The embodiments described herein relate to high frequency coaxial switches, and in particular, to frequency-related configurable high frequency coaxial switches.
In modern satellite systems, and in other applications, there is a need for radio frequency coaxial switches that perform at ever-higher frequencies. In the prior art, the design strategy for a coaxial switch has been to match the RF paths in as wide a frequency band as possible, such that a few designs could cover all of the frequency bands of commercial interest. However, prior art switch designs have demonstrated poor performance at high frequencies, mostly due to high mismatch losses.
The performance parameters of a coaxial RF switch are the RF power handling, the return loss and isolation; insertion loss is usually an outcome of design features imposed to achieve the desired RF power handling, return loss and isolation. Most coaxial switches, at high operating frequencies, are low RF power devices and therefore the RF power handling is not an important design driver. Isolation is a function of the RF channels, and is relatively easily predicted. However, return loss is more difficult to model, particularly in switches having a complex geometry, and is therefore more difficult to improve in a wide band RF switch design.
The majority of prior art coaxial RF switches that are impedance-matched to a wide frequency band of RF signals do not perform well at frequencies in excess of 30 GHz.
In addition, even relatively good performance individual switches, in terms of reflection, when cascaded, as required by the switching systems used on communication satellites for example, end-up as low performance assemblies. For example a cascaded assembly of N switches each having X return loss (in dB) will have an overall Y return loss (in dB) given by:
Y=X+10·log10 N (1)
Equation (1) shows that the overall reflection of the assembly will deteriorate by 10·log10 N dB, which in the case of 6 cascaded switches for example, means almost 8 dB. This deterioration in performance for the assemblies containing cascaded switches is pushing the requirements on each individual switch higher by at least the same amount.
The low performance of the prior art coaxial switches at higher frequencies is due to the fact that as the frequency increases the wavelength decreases and discontinuities that were transparent for lower frequencies become important, in terms of the reflected signal. Therefore as the frequency increases in a wide frequency band, in order to reduce reflection, one needs high precision parts and very accurate positioning of the moving conductors inside the RF channels of the switch. These requirements become more stringent in complex switch structures, for example T-switch structures, which impose some transmission line discontinuities by their very nature.
The required precision of the switch parts and/or their accurate positioning inside the RF channels of the switch can be reduced where a specific switch will only be used in a limited frequency band around the commercially required frequency and hence will be required to be well matched only in this narrow frequency band. The development of coaxial switches with very good reflection performance around all the required frequencies is however prohibitive for switch manufacturers due to the high cost of producing switch parts requiring high dimensional diversity.
In one aspect, at least one embodiment described herein provides a configurable high frequency coaxial switch comprising a switch housing module having at least two ports, the switch housing module being adapted for operation in a wide frequency band; and, at least one frequency-matching port component module configured to connect a transmission line to one of the ports of the switch housing module. The at least one frequency-matching port component module is configured to provide a match to a desired frequency range. In use, the switch housing module together with the at least one frequency-matching port component module allow for operation of the configurable high frequency coaxial switch at the desired frequency range.
In another aspect, at least one embodiment described herein provides a frequency-matching connector module for use in a configurable high frequency coaxial switch adapted for operation in a wide frequency band. The frequency-matching connector module comprises a connector female portion for receiving a transmission line; and, a connector male portion, attached to the connector female portion, for engaging a port of the configurable high frequency coaxial switch. The connector male portion comprises a modular portion with a geometry configured to provide a match for the configurable high frequency coaxial switch to a desired frequency range.
In another aspect, at least one embodiment described herein provides a frequency-matching connector adapter module for use in a configurable high frequency coaxial switch adapted for operation in a wide frequency band. The frequency-matching connector adapter module comprises an adapter female portion for receiving a transmission line; an adapter male portion for engaging a standard connector for a port of the reconfigurable high frequency coaxial switch; and, an adapter frequency-matching portion, for connecting the adapter female portion to the adapter male portion and having a geometry that is configured to provide a match for the configurable high frequency coaxial switch to a desired frequency range.
Further aspects and advantages of the embodiments described herein will appear from the following description taken together with the accompanying drawings.
For a better understanding of the embodiments described herein and to show more clearly how they may be carried into effect, reference will now be made, by way of example only, to the accompanying drawings which show at least one exemplary embodiment, and in which:
It will be appreciated that for simplicity and clarity of illustration, elements shown in the figures have not necessarily been drawn to scale. For example, the dimensions of some of the elements may be exaggerated relative to other elements for clarity.
