Background of the Invention Many radiotelephones employ retractable antennas, i.e., antennas which are extendable and retractable out of the radiotelephone housing. The retractable antennas are electrically connected to a signal processing circuit positioned on an internally disposed printed circuit board. In order to optimally operate, the signal processing circuit and the antenna should be interconnected such that the respective impedances are substantially "matched", i.e., electrically tuned to filter out or compensate for undesired antenna impedance components to provide a 50 Ohm impedance value at the circuit feed.

Unfortunately, complicating such a matching system, a retractable antenna by its very nature has dynamic components, i.e., components which move or translate with respect to the housing and the printed circuit board and as such does not generally have a single

impedance value. Instead, the retractable antenna typically generates largely different impedance values when in an extended versus a retracted position.

Therefore, it is preferred that the impedance matching system alter the antenna's impedance to properly match the terminal's impedance both when the antenna is retracted and extended.

The physical configuration of the matching network is further complicated by the miniaturization of the radiotelephone and the internally disposed printed circuit board. Many of the more popular hand- held telephones are undergoing miniaturization.

Indeed, many of the contemporary models are only 11-12. centimeters in length. Because the printed circuit board is disposed inside the radiotelephone, its size is also shrinking, corresponding to the miniaturization of the portable radiotelephone. Unfortunately, as the printed circuit board decreases in size, the amount of space which is available to support desired operational and performance parameters of the radiotelephone is generally correspondingly reduced. Therefore, it is desirable to efficiently and effectively utilize the limited space in the radiotelephone and on the printed circuit board.

This miniaturization can also create complex mechanical and electrical connections with other components such as the outwardly extending retractable antenna which must generally interconnect with the housing for mechanical support, and, as discussed above, to an impedance matching system operably associated with the printed circuit board in order for the signal to be processed.

Referring to Figures 1A and lB, desired equivalent circuits 10, 10' are illustrated for extended and retracted antenna positions, respectively.

As shown, in Figure lA, in the extended position the antenna rod 12 operates with a half-wave (X/2) load.

In this situation, the associated impedance may rise as high as 600 Ohms. In contrast, in the retracted position, as shown in Figure lB, the antenna rod 12 operates with a quarter-wave (X/4) load with an impedance typically near 50 Ohms. Therefore, when the antenna is in the extended position an L-C matching circuit 15 may be needed.

In the past, conventional portable radiotelephones have used a variety of antenna connections to match the impedance in the antenna to the housing and the printed circuit board. For example, U.S. Patent No. 5,374,937 to Tsunekawa et al. proposes downwardly spaced-apart contacts or terminals on the printed circuit board in the radiotelephone housing which act to engage with or short out of the associated matching network. Unfortunately and disadvantageously, this type of switching connection can employ a number of discrete switching components such as wiping contacts and additionally may use an undesirable amount of space on the printed circuit board. Further, this configuration can limit the operational bandwidth of the radiotelephone.

One alternative is described in a co-pending patent application, entitled "Radiotelephones with Antenna Matching Switching System Configurations" by Gerard J. Hayes and Howard E. Holshouser, identified by Attorney Docket No. 8194-73. This system employs transversely spaced-apart circuit and antenna contacts to reduce the amount of space on the printed circuit board needed to operate the matching system. However, the system employs a number of discrete components in the switching assembly and interconnection of the antenna to the circuit board of the device.

Objects and Summary of the Invention It is therefore a first object of the present invention to provide matching systems which reduce the

number of switching contacts and discrete components used to generate a retractable antenna matching system.

It is another object of the present invention to employ a top loaded half wave monopole retractable antenna in a way which reduces the number of discrete components used to match the antenna's associated impedances.

It is yet another object of the present invention to reduce the number of wiping contacts and separate switches and to reduce the amount of printed circuit board space necessary to operate a retractable antenna matching system.

It is a further object of the present invention to increase the operational bandwidth of the radiotelephone.

It is yet another object of the present invention to decrease the number of discrete components needed to operate a matching system.

It is a still further object of the present invention to provide an economical and easy to manufacture antenna and housing configuration which incorporates a radiotelephone antenna matching system.

These and other objects are satisfied by the present invention by integrating one or more of the operational elements of a matching system into the physical configuration of the radiotelephone housing and antenna. A first aspect of the invention includes a radiotelephone with a housing and antenna configured to define one or more matching circuit components. The radiotelephone comprises a radiotelephone housing with opposing first and second ends. The first end includes a passage of a predetermined length. The passage includes at least one conducting portion thereon. The radiotelephone also includes a retractable antenna with opposing first and second ends which define a central axis through the center thereof. The antenna is slidably extendable through the passage about the

central axis between a first extended position and a second retracted position. When the antenna is in the first extended position, the housing passage and the antenna define a matching circuit therebetween.

