprised from the connection part provided in this.

  In the antenna cable, by configuring the first antenna using a coaxial cable that avoids the influence of the human body, the first high-frequency signal that is a high-band high-frequency signal that is greatly affected by the human body is stably and efficiently received. . In the antenna cable, the second antenna having a sufficient antenna length by effectively using the entire length of the coaxial cable and the earphone cord is configured to widen the high-frequency signal and the influence of the human body is relatively small. Efficiently transmits and receives low-band high-frequency signals.

  In the antenna cable, the second antenna having a large overall length and widening the band also receives the first high-frequency signal having a high band whose characteristics are reduced by the influence of the human body. Cut by the high frequency filter so that only the high frequency signal in the predetermined frequency band received by the first antenna is transmitted to the portable terminal. In the antenna cable, the influence of the human body is reduced and efficient antenna characteristics are achieved so that a wide frequency band can be achieved. In the antenna cable, by providing a high-frequency filter at the first connecting portion that constitutes the connecting portion with the portable terminal, the coaxial cable length and the entire length of the earphone cord can be easily routed, and the operability is improved. The structure on the portable terminal side can be simplified, and the assembly efficiency can be improved, so that it can be manufactured at low cost.

  According to the present invention, the first antenna is configured on the coaxial cable, and the second antenna is configured by connecting the coaxial cable and the antenna element. The first high-frequency signal having the resonance characteristic with respect to the first antenna and the second By providing a high-frequency filter that selects the second high-frequency signal having resonance characteristics with respect to the antenna, it is possible to improve the characteristics by widening the band and reducing the influence of the human body.

  Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings. As shown in FIGS. 1 and 4, an antenna cable 1 shown as an embodiment includes a multipolar plug portion 2 that constitutes a first connection portion, which will be described in detail later, and a high-frequency jack portion 3 that constitutes a second connection portion. And the coaxial cable 4 provided with the multipolar plug portion 2 and the high-frequency jack portion 3 at opposite ends. The antenna cable 1 is provided with a high frequency filter 5 inside the multipolar plug portion 2 to restrict the distribution of the first RF signal and the second RF signal, that is, the transmission of the RF signal.

  As shown in FIGS. 1 and 2, the antenna cable 1 is a pair of left and right earphone cords 8L and 8R constituting the mobile phone 6 and the earphone antenna 7 (hereinafter collectively referred to as an earphone cord 8 unless otherwise described). .). As shown in FIG. 2, the antenna cable 1 is used by connecting the mobile phone 6 and the earphone antenna 7 at a part away from the human body H in a use state. The antenna cable 1 is detachable with respect to the mobile phone 6 and the earphone antenna 7 as will be described in detail later, and is removed from the mobile phone 6 together with the earphone antenna 7 when it is not particularly required as in the usage mode of a call. .

  The antenna cable 1 receives, for example, a 190 MHz band (first RF signal) digital radio broadcast program and a 70 MHz to 100 MHz band (second RF signal) FM radio broadcast program with high sensitivity even when the user is moving in cooperation with the earphone antenna 7. Thus, it is possible to listen with high sound quality by the left and right earphones 9L and 9R provided on the earphone cord 8 via the mobile phone 6 (hereinafter collectively referred to as the earphone 9 unless otherwise described).

  Note that the antenna cable 1 is not limited to a usage mode in which the mobile phone 6 and the earphone antenna 7 are connected, such as a rod antenna having a connection structure with various mobile terminal devices having a receiving function such as radio broadcasting and television broadcasting. Of course, various antennas can be connected and used. The antenna cable 1 is used as a receiving antenna for RF signals in different bands as described above, but it is of course also used as a transmitting antenna.

  Although not described in detail, the mobile phone 6 is equipped with a VHF high-band digital radio tuner, a VHF / low-band FM radio tuner, and the like along with various functions such as a call function and a camera function, and the above-described digital by connecting the antenna cable 1. Radio broadcast programs and FM radio broadcast programs can be received with high sensitivity. Although not described in detail, the cellular phone 6 has a multi-pin external connection connector portion 10 in a housing, and the multipolar plug portion 2 of the antenna cable 1 is attached to and detached from the external connection connector portion 10. When the mobile phone 6 connects the antenna cable 1 to the external connector 10, this connection is detected and, for example, the output circuit is switched from the internal speaker to the earphone cord 8 or the input circuit is switched from the built-in antenna to the earphone antenna 7. Is done. The mobile phone 6 can be connected to the earphone antenna 7 as an external speaker.

