Patent Grant
10665939
Not Applicable
Not Applicable
This disclosure relates generally to the field of directional antennas for transmitting and/or receiving electromagnetic radiation, particularly (but not exclusively) microwave and millimeter wavelength radiation. More specifically, the disclosure relates to antennas with serial feed that transmit and/or receive a directionally shaped and steered electromagnetic beam that is formed along the path of the propagating in the feed electromagnetic signal. These antennas, commonly referred to as scanning antennas, are well-known in the art, as exemplified by U.S. Pat. Nos. 6,750,827; 6,211,836; 5,815,124; and 5,959,589, the disclosures of which are incorporated herein by reference. One class of these antennas, which may be termed dielectric waveguide fed antennas, operate in the transmit mode by the evanescent coupling of electromagnetic waves traveling in an elongate (typically rod-like) dielectric waveguide (or “feed line”) to a scanning antenna element (typically, a rotating cylinder or drum), and then radiating the coupled electromagnetic energy in directions determined by surface features of the antenna element. Conversely, in the receive mode, the electromagnetic energy received from the free space by the antenna element is coupled into and travels in the dielectric waveguide. By defining rows of scattering features, wherein the features of each row have a different period, and by rotating the antenna element around an axis that is parallel to that of the waveguide, the radiation can be directed in a plane over an angular range determined by the different periods, thereby transmitting and/or receiving a highly directional beam with a desired beam shape.
In the context of this disclosure, the term “beam shape” encompasses the beam direction, which is defined by (a) the angular location of the power peak of the transmitted/received beam with respect to at least one given axis, (b) the beam width of the power peak, and (c) the side lobe distribution of the beam power curve.
Serial-feed scanning antennas are typically restricted to the first negative order of radiating space harmonics for transforming the guided electromagnetic signal energy to a single shaped beam propagating in free space with a given set of beam shape parameters and in a given direction. The scanning ability of such antennas is thus limited to the “negative” half space, meaning, generally, the angular portion of scanning range between the signal input to the waveguide and 0°, thus excluding the “positive” half space, meaning, generally, the angular portion of the scanning range between 0° and the end of the waveguide connected to an impedance-matching load. The scanning range, in fact, also typically excludes the zero-degree direction from the beam forming/scanning due to high constructive return interference in the “stop band” near the 0° scanning angle, and the low radiation efficiency commonly associated with such antennas.
It would therefore be an advance in the field of scanning antennas to provide a serial feed antenna that addresses the above-noted problem without undue complexity and in a cost-efficient manner. In particular, it would be advantageous to provide such an antenna with the ability to allow beam scanning in both halves (i.e., “negative” and “positive”) of the scanning space.
This disclosure relates to serial feed scanning antennas that can scan in both the positive and negative halves of the scanning space or field by switching the direction of propagation of the electromagnetic signal in the feed line. Such antennas may also provide a high gain broadside beam (in the vicinity of 0°, i.e., the “stop band”) by supplying the electromagnetic signal on both sides of the feed line simultaneously, with equal amplitude. With the electromagnetic beam propagating in opposite directions with equal amplitude, the return interference becomes destructive, and the radiation efficiency in the broadside direction increases significantly. Feeding and scanning in both halves of the scanning space or field also provides for higher gains for the same angular range of the scan as compared to the gains typically achievable in known serially fed scanning antennas.
The above-described advantages are achieved in a scanning antenna system that includes a feed line having first and second ends, and a scanning antenna element disposed with respect to the feed line so that, in the transmit mode, an electromagnetic signal input to one of the first and second ends of the feed line is evanescently coupled to the antenna element, whereby the antenna element radiates the signal as a shaped beam through an angular scanning field having a negative angular scanning space and a positive angular scanning space on either side of the stop band near 0°. A switching network, operatively coupled to the feed line, switches the signal input between the first and second ends of the feed line in a controlled sequence, whereby the shaped beam radiated by the antenna element is scanned in the negative angular scanning space, the stop band, and the positive angular scanning space. The antenna system performs reciprocally in the receive mode.