In one embodiment, the housing and the antenna are configured such that the antenna includes an inductor positioned thereon and the antenna and the housing together define a coaxial capacitor therebetween. Therefore, advantageously, when the antenna is extended the antenna and housing define an integral matching L-C network corresponding to the increased impedance generated by the antenna-in that position.

In a preferred embodiment of the present invention, a radiotelephone, similar to the one described above, includes a retractable antenna rod which includes an outwardly extending electrical top loaded rod element configured on the first end and a first antenna conductive contact electrically connected to the top rod end. The antenna also includes an inwardly extending center conductive element with first and second ends, the first end is electrically connected to the first antenna contact. A dielectric layer is disposed around the center conductive element and defines an insulating shell thereabout. The antenna also includes a matching inductor electrically connected to the center conductive element second end and a second longitudinally extending antenna conductive contact disposed on the second end of the antenna.

Correspondingly, the radiotelephone housing includes a passage formed therethrough configured to receive the retractable antenna therein. The passage includes an inwardly extending surface. The housing comprises a ground clip having first, second, and third segments. The first segment is disposed on the housing passage surface and has opposing first and second ends

and extends a predetermined distance into the housing passage. The second segment extends normal to the central axis and has opposing first and second ends such that the first end is defined by the first segment second end. The third segment extends substantially parallel to the central axis and has opposing first and second ends such that the first end is defined by the second segment second end.

The housing also includes a grounding insert disposed away from the passage such that the insert electrically connects with the third segment second end. The housing also includes a downwardly extending electrical contact feed disposed on the outer surface of the housing passage longitudinally spaced-apart a predetermined distance from the ground clip first segment. The radiotelephone also includes a radiotelephone printed circuit board disposed in the housing adjacent the antenna. The printed circuit board is configured to receive an electrical signal from the antenna.

In operation, when the antenna is extended the antenna and the housing form integrated inductive and capacitive matching components. The integrated matching capacitive component is defined by the antenna center conductive element, the dielectric shell, and the ground clip. The integrated matching inductive component is defined by the antenna matching inductor.

Advantageously, this matching system does not require separate wiping contacts or discrete switching components.

An additional aspect of the present invention is a matching system with an integral capacitor. In operation, the antenna conductive portions and the housing conductive portions are aligned to define an integrated capacitor when the antenna is extended.

Preferably, the radiotelephone antenna includes a longitudinally extending central conductive element

surrounded by an insulating dielectric layer. The central conductive element is connected with the electrical load of the antenna. The housing further includes a cylindrical ground clip in electrical contact with a portion of the passage. Thus, when the antenna is extended, the integrated capacitor is defined by the alignment of the antenna center element and the ground clip.

The foregoing and other objects and aspects of the present invention are explained in detail in the specification set forth below.

Brief Description of the Drawings Figure 1A is a schematic representation of an equivalent circuit of a conventional extended half-wave antenna and an associated L-C matching circuit.

Figure 1B is a schematic representation of the equivalent circuit of the antenna of Figure 1A, but in a retracted position, shown as a quarter-wave stub.

Figure 2 is a partial section view of one embodiment of a matching switching system according to the present invention, with the antenna in an extended position.

Figure 3 is an enlarged fragmentary view of the matching system illustrated in Figure 2, but with the antenna in a retracted position.

Figure 4 is a cutaway view of a radiotelephone with a preferred embodiment of a matching system according to the present invention.

Figure 5 is a schematic representation of one embodiment of an antenna according to the present invention.

Figure 6 is an enlarged assembly view of one embodiment of a radiotelephone and antenna of the present invention.

Figure 7 is an enlarged fragmentary exploded view of a preferred embodiment of an antenna rod and housing of the present invention.

Description of Preferred Embodiments The present invention will now be described more fully hereinafter with reference to the accompanying figures, in which preferred embodiments of the invention are shown. This invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. Like numbers refer to like elements~ throughout.

Generally described, as illustrated in Figures 4 and 6, the present invention is directed towards radiotelephones 20 with retractable antennas 22 and housings 25. Preferably, the radiotelephone 20 employs a top load electrical antenna rod 23 that operates as a half wave in the extended position and a quarter wave stub (helical spiral) in the retracted position. Of course, the invention is not limited to this antenna load as alternative antenna configurations can also be employed in the instant invention. For example, an antenna load which has an integer multiple of a half-wave length, or a coil, disc or other type antenna load element.