It will be appreciated that for simplicity and clarity of illustration, where considered appropriate, reference numerals may be repeated among the figures to indicate corresponding or analogous elements or steps. In addition, numerous specific details are set forth in order to provide a thorough understanding of the exemplary embodiments described herein. However, it will be understood by those of ordinary skill in the art that the embodiments described herein may be practiced without these specific details. In other instances, well-known methods, procedures and components have not been described in detail so as not to obscure the embodiments described herein. Furthermore, this description is not to be considered as limiting the scope of the embodiments described herein in any way, but rather as merely describing the implementation of the various embodiments described herein.
Reference is first made to
The switch housing 12 further comprises a first port 24 and a second port 26, each of the first port 24 and second port 26 comprising a cylindrical port wall 28 and a port channel 30. The port channel 30 is in fluid connection with the switch cavity 22. The first port 24 is located on the upper wall 14 of the switch housing 12 in the vicinity of the first end wall 16. The second port 26 is located on the upper wall 14 of the switch housing 12 in the vicinity of the second end wall 18.
The switch cavity 22 houses a conductive reed 31 having a length, m that is shorter than the length, l, of the switch cavity 22. The RF reed 31 is a substantially rectangular blade, having a width, d. The conductive reed is positioned in the switch cavity 22 such that it does not contact the first end wall 16 or the second end wall 18. The conductive reed 31 is movable through a switch mechanism (not shown) from a first position parallel to and contacting the lower wall 20 to a second position parallel to the lower wall 20 and free of any contact with the switch housing 12.
The switch 10 further comprises a first connector 32 and a second connector 34, which engage the first port 24, and the second port 26, respectively. Each connector 32, 34 comprises a connector female portion 40 for receiving a male connector of a transmission line 36, 38, and a connector male portion 41 for engaging a port 24, 26. Each connector 32, 34 further comprises a hollow, open-ended cylindrical connector shell 44 and a connector probe 42. The connector shell 44 and the probe 42 are positioned relative to one another with plastic beads, or by other means known in the art, not shown for clarity of the illustration.
A protruding end 47 of the connector probe 42, distal from the connector female portion 40, protrudes from the open end of the connector shell 44 distal from the female portion 40. The connector shell 44 of each connector 32, 34 engages with the port wall 28 of each port 24, 26 and the protruding end 47 of the connector probe 42 of each connector 32, 34 extends through the port channel 30, and the entry 29, into the switch cavity 22, without contacting the port wall 28.
The switch cavity 22 is a rectangular waveguide designed such as to have a cut-off frequency that is much higher than the operating switch signal frequency, thereby ensuring good isolation between the connector ports 42 when the reed 31 is grounded.
For clarity, the description and
As described previously, a switch structure is designed for a particular application and a desired frequency range. Conventionally, the switch structure as a whole is designed to meet specified performance requirements for the desired frequency range, and the manufacturing process is then designed to produce this particular switch. Thereafter, when a new switch is required for a new application and a new desired frequency range, conventionally a new design is made for the new switch, as well as a corresponding design of the manufacturing process for manufacturing the new switch.
As described herein, a new switch design is provided which has modular components such that different switch products can be produced for different applications and different frequency ranges without requiring a redesign of the switch or the manufacturing process. Rather, modular components are used such that at least one of the modular components can be re-used for a variety of different products while other portions of the modular components are redesigned as needed for the particular application and desired frequency range as the case may be. This allows different switch products to be more efficiently manufactured since the entire switch does not have to be redesigned for a new application and desired frequency range.
For example, according to the teachings herein, a switch housing module can be made for operation in a wide frequency band. The switch housing module can then be configured so that it is operable in any desired frequency range, which can be inside or outside of (i.e. higher or lower than) the wide frequency band, for example, by using frequency matching component modules that can provide a match for the switch housing module to the desired frequency range. This holds for all of the following embodiments described herein. This allows for the mass production of the switch housing module along with the production of particular frequency matching components, as required, which are then combined with the switch housing module to manufacture a switch product for the particular application at the desired frequency range. This notion of modularity can also be extended to the manufacture of the frequency matching components themselves. These structures are described in further detail below. Accordingly, the use of these modular components optimizes the production of these switches, which are easily configurable depending on the particular application and desired operating frequency range.