Thus, a serial feed scanning antenna system in accordance with aspects of this disclosure comprises a scanning antenna element evanescently coupled to a waveguide or feed line, and a switching network operatively coupled to the feed line to switch the direction of propagation of the electromagnetic energy (signal) in the feed line during scanning in a controlled sequence so as to shape and scan the beam radiated from the antenna element in both the negative and positive angular scanning spaces of the angular scanning field. More specifically, assuming the scanning is done across angular scanning spaces on either side of 0° (the “stop band”) (as a practical example, an angular scanning field of 90° from −45° to +45°, or vice versa), the signal is directed solely to a first end of the feed line from −45° until the scan gets to the “stop band”, at which point the switching network directs the signal equally to both the first end of the feed line and an opposite second end thereof. Once the scan passes through the stop band, the switching network directs the signal solely to the second end of the feed line.
The switching network, in exemplary embodiments, includes a master switch assembly having an input terminal configured for connection to a signal source, and output terminals selectively connectable to a negative side scan switch assembly and to a positive side scan switch assembly, which direct the signal respectively to first and second opposed ends of a feed line that is evanescently coupled to a scanning antenna element. First and second output terminals of the master switch assembly are configured to direct the full signal respectively to the negative side scan switch assembly and the positive side scan switch assembly. A third output terminal of the master switch assembly is selectively connectable to both the negative side scan switch assembly and the positive side scan switch assembly simultaneously, thereby splitting the signal equally between the negative and positive side scan switch assemblies. The negative side scan switch assembly has an output terminal connected to the first end of the feed line, and the positive side scan switch assembly has an output terminal connected to the opposite second end of the feed line. The master switch assembly, the negative side scan switch assembly, and the positive side scan switch assembly are actuated in a prescribed sequence to direct all of the signal to the negative side scan switch assembly during scanning of the negative angular scanning space of the scanning field, then to direct half the signal to each of the negative and positive side scan switch assemblies while beam forming in the stop band takes place, and finally to direct all of the signal to the positive side scan switch assembly while scanning from the stop band through the positive angular scanning space of the angular scanning field.
In one mode of operation, the sequence is simply reversed (i.e., full signal to the positive scanning space, half signal to each of the positive and negative scanning spaces, full signal to the negative scanning space) as scanning returns to the negative limit of the scanning field from the positive limit. Alternatively, the scanning can transition back to the negative field limit after the positive field limit has been reached, and the original switching sequence (negative space-to-stopband-to positive space) can be repeated.
In some exemplary embodiments, the master switch assembly comprises a single pole triple throw (SP3T) switch. Each of the negative side scan switch assembly and the positive side scan switch assembly also comprises an SP3T switch, each of the SP3T switches having a full signal input terminal, a half signal input terminal, and a matched load terminal connected to an impedance-matched load. In operation, scanning of the negative scanning space is performed with a first output terminal of the master switch assembly connected to the full signal input terminal of the negative side scan switch assembly, while the positive side scan switch assembly is connected to its matched load terminal. The stop band scanning is performed with a second output terminal of the master switch assembly connected to the half signal input terminal of both the negative side scan switch assembly and the positive side scan switch assembly. The scanning of the positive scanning space is performed with a third output terminal of the master switch assembly connected to the full signal input of the positive side scan switch assembly, while the negative side scan switch assembly is connected to its matched load terminal.
In other exemplary embodiments, the master switch assembly comprises two single pole double throw (SPDT) master switches. A first SPDT master switch has an input terminal connected to a signal source, and two selectable output terminals. The first output terminal of the first SPDT switch is connected to the full signal input of one of the SP3T side scan switches (e.g., the positive side scan switch), while the second output terminal of the first SPDT master switch is connected to the input terminal of a second SPDT master switch. The second SPDT master switch has two selectable output terminals, one of which is connected to the full signal input of the other SP3T side scan switch (e.g., the negative side scan switch), and the other of which is connected to the half signal inputs of both SP3T side scan switches.