  When the earphone antenna 7 is connected to the mobile phone 6 via the antenna cable 1, f1 is formed of the coaxial cable 4 of the antenna cable 1 with the housing as the ground and the connection site as the feeding point as will be described in detail later. A monopole type first antenna 11 having resonance characteristics with respect to an RF signal in a band, and a monopole type antenna having resonance characteristics with respect to an RF signal in an f2 band formed by integrating the coaxial cable 4 and the earphone antenna 7. The second antenna 12 is configured. The mobile phone 6 can listen to the high-quality sound by the earphone 9 by selecting and inputting the RF signal of the broadcast program of the two frequency bands received by the first antenna 11 and the second antenna 12 by the high-frequency filter 5. To do.

  As shown in FIGS. 2 and 3, the earphone antenna 7 is formed by integrating an earphone cord 8 with individual earphone cords 8LA and 8RA on the distal end side provided with earphones 9L and 9R on one end side at a coupling portion 8C. A multipolar plug body 13 is provided on the other end side of the integrated earphone cord 8D. The earphone antenna 7 is connected to the antenna cable 1 by inserting the multipolar plug body 13 into the multipolar jack section 3. In the embodiment where the antenna cable 1 is not used, the earphone antenna 7 is used by removing the multipolar plug body 13 from the antenna cable 1 and directly connecting to the multipolar jack portion provided in the mobile phone 6 or various portable terminals. Is also possible.

  The earphone antenna 7 is connected to the coaxial cable 4 and is electrically integrated to form the second antenna 12 as a whole, thereby efficiently receiving the second RF signal in the low frequency band that is less influenced by the human body H. It functions as an antenna for FM radio broadcasting. The earphone antenna 7 has resonance characteristics with respect to the second RF signal in the FM radio broadcasting band in cooperation with the coaxial cable 4 and efficiently receives the RF signal. For convenience, for example, the length a of the individual earphone cord 8LA is 140 mm. The length b of the individual earphone cord 8RA is 450 mm, and the length c of the integrated earphone cord 8D is 1050 mm.

  Each of the earphone cords 8 has two signal lines 14 as shown in FIG. That is, the L channel-side earphone cord 8L includes an L channel audio signal line 14L and an L channel ground line 14LG. The R channel earphone cord 8R also has signal lines of an R channel audio signal line 14R and an R channel ground line 14RG. In the earphone cord 8, the channel audio signal lines 14L and 14R are independently connected to the L channel terminal 13L and the R channel terminal 13R of the multipolar jack body 13, and the ground lines 14LG and 14RG are connected to the ground terminal 13G. Connected in common.

  The earphone antenna 7 configured as described above converts an L channel audio signal output from the mobile phone 6 side through the antenna cable 1 described later into an L channel audio signal line 14L and an L channel ground line 14LG of the earphone cord 8. And output from the L channel earphone 9L. The earphone antenna 7 transmits the R channel audio signal through the R channel audio signal line 14R and the R channel ground line 14RG and outputs it from the R channel earphone 9R.

  The earphone antenna 7 is connected to the coaxial cable 4 of the antenna cable 1 as will be described in detail later, and is a monopole second antenna having a connection point with the mobile phone 6 via the coaxial cable 4 as a feeding point. 12 is configured. The earphone antenna 7 functions as an RF signal line in which each signal line 14 has a large overall length in cooperation with the coaxial cable 4 and constitutes an antenna for receiving an FM radio broadcast program in a 70 MHz to 100 MHz band. Since the earphone antenna 7 has a large overall length, it receives a part of a high-band RF signal that is affected by the human body H. However, as will be described later, the mobile phone is provided by the high-frequency filter 5 of the antenna cable 1. The transmission to 1 is cut.

  The antenna cable 1 has a so-called 10-pin plug specification in which the multipolar plug portion 2 matches the specification of the external connection connector portion 10 on the mobile phone 6 side. As shown in FIG. 4, the multipolar plug portion 2 has an insulating case 15, and a wiring board 16 that also serves as a terminal board is accommodated in the insulating case 15. A high frequency filter 5, which will be described in detail later, is mounted on the wiring board 16. As will be described in detail later, the wiring board 16 has appropriate L-channel signal line pattern 17L, R-channel signal line pattern 17R, and ground line pattern 17G to which the respective signal lines 20 of the coaxial cable 4 are connected. A pattern 17 is formed.

  As shown in FIG. 4, the wiring board 16 has a side portion where a terminal portion is formed by drawing out each wiring pattern 17 and is exposed from the insulating case 15 so as to be fitted to the external connection connector portion 10 on the mobile phone 6 side. Configure. The wiring board 16 is formed with the above-described wiring patterns 17 and a shield line pattern 17S to which a shielded sheath wire 22 of the coaxial cable 4 described later is connected. The shield line pattern 17S is connected to the ground line pattern 17G. In addition, although illustration is abbreviate | omitted in the wiring board 16, the pattern for a connection detection etc. are formed.

