The present invention relates to temperature dependent switch apparatus, and particularly to temperature dependent switch apparatus suitable for use with phased array radars.
Phased array radar antennas are generally known and implemented. Phased array antennas include apertures formed from a multitude of radiating elements. Each radiating element is individually controlled in phase and amplitude. In this manner, desired radiating patterns and directions may be achieved. By rapidly switching the elements to switch beams, multiple radar functions may be realized.
A circuit including: at least one conductor; a least one vanadium oxide region electrically coupled to the at least one conductor; and, at least one thermionic cooler thermally coupled to the vanadium oxide region; wherein, the thermionic cooler is suitable for transitioning the at least one vanadium oxide region from a first temperature range where the at least one vanadium oxide region is substantially conductive to a second temperature range where the at least one vanadium oxide region is substantially non-conductive.
Understanding of the present invention will be facilitated by consideration of the following detailed description of the preferred embodiments taken in conjunction with the accompanying drawings, wherein like numerals refer to like parts and:
It is to be understood that the figures and descriptions of the present invention have been simplified to illustrate elements that are relevant for a clear understanding of the present invention, while eliminating, for the purpose of clarity, many other elements found in typical radar antenna arrays and signal processing systems. Those of ordinary skill in the art may recognize that other elements and/or steps are desirable and/or required in implementing the present invention. However, because such elements and steps are well known in the art, and because they do not facilitate a better understanding of the present invention, a discussion of such elements and steps is not provided herein.
Referring now to
Switching devices 240, 250 may each be operated in a first mode, which essentially provides a low electrical resistance condition, such that signals are steered from input terminal P1 to transmit terminal P3 and hence waste load 110. Devices 240, 250 may each also be operated in a second mode that essentially provides a high electrical resistance condition, such that signals are steered to receive terminal P2.
Switching devices 240, 250 are temperature dependent. Subjecting each of devices 240, 250 to a first temperature range effects their operation in the first mode, while subjecting them to a second temperature range effects their operation in the second mode. As will be understood by those possessing an ordinary skill in the pertinent arts, such a control mechanism is separate from the radio frequency (RF) signal path. Accordingly, such an approach advantageously may omit wires, jumpers and materials that deleteriously affect RF performance and compromise circuit performance, as is discussed in commonly-assigned, United States Patent Application Serial No. 11/371,174 entitled RF/MICROWAVE INTEGRATED SWITCH SUITABLE FOR USE WITH PHASED ARRAY RADAR ANTENNA, the entire disclosure of which is hereby incorporated by reference herein.
In one configuration, switching devices 240, 250 may take the form of vanadium oxide interconnections, such as vanadium (IV) oxide (VO2). Other vanadium oxide materials, such as vanadium (II) oxide (VO), vanadium (III) oxide (V2O3) and vanadium (V) oxide (V2O5) may also be suitable for use. The present invention will be further discussed as it relates to vanadium (IV) oxide, for non-limiting purposes of explanation.
Referring now to
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According to an aspect of the present invention, the temperature of VO2 based electrical interconnections may be selectively altered using thermionic cooling. By way of non-limiting explanation, thermionic cooling leverages the realization that a high work function cathode in contact with a heat source will emit electrons. When the electrons are absorbed by a cool low work function anode, they may be returned to the cathode—having the effect of cooling the cathode and heating the anode. Using a higher bandgap material between lower bandgap materials forming the cathode and anode provides a barrier to electron mobility there between. The amount of cooling equates to the product of the total current and average energy of carriers emitted over the barrier. Semiconductor heterostructure based thermionic coolers are discussed in U.S. Pat. No. 6,403,874, entitled HIGH-EFFICIENCY HETEROSTRUCTURE THERMIONIC COOLERS, by Shakouri et al., the disclosure of which is hereby incorporated by reference as if being set forth in its entirety herein.
Referring now to
Dielectric 320 also supports gold microstrips 340, 350 that connect contacts (not shown) to substrate 330. Microstrips 340, 350 may take the form of conventional circuit board traces, for example. Each of microstrips 340, 350 is electrically coupled to VO2 region 360. VO2 region 360 may be selectively operated in the first mode by making the temperature thereof around 80° C.—thereby providing for a low resistance electrical connection between microstrips 340, 350. VO2 region 360 may be selectively operated in the second mode by making the temperature thereof around 60° C.—thereby providing for a high resistance electrical connection between microstrips 340, 350. However, a much smaller temperature fluctuation may actually be used to transition between the first and second modes due to the sharp dependence of resistance of VO2 around 70° C. Accordingly, region 360 is suitable for use as switching device 240 or 250 (
System 300 also includes a VO2 region 360 controller 370. Controller 370 may serve to sufficiently change the temperature of region 360, so as to transition it between the first and second modes. In the illustrated case, region 370 is beneath region 360. Region 370 may be alongside and/or over region 360 as well, or in lieu of being there-under. In any case, controller 370 may be seen to be thermally coupled to VO2 region 360.