To perform the negative space scan, the first SPDT master switch is operated to connect serially to the second SPDT master switch, which is operated to connect to the full signal input of the negative SP3T side scan switch. Stop band scanning is performed by switching the second SPDT master switch to connect to the half signal inputs of both the SP3T side scan switches. The positive space scan is performed by switching the output of the first SPDT master switch from the second SPDT master switch to the full signal input of the positive SP3T side scan switch. Whichever of the SP3T side scan switches is not receiving input from one of the SPDT master switches is switched to be connected to its respective impedance-matched termination.
Other exemplary embodiments are similar to the previously-described embodiments with two SPDT master switches, except that each of the side scan switch assemblies comprises a serially-connected pair of SPDT switches. In these embodiments, a first SPDT negative side scan switch has a selectable full signal input terminal connected to a first selectable output terminal of the second SPDT master switch, and a selectable matched load terminal connected to an impedance-matched load. The output terminal of the first SPDT negative side scan switch is connected to one of two selectable input terminals of a second SPDT negative side scan switch, the other of which is a selectable half signal input connected to a second selectable output terminal of the second SPDT master switch. On the other side of the feed line, a first positive SPDT side scan switch has a selectable full signal input terminal connected to a selectable output terminal of the first SPDT master switch, and a selectable matched load terminal connected to an impedance-matched load. The output terminal of the first SPDT positive side scan switch is connected to one of two selectable inputs of a second SPDT positive side scan switch, the other of which is a selectable half signal input terminal connected to the second output terminal of the second SPDT master switch.
To perform the negative space scan, the first SPDT master switch is operated to connect serially to the second SPDT master switch. The second SPDT master switch and the first SPDT negative side scan switch are operated to connect the first selectable output terminal of the second SPDT master switch to the full signal input terminal of the first SPDT negative side scan switch. The first and second SPDT positive side scan switches are operated to connect the impedance-matched load to the positive end of the feed line. Stopband scanning is performed with the second output terminal of the second SPDT master switch, the second SPDT negative side scan switch, and the second SPDT positive side scan switch operated to connect the second selectable output terminal of the second SPDT master switch to the half signal input terminals of the second SPDT negative side scan switch and the second SPDT positive side scan switch. Finally, positive space scanning is performed by operating the first SPDT master switch, the first positive side SPDT switch, and the second SPDT positive side scan switch to connect the second selectable output terminal of the first SPDT master switch to the full signal input terminal of the first SPDT positive side scan switch, and to connect the first selectable input terminal of the second SPDT positive side scan switch to the output terminal of the first SPDT positive side scan switch. This will disconnect the second SPDT master switch from the first SPDT master switch. Also, the first and second SPDT negative side scan switches are operated to connect the negative side impedance-matched load to the negative end of the feed line.
It will be appreciated that the operation of the various switches used in the above embodiments may advantageously be operated in the desired sequence under the control of a suitably programmed electronic processor, or any other automated control system capable of coordinating the operation of the switches to provide the desired results. Such control systems and/or mechanisms are well-known in the art, and they will readily suggest themselves to those tasked with implementing the disclosed embodiments.
It should be understood that the terms “negative” and “positive,” as applied to the angular scanning spaces on opposite sides of the stop band in this disclosure, are defined in relation to an arbitrarily-selected one of the ends of the feed line, as shown in the drawing Figures. Thus, these terms are used in this disclosure for the purpose of explaining the embodiments described herein, and not in any limiting way.
As will be more fully understood from the detailed description below, the embodiments described herein provide a directional signal scanned with a high degree of efficiency across the entire scanning field, from the negative scanning limit to the positive scanning limit, including the stop band. This result is achieved without adding significantly to the cost or complexity of the scanning antennas with which these embodiments will be implemented, and, importantly in some applications, without adding appreciably to the physical size or weight of such antennas.