The radiotelephone housing 25 and antenna 22 are configured to provide one or more matching circuit components, i.e., a matching system 28 which has different circuit paths and associated impedances corresponding to predetermined positions of the translating antenna 22, i.e., corresponding to the retracted or extended position of the antenna 22 relative to the radiotelephone housing 25. It will be appreciated that when the antenna 22 is extended, a major portion of the body is outside of the housing 30; in contrast, when the antenna 22 is retracted, a major

portion of the antenna 22 is positioned inside the radiotelephone housing 25. In operation, the antenna 22 extends in and out of the housing passage 30 (Figures 2 and 3) along the central axis 50 and engages with the housing 25 such that different circuit paths are defined and activated by the position and alignment of the antenna 22 within the housing 25 corresponding to the retraction and extension of the antenna as will be discussed in more detail hereinbelow.

Preferably, the electrical length of the antenna 22 (typically defined by the top load element 23 and the length of the linear rod) is predsetermined.

Further preferably, the electrical length of the antenna 22 is configured to provide a half wavelength or an integer multiple of a half wavelength so that the antenna 22 resonates with the operation frequency.

The matching system 28 includes matably configured housing 28a and antenna 28b components.

The housing portion of the matching system 28a is as shown in Figure 4. In a preferred embodiment, the housing portion of the matching system 28a is positioned on the top surface of the radiotelephone 20.

Preferably, the housing portion of the matching system 28a is formed from a non-conducting substrate material.

The housing 25 includes a passage 30 formed therein which 30 extends a predetermined distance into the housing 25. The housing portion of the matching system 28a also includes a conducting ground clip 35 and spaced-apart conducting contact 40. The contact 40 is the 50 Ohm feed for the antenna 22. The contact 40 is operably associated with the printed circuit board 45 in the radiotelephone.

As shown in Figure 3, the ground clip 35 is preferably configured with first, second, and third segments 35a, 35b, 35c. The ground clip 35 is positioned in the housing 25 such that the first segment 35a is disposed substantially flush with the

passage 30. Preferably, the first segment 35a is a continuous conductive cylindrically shaped body having a constant inner diameter therearound. This configuration provides an outer plate of a matching capacitor as will be discussed further below. The second segment 35b extends normal to (transversely away from) the passage 30. The third segment 35c extends substantially parallel to the first segment 35a. The downwardly disposed end of the third segment 35c extends out of the housing 25 such that it contacts a grounded insert 65 positioned in the radiotelephone.

The conducting contact 40 is preferably positioned to be substantially flush with the contour of the passage 30. In a preferred embodiment, as illustrated in Figure 4, the contact 40 is positioned a predetermined distance into the housing passage 30 such that, unassembled, it is electrically and physically separated from the ground clip 35 and the ground insert 65.

As described above, the housing 25 and the antenna 22 are matably configured so that activation of the matching circuitry 25 occurs with the physical retraction and extension of the antenna 22. As illustrated, this configuration advantageously reduces the amount of space on the printed circuit board needed or dedicated to activate the corresponding matching circuit components.

In operation, the antenna 22 extends in and out of the housing opening 40 (Figures 4, 5, and 11) along the central axis 50. As described above, preferably, the electrical length of the antenna 22 (defined by the top load element 23 and the length of the linear rod 22) is predetermined. Further preferably, as described above, the electrical length of the antenna 22 is configured to provide a half wavelength or an integer multiple of a half wavelength

so that the antenna 22 resonates with the operation frequency.

Figure 2 shows the antenna 22 in the extended position and Figure 3 shows the antenna 22 in the retracted position. As illustrated in Figure 5, the antenna 22 includes opposing first and second ends 70, 75 and defines a central axis 50 through the center thereof. As illustrated in Figures 2 and 3, the first end 70 extends out of the housing 25 and includes the top load antenna element 23, such as a top load monopole. The antenna 22 also includes a first conducting contact portion 80 positioned below the antenna element 23. The conducting contact 80 is electrically connected to the antenna element 23.

Preferably, the antenna 22 next includes in longitudinal serial order, a center conductive element 90 surrounded by a non-conductive (insulating) dielectric shell 95, and an inductor 100. The second end 75 includes a second conducting portion 105 which remains within the housing 30 irrespective of the extension of the antenna 22. The center conductive element 90, the inductor 100, and the second conducting portion 105 are in electrical communication with the antenna element 23, preferably each component electrically contacting the adjacently positioned conducting component.

As illustrated in Figure 2, when the antenna is extended, the matching network 28 preferably includes a matching inductor (L1) and a matching capacitor (C1). In a preferred embodiment, the matching capacitor (C1) is formed by the position of the antenna 28b within the housing passage 28a, i.e., by the antenna rod 22, the ground clip 35, the center conductor 90 and dielectric shell 95. The capacitor is formed to provide about a 1/2-1 picofarad capacitance.