  The antenna cable 1 has a cylindrical insulating sleeve 18 in which the high-frequency jack portion 3 has an insertion opening into which the multipolar plug body 13 of the earphone antenna 7 is inserted on one side, although details are omitted as shown in FIG. The connection terminal 19 is provided inside the insulating sleeve 18. As shown in FIG. 1, the connection terminal 19 includes an L channel connection terminal 19L, an R channel connection terminal 19R, and a ground connection terminal 19G. Provided. The high-frequency jack unit 3 is connected to the earphone antenna 7 by connecting the connection terminals 19L, 19R, and 19G to the opposing terminals 13L, 13R, and 13G, respectively, by inserting the multipolar plug body 13 from the insertion port.

  As shown in FIGS. 1 and 4B, the antenna cable 1 includes a coaxial cable 4 having three signal lines 20 including an L channel signal line 20L, an R channel signal line 20R, and a ground signal line 20G. The insulation coating 21 that covers the signal lines 20, the shield sheath wire 22, and the insulation sheath 23 are configured. The coaxial cable 4 constitutes a first antenna 11 that efficiently receives a first RF signal of a 190 MHz band (f1 band) digital radio broadcast program with the multipolar plug portion 2 as a feeding point. The coaxial cable 4 is set to about 430 mm in length, which is a quarter wavelength of the RF signal in the f1 band, in order to efficiently resonate with the first RF signal in the f1 band.

  In the coaxial cable 4, the L channel signal line 20 </ b> L is connected to the L channel signal line pattern 17 </ b> L of the wiring board 16 on the multipolar plug part 2 side and to the L channel connection terminal 19 </ b> L on the high frequency jack part 3 side. In the coaxial cable 4, the R channel signal line 20 </ b> R is connected to the R channel signal line pattern 17 </ b> R of the wiring board 16 on the multipolar plug part 2 side and to the R channel connection terminal 19 </ b> R on the high frequency jack part 3 side.

  In the coaxial cable 4, the ground signal line 20G is connected to the ground line pattern 17G on the multipolar plug part 2 side and to the ground connection terminal 19G on the high frequency jack part 3 side. The coaxial cable 4 is connected to a shielded wire pattern 17S that connects the shielded skin wire 22 to the ground wire pattern 17G of the wiring board 16 by peeling off the insulation skin 23 and exposing the shielded skin wire 22 on the multipolar plug portion 2 side. To do.

  The coaxial cable 4 configured as described above is connected to the mobile phone 6 and the earphone antenna 7 via the multipolar plug portion 2 and the high frequency jack portion 3, and the L channel audio signal output from the mobile phone 6 side. The R channel audio signal is transmitted to the earphone cord 8 via each signal line 20 and output from the earphone 9.

  The coaxial cable 4 has a shield outer sheath wire 22 that is electrically open on the high frequency jack portion 3 side, and constitutes the monopole first antenna 11 having the multipolar plug portion 2 as a feeding point as described above. The digital radio broadcast program is received by resonating with the RF signal in the 190 MHz band. The coaxial cable 4 constitutes a part of the second antenna 12 having a large overall length by connecting each signal line 20 to the antenna cable 7 as described above.

  In the antenna cable 1, the high-frequency filter 5 is configured by a parallel resonance circuit of an inductor 24 and a capacitor 25 provided on a ground line pattern 17 </ b> G formed on the wiring board 16 of the multipolar plug portion 2 as shown in FIG. 1. The high frequency filter 5 passes the audio signal output from the mobile phone 6 side, transmits the audio signal to the earphone cord 8 via the coaxial cable 4, and outputs the audio signal from the earphone 9. As the high-frequency filter 5, an inductor 24 and a capacitor 25 having characteristics described later are used, and an RF signal received by the second antenna 12 configured by the coaxial cable 4 and the earphone antenna 7 together with the above-described audio signal passing function. The predetermined frequency band component is selected and transmitted to the mobile phone 6 side.

  By the way, since the impedance ZL of the inductor 24 is ZL = j2πL and the impedance ZC of the capacitor 25 is ZC = j2πC in the parallel resonance circuit of the inductor 24 and the capacitor 25 described above, the impedance Z is equal to the impedance ZL of the inductor 24 and the capacitor. The parallel impedance of 25 impedances ZC is represented by Z = 1 / (1 / ZL + 1 / ZC). Therefore, in the parallel resonance circuit, the resonance frequency f at which the impedance Z becomes infinite is represented by f = 1 / (2π (√LC)).

  The high-frequency filter 5 is configured by a parallel resonant circuit in which an inductor 24 and a capacitor 25 having predetermined characteristic specifications are appropriately combined, thereby preventing band-passing that cuts an RF signal component in the f1 band from the RF signal received by the second antenna 12. A filter (BEF) is configured. As described above, the high-frequency filter 5 allows a low-band 70 MHz to 100 MHz band RF signal that is relatively less affected by the human body H to pass through and transmit the RF signal to the mobile phone 6 side. The first RF signal is cut to prevent transmission to the mobile phone 6 side.