Referring first to
The scanning antenna element 104 scans the coupled electromagnetic signal from the first end 106 of the feed line 102 to the second end 108 of the feed line 102. The scanning field thus may be considered as spanning a 180° angular spectrum, from −90° at the first end 106 of the feed line 102 to +90° at the second end 108 of the feed line 102, thereby crossing through 0°. Alternatively, fields with less than a full 180° spectrum (e.g. a 90° spectrum from −45° to +45°) may be scanned. Thus, the first end 106 of the feed line 102 may be deemed, for the purpose of this discussion, the “negative” end, while the second end 108 of the feed line 102 may be deemed the “positive” end, although the application of terms “negative” and “positive” to the first end 106 and to the second end 108, respectively, is arbitrary, as mentioned in the Summary above. In either case, the scanning region in the proximity of 0° (and on either side thereof) may be termed the “stop band”. The stop band may be defined as the angular range on either side of 0° in which the antenna Gain is reduced by 3 dB from its maximum value. Thus, in one exemplary embodiment, if the 3 dB Antenna Gain reduction occurs in a beamwidth of 1°, the stop band is defined (in this example) as 0°±0.5°.
In the embodiments according to
A second SP3T switch 130 has a single output terminal 132 in the form of a fixed contact electrically coupled to the first or “negative” end 106 of the feed line 102. The second SP3T switch 130, which may be termed the “negative side scan switch,” has first, second, and third selectable input terminals 134, 136, 138, respectively. The first input terminal 134 is a full signal input terminal that is connected to the first output terminal 116 of the master switch 110. The second input terminal 136 is a half signal input terminal that is connected to the second output terminal 118 of the master switch 110. The third input terminal 138 is a matched load terminal that is connected to a negative side impedance-matched load 140.
A third SP3T switch 150 has a single output terminal 152 in the form of a fixed contact electrically coupled to the second or “positive” end 108 of the feed line 102. The third SP3T switch 150, which may be termed the “positive side scan switch,” has first, second, and third selectable input terminals 154, 156, 158, respectively. The first input terminal 154 is a full signal input terminal that is connected to the third output terminal 120 of the master switch 110. The second input terminal 156 is a half signal input terminal that is connected to the second output terminal 118 of the master switch 110. The third input terminal 158 is a matched load terminal that is connected to a positive side impedance-matched load 160.
In operation, a negative angular space scan (e.g., −45° to the stop band) is performed with the first output terminal 116 of the master switch 110 connected to the full signal input terminal 134 of the negative side scan switch 130, while the matched load terminal 158 of the positive side scan switch 150 is connected to its impedance-matched load 160. The stop band scanning (i.e., the portion of the scanning field including and proximate to 0°, as defined above) is performed with the second output terminal 118 of the master switch 110 connected both to the half signal input terminal 136 of the negative side scan switch 130 and the half signal input terminal 156 of the positive side scan switch 150. The positive space scanning (e.g., from the stop band to +45°) is performed with the third output terminal 120 of the master switch 110 connected to the full signal input terminal 154 of the positive side scan switch 150, while the matched load terminal 138 of the negative side scan switch 130 is connected to its impedance-matched load 140.
The resulting radiated beam shape, a simulated representation of which is shown in
Referring to
In the embodiments according to
The first master switch 210a receives an RF (or microwave) signal through a signal port 212 connected to an input terminal 214 that is a fixed contact of the first master switch 210a. The first master switch 210a has first and second selectable output terminals 216, 218, respectively, to which the input terminal 214 can be selectively connected. The first output terminal 216 of the first master switch 210a is connected to a fixed contact input terminal 220 of the second master switch 210b. The second output terminal 218 of the first master switch 210a is connected to a selectable full signal input terminal 254 of the positive side scan switch 250.
The second master switch 210b has first and second selectable output terminals 222, 224, respectively. The first output terminal 222 of the second master switch 210b is connected to a selectable full signal input terminal 234 of the negative side scan switch 230. The second output terminal 224 of the second master switch 210b is connected both to a selectable half signal input terminal 236 of the negative side scan switch 230, and to a selectable half signal input terminal 256 of the positive side scan switch 250.
The negative side scan switch 230 has a third selectable input terminal 238 that is a matched load terminal connected to a negative side impedance-matched load 240. Similarly, the positive side scan switch 250 has a third selectable input terminal 258 that is a matched load terminal connected to a positive side impedance-matched load 260.
