1. Technical Field
The present invention relates to radar systems. More particularly, the present invention relates to transmit/receive modules in compact packages.
2. Description of the Background Art
A variety of technical problems face one looking to equip an airplane with Ku and Ka band radars (for simplicity, K band radars are referred to with lower case letters, not the official subscripts). Modern radars systems are often implemented as active electronically scanned arrays with hundreds of transmit/receive modules aligned in an array. One advantage of an active electronically scanned array is that it can perform radar scans without physically turning the radar array. This is accomplished by altering the phase of the transmitted radars. By synchronizing the phases of each of the transmit/receive modules, the beam transmitted points in a different direction. However, in order to change the direction of the radar beam (i.e., the main lobe) the transmitted radars must be packed close enough together to work in unison.
Ka band radar, short for “K above,” is transmitted at approximately 18-40 GHz. Because such high frequencies are being used, the transmit/receive modules must be packed very tightly. In an active electronically scanned array, the lattice spacing must be approximately half of the wavelength of the highest frequency used. Ka band radar requires five elements per inch. Systems operating in the X band, e.g. 10 GHz, had ten times as much area in which to place transmit/receive modules. The demanding space requirements were too small for the current size of transmit/receive modules.
In addition to the size of the modules, a designer must also contend with the size of the connections to and from modules. Prior art designs require bulky connectors connecting a module to a radiating element. Prior art designs also require a connector from the module to a manifold interconnect. The inventors discovered that current connectors did not meet the height requirements of a Ka band radar grid.
These issues are compounded where a plane needed both Ku and Ka band radars. The module must be small enough to be able to create an effective array of Ka band radar, but still make room for both Ka band radar technology and Ku band radar technology. Because these two bands are at different frequencies, they must be transmitted and received separately. At the same time, the circuitry for both must be compact enough that it can fit into the Ka space requirements.
Embodiments of the present invention provide a multi-channel, dual-band, radio frequency (RF) transmit/receive (T/R) module for an active electronically scanned array. The module includes a compact, RF manifold connector and at least four T/R channels. Each of the T/R channels includes a notch radiator, a diplexer coupled to the notch radiator, a power amplifier, including at least one dual-band gain stage, coupled to the notch radiator, a low noise amplifier, including at least one lower-band gain stage and at least one upper-band gain stage, coupled to the diplexer, and a T/R cell, including a phase shifter, a signal attenuator and at least one dual-band gain stage, coupled to the power amplifier, the low noise amplifier and the manifold connector.
The same part of an invention appearing in more than one view of the drawing is always designated by the same reference character. Lowercase letters designate different instances of a given part.
The LNA 215 output flows across the LNA switch 230 to the T/R cell 235. The T/R cell 235 provides a series of gain stages 240. After the first gain stage 240-1, the signal is phase shifted by a variable shifter 245. After the second gain stage 240-2, the signal is attenuated by a variable resistance 250, sometimes implemented as a digital attenuator. The T/R cell 235 implements 5 bits of phase shift 245 and 6 bits of attenuation 250. This allows the T/R cell 235 to transmit or receive one of the four channels 200. The attenuation allows the beam steering circuitry to control the size of the transmitted signals from each transmit/receive channel 20 relative to each other channel 200. If an array is malfunctioning such that the right side lobe is too pronounced, the variable resistance 250 can be used to ensure that a smaller side lobe is produced. In other situations, fine grained attenuation may be employed to make small adjustments to the shape of a signal transmitted. The T/R cell 235 has three switches, the manifold interconnect switch 255, the transmit path switch 260 and the receive path switch 265. These three switches control the flow of signals through the T/R cell's three gain stages. The output of the third gain stage 240-3 travels across the manifold interconnect switch 255 and the transmit path switch 260 to the manifold interconnect 240.
The transmit path begins at the T/R cell 235. The T/R cell 235 performs the same function on transmitted signals as it does on received signals. When the manifold interconnect switch 255 is set to the transmit path, the signal will flow across from the manifold connection 285 to the receive path switch 265 to the three gain stages 240. After being shifted and attenuated, the signal exits the T/R cell 235 via the transmit path switch 260 and continues to the power amplifier 270. Conversely, the receive path flows as described above. The signal travels from the LNAs 215 to the receive path switch 265, across the three gain stages 240, to the transmit path switch 260 and then to the manifold interconnect switch 255.
The T/R cell 235 outputs to the power amplifier 270. The power amplifier 270 has three gain stages 275 to ensure that the transmitted signal has the requisite signal strength. The power amplifier 270 outputs to the T/R switch 205, where it is routed to the radiator 105. In a preferred embodiment, the power amplifier 270, like the T/R switch 205, is designed to work at both the Ka and Ku bands. When the T/R switch 205 is integrated with the power amplifier 270, it may be referred to as a power amplifier switch 205.