  The high-frequency filter 5 is configured by a parallel resonant circuit in which an inductor 24 and a capacitor 25 are connected in parallel to the ground line pattern 17G. However, the present invention is not limited to such a mounted component. The high frequency filter 5 may be a chip component in which the functions of the inductor 24 and the capacitor 25 are integrated into one chip. The high-frequency filter 5 can also form the functions of the inductor 24 and the capacitor 25 in the layer by using the wiring substrate 16 as a multilayer substrate.

  In the antenna cable 1, the first RF signal (f1) in the high frequency band that is easily affected by the human body H as described above is received by the first antenna 11 including the coaxial cable 4 that reduces the influence of the human body H, and the human body. The second antenna 12 having a large total length including the coaxial cable 4 and the earphone antenna 7 in which the antenna characteristics are deteriorated by touching H is also received. In the antenna cable 1, the first RF signal received on the second antenna 12 side is cut by the high-frequency filter 5 set to the above-described function. In the antenna cable 1, this prevents characteristic deterioration due to mutual interference with the first RF signal received by the first antenna 11.

  As described above, the antenna cable 1 includes the high-frequency filter 5 configured by the parallel resonance circuit of the inductor 24 and the capacitor 25, and cuts the first RF signal component of the predetermined frequency band f1 from the RF signal received by the second antenna 12. . In the antenna cable 1, an inductor 24 having a small inductance value and a high-capacitance capacitor 25 constitute a parallel resonance circuit, thereby ensuring an impedance sufficient to cut a high-frequency component in a predetermined frequency band.

  In the antenna cable 1, the high frequency filter 5 is provided in the multipolar plug portion 2 that constitutes the feeding point of each antenna, whereby the line length of the antenna is effectively utilized. Further, in the antenna cable 1, the inductor 24 and the capacitor 25 can be easily mounted to reduce the cost by simplifying the assembly process and reducing the number of parts. (Reduction) is facilitated, and the routing including the earphone antenna 7 is facilitated and the usability is improved.

  In the antenna cable 1, the RF signal received by the first antenna 11 is transmitted to the mobile phone 6 by controlling (selecting) the passage of the RF signal received by the second antenna 12 by the high-frequency filter 5 as described above. Antenna characteristics are improved by suppressing interference with signals. In addition, the antenna cable 1 can be provided with the high frequency filter 5 to reduce the inductance as an audio signal line and to reduce the DC resistance component, thereby reducing the audio characteristics (sound pressure level, L channel signal and R channel signal). Of high sound quality and low power consumption.

  In the conventional earphone cord, as described above, a pair of signal lines using litz wires or the like are accommodated in the outer skin in a parallel state, so that each signal line is coupled at a high frequency. Therefore, in the earphone cord, when the RF signal is cut off, a high frequency cut-off circuit must be provided for all signal lines. On the other hand, in the antenna cable 1, the first antenna 11 is configured by using the shield outer sheath wire 22 of the coaxial cable 4 and the signal line 20 constituting the audio signal line as the antenna signal line. In the antenna cable 1, it is necessary to provide a high-frequency cutoff circuit for each signal line 20 due to the characteristics of the coaxial cable 4 in which the insulation between the shielded sheath wire 22 and the signal line 20 is sufficiently maintained and is difficult to couple as a high frequency. There is no simple configuration. The antenna cable 1 has a structure in which the shielded outer sheath wire 22 of the coaxial cable 4 is physically opened so that the RF signal does not easily flow to the earphone cable 8, and the transmission of the RF signal in the predetermined frequency band f1 is cut.

  In the antenna cable 1, as described above, it is possible to secure a sufficient conductor area by using the shielded sheath wire 22 of the coaxial cable 4 made of a mesh wire as an antenna wire, and the conductor resistance value of the high-frequency signal line is reduced. Thus, the radiation efficiency of the antenna is improved or the loss is reduced. In the antenna cable 1, the signal line 20 shielded as described above constitutes a signal line for an audio signal, thereby reducing external noise. In the antenna cable 1, by using the coaxial cable 4, it is possible to manage the high frequency impedance at the time of manufacturing the electric wire, and the characteristic variation is reduced.

  In the mobile phone 6, when the first RF signal antenna and the second RF signal antenna are used separately, connection terminals (feeding terminals) for connecting the antennas are required and the matching circuit is complicated. In the antenna cable 1, as described above, the coaxial cable 4 and the earphone cable 8 are integrated and detached from the external connection connector unit 10, thereby simplifying the matching circuit and reducing the number of parts on the mobile phone 6 side. Reduce costs. Since the antenna cable 1 has a structure in which the high-frequency filter 5 is built in the multipolar plug portion 2 constituting the antenna feeding terminal through which the most current flows, the filter function is exhibited to the maximum.