Controller 370 may be on the order of about 250 μm×250 μm in surface area. Controller 370 may be suitable for transitioning the temperature of region 260 between first and second temperature ranges including 80° C. and 60° C., respectively. Controller 370 may have a negligible transient heat load.
According to an aspect of the present invention, system 300 may be manufactured as follows. Dielectric block 320 may be bonded to ground plane 310 using conventional printed wiring board processes, such as those described in Roger's Material Guide. A pocket may be milled in dielectric 320 to accept substrate 330. Substrate 330 may be epoxied in place to dielectric 320. Microstrips 340, 350 may be separate, and both partially overlap substrate 330 and block 320. The portions of microstrips 340, 350 that overlap substrate 330 may be joined by solder, wirebond or ribbon bond to the portions that overlap block 320, respectively. Region 370 is formed on substrate 330, such as by using Molecular Beam Epitaxy (MBE) or Metal Organic Chemical Vapor Deposition (MOCVD) to form an integrated thermal controller. Region 360 may be deposited, and cured, onto the 370, 330 integrated controller to form a thermally controlled electrical switch. The 370, 330, 360 switch may be attached to dielectric 320 by epoxy. Alternatively, substrate 330, region 360, the portions of microstrips 340, 350 over substrate 330 and controller 370 may be assembled, and then attached to an assemblage of block 320 and the portions of microstrips 340, 350 over block 320.
In one configuration, controller 370 may take the form of a thermionic cooler apparatus. Referring now also to
Cooler 400 further includes a combination of n-doped 420 and p-doped 430 devices coupled in electrical series, similar to conventional thermoelectric coolers. The cascade structure of devices 420, 430 serves to increase the cooling area of the device 10 without increasing input current demands. Electrons are injected at contact +V and emitted from GROUND. Electrons travel through each layer of devices 420, 430 and electrical contacts 440, 450 in a serpentine fashion, as in conventional thermoelectric coolers.
Devices 420 may be based upon alternating device and barrier layers, e.g., GaAs/AlxGa1-xAs. Of course, other conventional device/barrier layer combinations, such as those incorporating Si, SiGe or SiC may be used. The barrier layers are n-type or p-type doped, to provide n-type and p-type devices 420, 430. Conventional semiconductor manufacturing techniques, such as Molecular Beam Epitaxy (MBE) or Metal Oxide Chemical Vapor Deposition (MOCVD) may be used to form devices 420, 430, as set forth in the incorporated U.S. Pat. No. 6,403,874.
According to an aspect of the present invention, VO2 region 360 may be directly deposited onto cooler 400 or substrate 330, and the combination then soldered, epoxied, ribbon bonded or wire bonded to a host substrate.
By way of further, non-limiting explanation, cooler 400 may take the form of an InGaAs/InGaAsP material based thermionic cooling system. Cooler 400 may have around 5-20 barriers, each about 200 nm thick. Cooler 400 may have a thickness around 1.3 μm. Cooler 400 may have a specific heat around 0.340 J/g.K, a density around 5.5 g/cm3 and a barrier height around 60 meV. Cooler 400 may provide for low-voltage (around 0.1 V), high-current operation, around 10 e4 A/cm2, have a capacitance around 6.64 pF, and an RC time constant around 0.3 ns (50 ohms). In such a configuration, a switching energy (for 0.1V) is expected around 33 fJ, which provides for a heat flow density around 320 W/cm2, or around 200 mW cooling for region 260. Stored heat may typically be removed in around 10 ns, while an expected Carnot specific power=0.058 W/W, an expected efficiency to Carnot is around 35% and an expected specific power is around 0.167 W/W. It is expected this will provide for an input power requirement around 34 mW (+ohmic loss).
Referring now also to
In such a configuration, regions 360′, 360″ may be individually operated in the first and second modes by selectively operating controllers 370′, 370″. The thermal conductivity between region 360′ and controller 370″, as well as the thermal conductivities between region 360″ and controller 370′, regions 360′, 360″ and controllers 370′, 370″ should be considered though, such that inadvertent thermal leakages do not inadvertently transition the regions 360′, 360″ between the first and second modes. This risk may be mitigated by providing a suitable thermal, e.g., spatial, separation between region 360′/controller 370′ and region 360″/controller 370″.
As set forth above, the present invention has a wide range of applicability. It may also be used to provide for re-configurable phased array radar devices, for example.
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While the foregoing invention has been described with reference to the above-described embodiment, various modifications and changes can be made without departing from the spirit of the invention. Accordingly, all such modifications and changes are considered to be within the scope of the appended claims.
Number | Name | Date | Kind |
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3503902 | Takeshi | Mar 1970 | A |
3598762 | Hisao-Futaki et al. | Aug 1971 | A |
4310837 | Kornrumpf et al. | Jan 1982 | A |
6403874 | Shakouri et al. | Jun 2002 | B1 |
Number | Date | Country |
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53132797 | Nov 1978 | JP |
04299802 | Oct 1992 | JP |
491163 | Feb 1976 | SU |