Reference is now made to
The switch housing module 52, in the absence of the frequency-matching port component modules 54, is wideband and is matched to a wide range of signal frequencies, up to the higher mode propagation limit in the range of 22-26 GHz. The frequency-matching port component modules 54, 56 optimize the RF performance of the configurable high frequency coaxial switch 50 in a limited (for example, in the range of 2 GHz) high-frequency band around an operating frequency that may be significantly higher than, lower than or within the wide range of frequencies matched to the switch housing module 52 without the frequency-matching port component modules 54, 56. For example, the switch housing module 52 can be matched to a wide range of frequencies up to 26 GHz. With the addition of the frequency-matching port component modules 54, 56 the configurable high frequency switch 50 can be matched to perform in a limited high frequency range around 30 GHz, 40 GHz, or 50 GHz. Accordingly, the configurable high frequency switch module 50 can be configured to perform in a desired limited high frequency range by adding the frequency-matching component modules 54, 56 that are matched to the desired limited high frequency range to the switch housing module 52. This allows the switch housing module 52 to be re-used for a variety of different applications and frequency ranges by using a frequency-matching component module that can provide a match for operation at the intended or desired frequency range.
The exemplary configurable high frequency coaxial switch 50 of
Reference is now made to
The modular frequency-matching probe 66 has a protruding end, having a frequency-matching region 68 and a reed contact surface 70, distal from the female portion 60, that protrudes past the frequency-matching connector shell 64. The frequency-matching region 68 comprises sections with lengths and diameters calculated to achieve good impedance matching around the desired operating frequency for the cavity 22 of the switch housing module 52. Accordingly, the frequency matching connector module 58 is also modular in the sense that most of the components of the frequency matching connector module 58 can be standard components that are manufactured in bulk and the modular frequency-matching probe 66 can be manufactured according to the desired frequency range of operation thereby increasing the efficiency of the manufacturing process.
The frequency-matching region 68 of the frequency-matching connector module 58 of
It will be understood by those skilled in the art that a variety of similar frequency-matching probes, having different numbers of matching segments, diameters of matching segments, and lengths of matching segments are comprised in various embodiments of the frequency-matching probe. The dimensions and shape of each frequency-matching probe are selected to optimize the performance of the configurable high frequency coaxial switch 50 in a desired limited bandwidth around the required operating frequency (i.e. desired frequency range).
Reference is now made to
A signal with frequency components in the limited range surrounding the desired operating frequency that is optimized by the frequency-matching connector module 58 can be transmitted through the closed configurable high frequency coaxial switch 50 with minimal loss. If a different high frequency operating frequency is required in an application of the device, then a different frequency-matching connector module 58 can be installed within the port 26 of the switch housing module 52 which is matched to the different high operating frequency.
Reference is now made to
Each of the first frequency-matching connector adapter module 124 and the second frequency-matching connector adapter module 126 is designed so that the configurable high frequency switch 118 is operable in a narrow high-frequency band surrounding a desired operating frequency. If a different operating frequency is required, a different first frequency-matching connector adapter module 124 and second frequency-matching connector adapter module 126 can be used that can provide a match to the different narrow high frequency band surrounding the different operating frequency.
Reference is now made to
The frequency-matching connector adapter module 124 further comprises a female portion 138 for receiving a transmission line (not shown). The female portion 138 comprises receiving sections 140, 142 in the adapter shell 132 and in the adapter core module 134 respectively, as is well known in the art. The frequency-matching connector adapter module 124 also comprises a male portion 144 for engaging a standard connector (not shown). At the male portion 144, the adapter core module 134 protrudes from the adapter shell 132 in order to engage the standard connector, as is well known in the art.
The frequency-matching connector adapter module 124 further comprises a frequency-matching portion 146. The frequency-matching portion 146 is characterized by at least one section 149, 150, 151 of the adapter core module 134 having a diameter differing from the diameter of the remainder of the adapter core 134. The dimensions and number of sections of the frequency-matching portion 146 are designed to match the configurable high frequency switch 118 to a narrow high-frequency band surrounding a desired operating frequency or desired frequency range.
Reference is now made to
It will be understood by those skilled in the art that a variety of similar frequency-matching adapter cores, having different numbers, diameters and lengths of sections are comprised in various embodiments of the frequency-matching adapter core module. The dimensions and shape of each frequency-matching adapter core module are selected to optimize the performance of the configurable high frequency coaxial switch 118 in a desired limited bandwidth or frequency range around the required operating frequency.