  The antenna cable 1 is used by being connected to the mobile phone 6 and the earphone antenna 7, so that the casing of the mobile phone 6 is grounded as shown in FIGS. 5A and 5B, and the multipolar plug portion 2 is used. A composite antenna having a first antenna 11 and a second antenna 12 having resonance characteristics with RF signals in different bands with the feed point as a feed point is configured. Specifically, the antenna cable 1 includes a first antenna 11 that receives (transmits) the first RF signal in the frequency band f1 as shown in FIG. 5C, and a first antenna 11 other than the frequency band f1 shown in FIG. The 2nd antenna 12 which receives (transmits) 2RF signal is comprised.

  In the antenna cable 1, as described above, the high-frequency filter 5 is provided on the feeding point side of the second antenna 12 to constitute a band pass blocking filter. The high frequency filter 5 does not function as a high frequency cutoff circuit when f ≠ f1, functions as an inductor L when f <f1, and functions as a capacitor C when f> f1. The high frequency filter 5 is configured using, for example, an inductor 24 having an inductance of 68 nH and a capacitor 25 having a capacitance of 10 pF. As is clear from the S11 characteristic diagram shown in FIG. 6 and the S21 characteristic diagram shown in FIG. 7, the high frequency filter 5 has an infinite impedance at the resonance frequency f1 = 192 MHz, and cuts the first RF signal in the f1 band.

  The antenna cable 1 is shown in FIG. 8 and FIG. 9 by connecting a mobile phone 6 and an earphone antenna 7 and forming a first antenna 11 and a second antenna 12 whose RF signal transmission is controlled by a high frequency filter 5. Show the characteristics. In contrast, FIG. 10 shows the characteristics of an earphone antenna configured with a general litz wire. In the antenna cable 1, the first antenna 11 configured by the coaxial cable 4 in FIGS. 8 and 9 has the characteristics indicated by f 1, and the second antenna 12 configured by the coaxial cable 4 and the earphone antenna 7 has the characteristics indicated by f 2. Have. Therefore, the antenna cable 1 can improve the antenna gain by about 10 dB in the f1 band as compared with the conventional earphone antenna.

  In the above-described embodiment, the antenna cable 1 that connects the mobile phone 6 and the earphone antenna 7 to receive the digital radio broadcast program in the 190 MHz band and the FM radio broadcast program in the 70 MHz to 100 MHz band with high sensitivity. Of course, the present invention is not limited to such an antenna cable 1. The antenna cable 1 can be used by connecting to various mobile terminals instead of the mobile phone 6 as described above, and can also be used by forming a second antenna by connecting to an appropriate antenna such as a rod antenna. You may do it.

  Even when the antenna cable 1 is used by being connected to various antennas, the first RF signal is efficiently received by the first antenna 11 that resonates with the entire length of the coaxial cable 4, and the second antenna is connected between the coaxial cable 4 and the connection antenna. To increase the bandwidth and efficiently receive the second RF signal. In the antenna cable 1, regardless of which antenna is used, the first RF signal is received by the first antenna 11 in which the influence of the human body H is avoided, and the second antenna 12 has a lower frequency band than the first RF signal. The second RF signal is used so as to be received.

  In the antenna cable 1, the coaxial cable 4 is set to a predetermined length to change the resonance frequency f1 of the first antenna 11, and the LC constant by the inductor 24 and the capacitor 25 constituting the high frequency filter 5 is appropriately set. It is also possible to easily cut the RF signal of the changed band f1. In the antenna cable 1, for example, the resonance frequency f1 of the first antenna 11 can be easily changed from a 190 MHz band digital radio broadcast antenna to a higher band 470 MHz to 870 MHz band UHF television broadcast antenna. It is.

  In the antenna cable 1, as described above, by setting the LC constant by the inductor 24 and the capacitor 25, the resonance frequency f <b> 1 set by the length of the coaxial cable 4 by the high frequency filter 5 is set to the resonance frequency of the second antenna 12. It functions as a band pass blocking filter (BEF) that cuts off the transmission of the RF signal to f1. Therefore, in the antenna cable 1, as described above, the first RF signal in the high band of the resonance frequency f1 is resonated and received by the first antenna 11 formed of the shielded sheath wire 22 of the coaxial cable 4, and the band of the resonance frequency f1 is received. The second external RF signal is received by the second antenna 12 constituted by the coaxial cable 4 and the earphone antenna 7.

  The antenna cable 1A shown in FIG. 11 is configured as a low-pass filter (LPF) in which the high-frequency filter 5 sets the LC constant by the inductor 24 and the capacitor 25 as appropriate to set the reference frequency to f1. In the antenna cable 1A, the high frequency filter 5 passes (cuts) a low-band RF signal with respect to the reference frequency as shown by an arrow in the figure so as to resonate and transmit (receive) the second antenna 12. To do. In the antenna cable 1A, the high frequency filter 5 cuts (passes) an RF signal in a band higher than the reference frequency by the high frequency filter 5 and causes the first antenna 11 to resonate and transmit (receive) the RF signal.