The path used to transmit a signal has a number of components in common with the receive path. A signal to be transmitted is provided by the manifold interconnect 315, and is routed to the T/R cell 235. The T/R cell 235 directs the signal to the T/R switch 205, which routes the signal to the radiator 105. The transmit path does not use the LNAs 215 or the diplexer 210. By avoiding these band specific devices, the transmit path is identical for both the Ka and Ku bands. Therefore, it may be possible to transmit in both bands at one time.
The receive and transmit paths converge at the T/R cell 235, preferably embodied as a SAD MMIC. The T/R cell 235 interfaces with the manifold interconnect 315 and receives control signals for its channel 200. The control signals allow the T/R cell 235 to either route signals from the manifold 315 to the transmit path or from the receive path to the manifold interconnect 315. Like the power amplifier 270, the T/R cell 235 is a dual band device.
All of the MMICs in a transmit/receive module 100, such as the SAD MMIC 235, the LNA MMIC 310 and the power amplifier MMIC 305, share a drain regulator ASIC 410 (depicted in
The control signals are provided to the T/R cell 235 by the control module 320 for each channel 200. The control module 320 may be implemented as an ASIC. The control module 320 receives six bidirectional DC signals which are used to generate control signals for the T/R cell 235, the LNA switches 230 and the T/R switch 205. An ASIC control module is a type of control chip.
The control signals allow the T/R cell 235 to interface with beam steering circuitry (not shown). Beam steering refers to changing the main lobe of radar signal. This allows a stationary radar array to point in different directions, often in a sweeping pattern. In certain instances, beam steering circuitry may be employed to enlarge or reduce side lobes of a transmitted signal. Beam steering and lobe adjustment may be accomplished by altering three variables: which transmit/receive modules 100 are addressed; the phase of signals transmitted; and the attenuation of the signals transmitted. Digital signal processors (not shown) are often employed to calculate the particular control signals needed to direct various lobes. A beam steering controller (not shown) includes a memory module, a controller CPU module, an interface timing module, a beam computation module and array interface module.
In a preferred embodiment, a manifold interconnect 315 is connected to the T/R cells 235 with an RF network which delivers signals from the manifold interconnect 315 to the T/R cells 235 and transports received signals back to the manifold interconnect 315. The RF network, part of the manifold interconnect 315, is an example of a manifold connection.
MMICs are generally manufactured from Gallium Arsenide, Indium Phosphate or Silicon Germanium, so that the devices can operate at the required frequencies. One element of a compact design may be manufacturing a three metal interconnect MMIC from Gallium Arsenide.
The placement of the power amplifier 270 is important for transmission, and the switch 205 is integrated with the power amplifier 270 to save space. In a preferred embodiment, a high power T/R switch 205 is used instead of a circulator because traditional circulators may be too large to fit inside of the power amplifier cavity. Power amplifiers 270 have lower linear response requirements than the LNAs 215. The T/R switch 205 is placed on the front end of the power amplifier MMIC 305 closest to the integrated radiators 105, and is built into a power amplifier 270 and located in the power amplifier cavity. Each power amplifier 270 and T/R switch 205 is placed directly behind its respective integrated radiator 105, so that the power amplifier 215 is as close to the integrated radiator 105 as possible. One advantage of placing the power amplifier 270 directly before the integrated radiator 105 is that any potential interference or attenuation is minimized. This helps to ensure that the transmitted signal is not changed before being transmitted.
The diplexers 210 are placed in a cavity between the power amplifier cavities and the LNA cavities. Unlike some of the other devices, the diplexers 210 are not placed in line with their respective transmit and receive channels 200. The MMICs are each separate integrated circuits, whereas the diplexers 210 are, in large part, stripline RF traces embedded in ceramic, a type of ceramic insulation.
The LNAs 215 are placed directly after the diplexers 210 to be as close together as possible. LNAs 215 are most effective if used close to the integrated radiators 105 because the less there is between the integrated radatior 105 and the LNAs 215, the less possibility there is for noise to be introduced. Noise that is introduced before the LNA 215 may be indistinguishable from the signal, particularly if it is at the same frequency. That is, if the noise is within the band that the LNA 215 is designed to amplify, then the noise will be amplified as though it were the signal. Conversely, if this same noise is added to the signal after the LNA 215, it will be attenuated relative to the signal and thus have a reduced effect on system input. By placing the LNA 215 physically close to the diplexer 210, feedline losses are reduced.