In embodiments in accordance with the system shown in
Again, the resulting radiated beam, a simulated representation of which is shown in
Referring to
In the embodiments according to
The first master switch 310a receives an RF (or microwave) signal through a signal port 312 connected to an input terminal 314 that is a fixed contact of the first master switch 310a. The first master switch 310a has first and second selectable output terminals 316, 318, respectively, to which the input terminal 314 can be selectively connected. The first output terminal 316 of the first master switch 310a is connected to a fixed contact input terminal 320 of the second master switch 310b. The second output terminal 318 of the first master switch 310a is connected to a selectable full signal input terminal 354 of the first positive side scan switch 350a.
The second master switch 310b has first and second selectable output terminals 322, 324, respectively. The first output terminal 322 of the second master switch 310b is connected to a selectable full signal input terminal 334 of the first negative side scan switch 330a. The second output terminal 324 of the second master switch 310b is connected both to a selectable half signal input terminal 336 of the second negative side scan switch 330b, and to a selectable half signal input terminal 356 of the second positive side scan switch 350b.
The first negative side scan switch 330a has a second selectable input terminal 338 that is a matched load terminal connected to a negative side impedance-matched load 340. Likewise, the first positive side scan switch has a second selectable input terminal 358 that is a matched load terminal connected to a positive side impedance-matched load 360.
In embodiments in accordance with the system shown in
Again, the resulting radiated beam from the antenna element 304, a simulated representation of which is shown in
The operating program is configured to operate or actuate the various switches in an appropriate sequence so as to be coordinated with the scanning motion (i.e., rotation) of the antenna element, whereby the desired beam shapes (as shown, for example, in
The systems described above have been described in the transmission mode of operation. It will be appreciated that their operation in the reception mode will be the reciprocal of the transmission mode, to which the drawing Figures are equally applicable. Thus, in the reception mode, the scanning antenna elements 104, 204, 304 receive a signal across the angular scanning field, and the received signal is evanescently coupled to the feed line 102, 202, 302, from which the signal is directed to the signal port 112, 212, 312 by the switching network so as to receive the incoming signal across the full angular scanning field, including the stop band.
| Number | Name | Date | Kind |
|---|---|---|---|
| 5815124 | Manasson et al. | Sep 1998 | A |
| 5959589 | Sadovnik et al. | Sep 1999 | A |
| 6211836 | Manasson et al. | Apr 2001 | B1 |
| 6750827 | Manasson et al. | Jun 2004 | B2 |
| 7667660 | Manasson | Feb 2010 | B2 |
| 8629813 | Milosavljevic | Jan 2014 | B2 |
| 9070975 | Collins | Jun 2015 | B2 |
| 9153867 | Kim | Oct 2015 | B2 |
| 9553361 | Hu | Jan 2017 | B2 |
| 9711841 | Yong | Jul 2017 | B2 |
| 20030073463 | Shapira | Apr 2003 | A1 |
| 20060244672 | Avakian et al. | Nov 2006 | A1 |
| 20070152868 | Schoebel | Jul 2007 | A1 |
| 20090059890 | Cordeiro et al. | Mar 2009 | A1 |
| 20090251382 | Umehara | Oct 2009 | A1 |
| 20120105295 | Lin et al. | May 2012 | A1 |
| 20120133571 | Collins | May 2012 | A1 |
| 20150116159 | Chen | Apr 2015 | A1 |
| 20160006092 | Ueda et al. | Jan 2016 | A1 |
| 20190058254 | Zhu | Feb 2019 | A1 |
| 20190181555 | Lee | Jun 2019 | A1 |
| Number | Date | Country |
|---|---|---|
| WO2016153459 | Sep 2016 | WO |
| Entry |
|---|
| International Search Report on corresponding PCT application (PCT/US2019/025378) from International Searching Authority (USPTO) dated Jul. 5, 2019. |
| Written Opinion on corresponding PCT application (PCT/US2019/025378) from International Searching Authority (USPTO) dated Jul. 5, 2019. |
| Number | Date | Country | |
|---|---|---|---|
| 20190312350 A1 | Oct 2019 | US |