  The antenna cable 1B shown in FIG. 12 is configured as a high-pass filter (HPF) in which the high-frequency filter 5 sets the LC constant by the inductor 24 and the capacitor 25 as appropriate to set the reference frequency to f1. In the antenna cable 1B, the high frequency filter 5 passes (cuts) a high-band RF signal with respect to the reference frequency as shown by an arrow in the figure, and resonates with the second antenna 12 to transmit (receive) it. To do. In the antenna cable 1A, the high frequency filter 5 cuts (passes) an RF signal in a low band with respect to the reference frequency, and resonates with the first antenna 11 to transmit (receive) it.

  By the way, in an antenna cable that can receive RF signals in different frequency bands by connecting a mobile terminal such as the mobile phone 6 and an antenna such as the earphone antenna 7, a coaxial cable is used to reduce the influence of the human body H. Ideally, an RF signal is passed through the four shield sheath wires 22. However, in the case of an antenna cable, when receiving an RF signal having a shorter wavelength than the coaxial cable 4 having a length of ¼ wavelength, it may be more efficient to flow the signal cable 20 than the shielded sheath wire 22. .

  In the above-described embodiment, the high-frequency filter 5 that selects and transmits the predetermined frequency component of the second RF signal received by the second antenna 12 configured by the coaxial cable 4 and the earphone antenna 7 to the mobile phone 6 is provided. The present invention is also applied to the antenna cable 30 shown as the second embodiment in FIGS. 13 and 14, for example. Since the antenna cable 30 has the same basic configuration as the antenna cable described above, the corresponding parts are denoted by the same reference numerals and description thereof is omitted.

  As shown in FIG. 14, the antenna cable 30 is basically provided with a first high-frequency filter 31 connected to the signal line 20 of the coaxial cable 4 and a second high-frequency filter 32 connected to the shield sheath wire 22. In the antenna cable 30 as well, in the embodiment shown in FIG. 13, the high-frequency filters 31 and 32 are each constituted by a parallel circuit including an inductor and a capacitor. However, the antenna cable 30 is not limited to such a high-frequency filter. In the antenna cable 30, a low-pass filter, a high-pass filter, a band-pass filter, and a band-pass blocking filter are selected as the first high-frequency filter 31 and the second high-frequency filter 32, respectively. Various antennas can be configured by combining the first antenna 11 and the second antenna 12 having the above.

  In the antenna cable 30, the second high-frequency filter 32 is mounted on the wiring board 33 in parallel with the first high-frequency filter 31, and the first RF filter 31 controls the second RF signal received (transmitted) by the above-described second antenna 12. And the second RF filter 32 controls the first RF signal received (transmitted) by the first antenna 11 so that more efficient antenna characteristics can be obtained. The first high-frequency filter 31 is also composed of a parallel resonant circuit including a first inductor 34 and a first capacitor 35 provided on the ground line pattern 17G, as with the high-frequency filter 5 described above.

  As described above, the antenna cable 30 is formed with the shield line pattern 17S for connecting the shield outer sheath wire 22 of the coaxial cable 4 to the wiring board 33 of the multipolar plug portion 2, and as shown in FIG. The second high frequency filter 32 comprising a parallel resonant circuit of the second inductor 36 and the second capacitor 37 is provided. That is, the antenna cable 30 is connected to the shielded sheath wire 22 of the coaxial cable 4 connected in parallel to the first high frequency filter 31 provided in the ground line pattern 17G connected to the ground signal line 20G of the coaxial cable 4. A second high-frequency fill 32 is provided on the shield line pattern 17S. The second high-frequency filter 32 is not limited to the one constituted by the above-described parallel resonance circuit of the inductor and the capacitor because it does not constitute an audio signal transmission path.

  In the antenna cable 30, the LC constant by the first inductor 34 and the first capacitor 35 constituting the first high frequency filter 31 and the LC constant by the second inductor 36 and the second capacitor 37 constituting the second high frequency filter 32 are appropriately determined. Is set. In the antenna cable 30, depending on the LC constant of the first high-frequency filter 31 and the LC constant of the second high-frequency filter 32, whether an RF signal in a necessary frequency band is sent to the shielded sheath wire 22 or the signal line 20 of the coaxial cable 4. A multi-function antenna is selected.

  In the antenna cable 30, the first high-frequency filter 31 has a low-pass filter (LPF) that passes a low-band signal and a high-pass filter that passes a high-band signal (resonance frequency f1 set by the length of the coaxial cable 4). HPF), a band pass filter (BPF) that passes a signal in a predetermined band, or a band pass blocking filter (BEF) that cuts a signal in a predetermined band. In the antenna cable 30, the second high frequency filter 32 is caused to function as LPF, HPF, BPF, or BEF in the same manner.