The first segment of the ground clip 35a forms the outer plate of the capacitor and electrically contacts

the ground insert 65. The matching inductor (L1) is formed by an inductor 100 that is wound over dielectric material 95a of the antenna rod. This inductor 100 can be provided in any number of ways, including but not limited to, physically winding, selectively etching, or plating and then machining. An exemplary winding pattern includes a 50 mil wire wrapped 3-4 turns to provide about a 15 nanohenry inductor. The center conductor and or antenna rod conducting portions are preferably formed from a Ni-Ti alloy.

As illustrated in Figure 2, when the antenna 22 is extended, the antenna second end condu-cting portion 105 contacts the housing conducting portion 40 (the 50 Ohm feed for the antenna) and the antenna rod thereby defining an extended signal path therebetween.

The antenna second conducting portion 105 also electrically contacts the inductor 100 which electrically connects with the center conductive element 90 which electrically contacts the helical spiral 23 at the top of the antenna 22.

In contrast, as illustrated by Figure 3, when retracted, the antenna first conducting contact 80 connects to the helical spiral 23 (quarter wave) at the top of the antenna rod. In this position, the antenna first conducting portion 80 also connects to the housing conducting contacts 40 creating a retracted signal path therebetween. Further, when retracted, the antenna second conducting portion 105 may be grounded in the radiotelephone directly to shift the quarter wave resonance out of the desired pass band, or alternatively, grounded through a capacitor to tune out the inductor L1. Nonetheless, in operation, a 50 Ohm feed impedance will be realized at the housing conducting contact 40.

As shown, the matching network or system 28 provides a 50 Ohm circuit contact via the housing conducting portion 40. This feed is electrically

connected with the printed circuit board or other substrate which processes the radiotelephone signal.

As shown in Figure 2, to activate the matching network or components thereof when extended, the antenna end portion 105 contacts the housing contact 40 to activate the associated matching components L1, C1. In contrast, when retracted, the antenna conducting contact portion 105 is preferably grounded. The antenna first conducting contact electrically connects with the housing contact 40 by positioning the retracted antenna 22 therebetween.

Thus, the interconnection of the contact 40 with the first or second conducting portion 80, 105 of the antenna 22 provides different signal paths to activate selected matching circuit components. Preferably, the matching circuit includes both an inductor and a capacitor, but the invention is not limited thereto.

Indeed, the integrated system can alternatively be configured to selectively match either the impedance of the inductive or the capacitive portion of the signal.

Resistive components may also be added, either external to, or integral with, the capacitive and inductive components.

Figure 7 illustrates an exploded view of the components used in a preferred embodiment of the instant invention. As shown the antenna 22 components are cylindrically shaped to form a substantially continuous constant outer diameter over the length of the antenna. The non-conducting housing passage 30 and the conducting ground insert 36 are also cylindrically shaped. Similarly, the conducting ground clip 35 is a cylindrical body and includes a circumferentially extending center segment component, i.e., is a stepped body having two longitudinally diameters and a center intermediate thereof. The conducting housing contact is a stationary ferrule 40 positioned in the housing passage 30 and having a downwardly extending length

such that it extends beyond the ground insert 36 when assembled theretogether.

As will be appreciated by those of skill in the art, the above described aspects of the present invention may be provided by hardware, software, or a combination of the above. Thus while the various components have been described as integrated elements, one or more may, in practice, be implemented by a microcontroller including input and output ports running software code, by custom or hybrid chips, by discrete components or by a combination of the above.

For example, one or more components of the matching circuit 28, can be a implemented as a programmable controller device or as a separate discrete component.

Of course, discrete circuit components and discrete matching circuits corresponding to the impedance requirements of the antenna can be employed with the integrated housing and antenna and can be mounted separately or integrated into a printed circuit board.

Similarly, the term "printed circuit board" is meant to include any microelectronics packaging substrate.

The foregoing is illustrative of the present invention and is not to be construed as limiting thereof. Although a few exemplary embodiments of this invention have been described, those skilled in the art will readily appreciate that many modifications are possible in the exemplary embodiments without materially departing from the novel teachings and advantages of this invention. Accordingly, all such modifications are intended to be included within the scope of this invention as defined in the claims. In the claims, means-plus-function clause are intended to cover the structures described herein as performing the recited function and not only structural equivalents but also equivalent structures. Therefore, it is to be understood that the foregoing is illustrative of the present invention and is not to be construed as limited to the specific embodiments disclosed, and that modifications to the disclosed embodiments, as well as other embodiments, are intended to be included within the scope of the appended claims. The invention is defined by the following claims, with equivalents of the claims to be included therein.