After the LNAs 215, there are four pairs of T/R cells 235 and control module 320 ASICs, and each pair is placed in a corner. This placement allows space for the gate regulator ASICs 405 and drain regulator ASICs 410 and for the manifold interconnect 315 to be symmetrically routed to each T/R cell 235.
Because the Ka grid may force tight spacing requirements, a number of techniques may be employed to route signals within one embodiment of the module. In order to obtain the benefits of a four-channel architecture, one embodiment of the transmit/receive module 100 utilizes minimum spacing tolerances between all RF and DC lines in most areas of the package layout. The use of thin dielectric tape layers allows for stripline 530, discussed in more depth in
Double rows of grounding vias 535 may be used on both sides of the stripline 545 to keep Ka signals from leaking through to other transmit and receive channels 200. This dense placement of grounding vias 535 improves the problem of Ka leakage. New techniques in LTCC fabrication such as placing fewer transmit/receive modules 100 on each LTCC panel to reduce shrinkage of the LTCC have been developed to counter the effects of increased via 510 count.
Received signals enter the module 100 through one of four integrated notch radiators 105. A transmit/receive module 100 may have one integrated radiator 105 for each of the four channels 200, where the term integrated radiator 105 commonly refers to a radiator 105 without a bulky connector attaching the transmit/receive module 100 to a separate radiator or antenna. The desire for both Ka and Ku band radar may prompt some designers to implement integrated radiators 105 that are wideband.
In one embodiment, an integrated radiator 105, such as a wideband notch radiator, couples a stripline 530, often 50 ohms, with the air, usually 376 ohms, such that a signal may be fed into the stripline 530 and may pass through to the radiating medium with minimal interference. The notch is an aperture cut to form an integrated radiator 105 with a load that matches the ambient radiating medium. The aperture is cut from a dielectric substrate, which also houses the stripline 530. The substrate sandwiches the stripline 530 and provides insulation. The stripline 530 is connected to the notch with a feed end, and both connecting ends are generally a quarter wavelength long, or a multiple thereof. The integrated radiator 105 is designed for wideband operation using low-temperature co-fired ceramic (LTCC), such as Dupont 943 LTCC. In one embodiment, the stripline feed 505 connects to the power amplifier cavity.
In one embodiment, a manifold interconnect 315 may be comprised of a plurality of contiguous RF stripline microwave conductor board members, an example of stripline 530, which are mutually insulated from one another and include RF coupler sections which abut a pair of relatively shorter tubular coupler members, and which are also adapted to couple transmit RF and receive RF to and from a transmit/receive module 100. The single connection may provide four channels 200 which are received by a ceramic locus splitter.
Grounding walls 535 are placed on both sides of the Ku band signal path to provide isolation from other signals. The Ku band signal path is more sensitive to unwanted signals than the Ka band path because the Ku path contains passive components, such as a low pass filter 525. The rectangular waveguide 520 of the Ka path is shielded. The grounding walls 535 are between two ground planes, one above the diplexer and one below. The grounding walls 535 are formed with a series of grounding vias 540 between the ground planes. Unwanted signals from outside the diplexer 210 encounter the ground planes or the grounding vias 540 and are absorbed into the ground plane rather than interfering with the signals passing through the diplexer 210.
In an embodiment where the diplexer 210 performs a transmit function in addition to receiving, added isolation between Port 2510 and Port 3515 may be needed, because these transmitted signals represent noise to the other band. This is less of a concern when receiving because the received signals are amplified after the diplexer 210, whereas the transmitted signals are amplified and then sent to the diplexer 210.
Ceramics may be used to insulate against unwanted signals as well as grounding techniques. Interface issues between Ku energy operating in a Ka band environment can be solved, in part, by embedding the diplexer 210 in ceramics.
The DC traces 710 are paired, for balance, and then routed out through the floor of the cavity and then through the wall of the cavity one pair at a time. As depicted, the DC traces 710 are routed through the cavity with vias 715. The vias 715 are about 5 mils in diameter. On the far side of the cavity, grounding vias 540 are placed that connect to the ground plane, as shown. The use of a pair of grounding vias 540 helps insulate cavity resonance.
The DC traces 710 originate from a data bus. Each of the channels 200 has a separate data bus. Each data bus has a control module 320, such as a module channel controller, often implemented as an ASIC. In one embodiment, each control chip is separately addressable across the manifold interconnect 315.
While this invention has been described in conjunction with specific embodiments thereof, many alternatives, modifications and variations will be apparent to those skilled in the art. Accordingly, the preferred embodiments of the invention as set forth herein, are intended to be illustrative, not limiting. Various changes may be made without departing from the true spirit and full scope of the invention as set forth herein.
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Number | Date | Country | |
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20090009390 A1 | Jan 2009 | US |