  The antenna cable 30A shown in FIG. 15 uses a BEF that cuts the first RF signal of the resonance frequency f1 toward the second antenna 12 as the first high-frequency filter 31, and the first RF of the resonance frequency f1 as the second high-frequency filter 32. A BPF that allows a signal to pass through is used. In the antenna cable 30A, the first RF signal having the band of the resonance frequency f1 is resonated and received by the first antenna 11, and the second RF signal outside the resonance frequency f1 is resonated and received by the second antenna 12.

  The antenna cable 30B shown in FIG. 16 uses, as the first high-frequency filter 31, an LPF that passes an RF signal having a band lower than the resonance frequency f1 toward the second antenna 12, and the second high-frequency filter 32 is connected to the resonance frequency f1. It is configured using an HPF that allows a higher-band RF signal to pass therethrough. In the antenna cable 30B, the first RF signal having a band higher than the band of the resonance frequency f1 is resonated and received by the first antenna 11, and the second RF signal having a band lower than the band of the resonance frequency f1 is received. Resonate with the second antenna 11 for reception.

  The antenna cable 30 </ b> C shown in FIG. 17 uses an HPF that passes an RF signal having a higher band than the resonance frequency f <b> 1 toward the second antenna 12 as the first high-frequency filter 31, and the resonance frequency f <b> 1 as the second high-frequency filter 32. It is configured using an HPF that passes an RF signal of a lower band than that. In the antenna cable 30B, a first RF signal having a band lower than the band of the resonance frequency f1 is received by being resonated by the first antenna 11, and a second RF signal having a band higher than the band of the resonance frequency f1 is received. Resonate with the second antenna 11 for reception.

  The antenna cable 40 shown in FIG. 18 as the third embodiment includes a high frequency filter 41 that selects a predetermined frequency component of the second RF signal received by the second antenna 12 and transmits the selected frequency component to the mobile phone 6. Is the same as the antenna cable 1 described above, but the high-frequency filter 41 is composed of a plurality of high-frequency filters 41 (41A, 41B). In the antenna cable 40, these high frequency filters 41 are configured by appropriately combining the filters having the above functions, and the second RF signal received by the second antenna 12 is multistaged by the first high frequency filter 41A and the second high frequency filter 41B. Control.

  The antenna cable 40 uses, for example, a BEF that cuts an RF signal having a resonance frequency f1 toward the second antenna 12 as the first high-frequency filter 41A, and a resonance frequency toward the second antenna 12 as the second high-frequency filter 41B. A BEF that cuts the RF signal of f2 is used. In the antenna cable 40, a first RF signal having a resonance frequency f1 band and a resonance frequency f2 band is resonated and received by the first antenna 11, and a second RF signal outside the resonance frequencies f1, f2 is received by the second antenna 12. Resonate and receive.

  The antenna cables shown as the above-described embodiments are connected to the mobile phone 6 and the earphone cord 8 to receive a 190 MHz band digital radio broadcast program and a 70 MHz to 100 MHz band FM radio broadcast program, and the left and right earphones. Although 9L and 9R are used for listening with high sound quality, it is needless to say that the present invention is not limited to such two frequency band RF signals. In the antenna cable, the coaxial cable 4 and the earphone antenna 7 are appropriately selected to efficiently transmit and receive the first RF signal and the second RF signal in different bands.

  The antenna cable can be applied to the harmonic signal as the first RF signal (f1) as well as the 1 / 4λ1 and 1 / 2λ1 RF signals with respect to the target reference RF signal of λ1. The antenna cable can be applied to the harmonic signal as well as the 1 / 4λ1 and 1 / 2λ1 RF signals with respect to the reference RF signal of λ2 as the second RF signal (f2). The antenna cable includes a first antenna 11 having resonance characteristics with respect to the first RF signal and a second antenna 12 having resonance characteristics with respect to the second RF signal, thereby achieving a wide band and improving the antenna characteristics. Like that.

  Note that the present invention combines the above-described second embodiment in which high-frequency filters are connected to the first antenna 11 and the second antenna 12, respectively, and the third embodiment in which multi-stage high-frequency filters are provided. Of course, you may make it comprise a cable.

It is a block diagram of the application example which connected the mobile telephone and the earphone antenna using the antenna cable shown as the 1st Embodiment of this invention. It is explanatory drawing of the use condition of an antenna cable. It is explanatory drawing of the earphone antenna connected with an antenna cable. It is a principal part top view of an antenna cable. It is explanatory drawing of the antenna comprised by connecting a mobile telephone and an earphone antenna using an antenna cable, The figure (A) is a connection figure of each part, The figure (B) is an antenna block diagram, The figure (C ) Is the first antenna diagram, and FIG. 4D is the second antenna diagram. It is a S11 characteristic figure of an antenna for explaining a function of a high frequency filter. It is a S21 characteristic view of the antenna. It is a S11 characteristic figure of the antenna comprised by connecting a mobile telephone and an earphone antenna using an antenna cable. It is a frequency band gain measurement figure in the use condition of the antenna. It is a characteristic view in the use condition of the conventional earphone antenna. It is explanatory drawing of the antenna which set the high frequency filter of the antenna cable to the low-pass filter function. It is explanatory drawing of the antenna which set the high frequency filter of the antenna cable to the high pass filter function. It is a block diagram of the application example which connected the mobile telephone and the earphone antenna using the antenna cable shown as the 2nd Embodiment of this invention. It is explanatory drawing of the antenna cable. It is explanatory drawing of the antenna which set the 1st high frequency filter provided in the 2nd antenna side of an antenna cable to a band pass blocking filter function, and set the 2nd high frequency filter provided in the 1st antenna side to a band pass filter function. . It is explanatory drawing of the antenna which set the 1st high frequency filter provided in the 2nd antenna side of an antenna cable to a low pass filter function, and set the 2nd high frequency filter provided in the 1st antenna side to a high pass filter function. It is explanatory drawing of the antenna which set the 1st high frequency filter provided in the 2nd antenna side of an antenna cable to a high pass filter function, and set the 2nd high frequency filter provided in the 1st antenna side to a low-pass filter function. It is explanatory drawing of the application example which connected the mobile telephone and the earphone antenna using the antenna cable which connected the high frequency filter shown as the 3rd Embodiment of this invention in multiple stages.

Explanation of symbols

  1 antenna cable, 2 multipolar plug, 3 high frequency jack, 4 coaxial cable, 5 high frequency filter, 6 mobile phone, 7 earphone antenna, 8 earphone cord, 9 earphone, 10 external connection connector, 11 first antenna, 12 Second antenna, 13 Multi-polar plug body, 14 Audio signal line, 16 Wiring board, 17 Wiring pattern, 20 Signal line, 21 Insulating coating, 22 Shielded skin wire, 23 Insulating skin, 24 Inductor, 25 Capacitor, 30 Antenna cable, 31 1st high frequency filter, 32 2nd high frequency filter, 33 wiring board, 34 1st inductor, 35 1st capacitor, 36 2nd inductor, 37 2nd capacitor, 40 antenna cable

Claims (5)

A first connection unit detachably connected to the mobile terminal;
A second connection portion detachably connected to the antenna element;
A high-frequency filter provided in the first connection portion;
One end side is connected to the first connection portion including the high-frequency filter, and the other end side is configured from a coaxial cable of a predetermined length connected to the second connection portion,
A ground antenna of the coaxial cable constitutes a first antenna having a resonance characteristic for a first high-frequency signal based on a first reference frequency, and the signal line of the coaxial cable and the antenna element connected to the signal line, A second antenna having a resonance characteristic with respect to a second high-frequency signal based on a second reference frequency that is longer than the first antenna and is lower than the first reference frequency ;
The first connection part including the high-frequency filter includes:
The signal line pattern and the ground line pattern connected to the signal line and the ground line of the coaxial cable, and the shield line pattern connected to the ground line pattern, and the shield antenna includes the first antenna. The ground sheath of the coaxial cable is connected,
The high frequency filter
Arranged for the signal line and ground line of the coaxial cable,
When the second antenna is configured, the first high-frequency signal component received by the second antenna is cut to prevent transmission to the portable terminal connected to the first connection unit,
An antenna cable that transmits the second high-frequency signal received by the second antenna to the portable terminal . The high frequency filter,
2. The antenna cable according to claim 1, wherein the antenna cable is provided between a connection between the ground line pattern of the first connection part and a ground line of the coaxial cable, and a connection part between the ground line pattern and the shield line pattern. . The high frequency antenna cable filter according to claim 1 or 2 RF filter is further connected to cut the second high-frequency signal of the to the second antenna side in series. A second high frequency filter is connected to the shield line pattern of the first connection portion;
The second high frequency filter is
The antenna cable according to claim 1 , wherein the antenna cable has a filter characteristic that allows the first high-frequency signal to pass therethrough or a filter characteristic that allows a high-frequency signal in a higher band than the first high-frequency signal to pass . The high frequency filter disposed with respect to the signal line and the ground line of the coaxial cable of the first connection portion,
The audio signal output from the mobile terminal is passed through and transmitted to the antenna element via the coaxial cable,
The antenna element is
A pair of left and right earphones, a pair of left and right signal lines and ground lines provided at one end of each of these earphones, and a connecting portion provided at the other end of the earphone cord. An earphone antenna,
The antenna cable according to any one of claims 1 to 4, wherein the connection portion is detachable from the second connection portion.

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