All of the other considerations regarding the way to achieve impedance matching, the type of ports and their influence on the geometry of the frequency-matching adapter module remain the same as in the first embodiment shown in
Reference is now made to
The frequency-matching connector adapter module 154 further comprises a female portion 162 for receiving a transmission line (not shown). The female portion 162 comprises receiving sections 164, 166 in the adapter shell module 156 and in the adapter core 158 respectively, as is well known in the art. The frequency-matching connector adapter module 154 also comprises a male portion 168 for engaging a standard connector (not shown). At the male portion 168, the adapter core 158 protrudes from the adapter shell module 156 in order to engage the standard connector, as is well known in the art.
The frequency-matching connector adapter module 154 further comprises a frequency-matching portion 170. The frequency-matching portion 170 is characterized by at least one section 172, 174, 176 of the adapter shell module 156 having an inner diameter differing from the inner diameter of the remainder of the adapter shell module 156. The number, diameters and lengths of the sections are designed such that the configurable high frequency switch 118 is matched to a narrow high-frequency band surrounding a desired operating frequency (i.e. a desired frequency range). The dimensions may be determined by any method known in the art.
It will be understood by those skilled in the art that a variety of similar frequency-matching adapters, having different numbers, diameters and lengths of sections can be used in various embodiments of the frequency-matching adapter core and adapter shell modules. The dimensions and shape of each frequency-matching adapter core and adapter shell module are selected to optimize the performance of the configurable high frequency coaxial switch 118 in a desired limited bandwidth around the required operating frequency.
Reference is now made to
Reference is now made to
Reference is now made to
In summary, looking to the various switch structures presented in
A section from the frequency-matching port component modules described herein can be modeled as a transfer scattering matrix (Janusz A. Dobrowolski, Introduction to Computer Methods for Microwave Circuit Analysis and Design, Artech House Inc., ISBN 0-89006-505-5, 1991, pp. 30) as given by:
Where: gi, γi, Zi are the section parameters: length, propagation constant and characteristic impedance respectively, ZN is the port reference impedance (50 Ω), and cosh and tanh are the hyperbolic cosine and hyperbolic tangent, respectively. Because the frequency-matching port component modules are cascaded sections of transmission lines with air (vacuum) as dielectric, the propagation constant γi, is given by:
γi=αCi+j·βi (3)
In equation (3), the attenuation constant αCi is due only to the properties of the inner and outer conductors, and is given by:
In equation (4), f=frequency, Di=inner diameter of the outer conductor, si=outer diameter of the inner conductor, ρD/s=electric resistivity of the outer conductor and inner conductor respectively, μ0=vacuum permeability (4·π·10−7 H/m), the phase constant is:
where λ=wavelength of the signal, and the characteristic impedance is:
For the whole frequency-matching port component 54 the transfer scattering matrix is therefore:
where n=number of sections in the frequency-matching port component module and gi, Di and si are the length and diameters of each section.
Reference is now made to
At a first step 214 of the method 212, the manufacturer of the configurable high frequency coaxial switch 50 identifies the limited high frequency range for which the performance of the configurable high frequency coaxial switch must be optimized in the desired application.
At a second step 216, the manufacturer of the configurable high frequency coaxial switch 50 identifies the geometrically identical and geometrically different ports 26 in the configurable high frequency coaxial switch 50. This can be done experimentally using a Vector Network Analyzer and measuring the scattering parameters for a required frequency range.
At the second step 216, if the replaceable frequency-matching port component modules 54 are frequency-matching connector modules 58, then it is necessary to de-embed the frequency-matching connector modules 58 from the measurement results. Characterizing the frequency-matching connector modules 58 used in the measurement can be done either by measurement or by modeling them as cascaded coaxial sections.
At the second step 216, if the frequency-matching port component modules 54 are frequency-matching connector adapters 124, the de-embedding step is not necessary because the scattering parameters fully characterize the RF path. In both cases the scattering parameters matrix has to be transformed to its transfer scattering form which is more useful for cascaded sections. The following formula can be used to achieve this:
where [S] is the scattering parameters matrix measured for each frequency point and the transfer scattering matrix [T] has its parameters defined in terms of wave variables normalized to the reference impedances of each port (i.e. 50 Ω).
Next, at a third step 218, the user selects the appropriate replaceable frequency-matching port component modules 54, in the form of either a frequency-matching connector module 58 or in the form of a frequency-matching connector adapter module 124 used in conjunction with a standard connector, for each port 26 of the configurable high frequency coaxial switch 50. The geometry of the frequency-matching port component modules 54 is related to the desired limited high frequency range, and the geometry of the port 26. The overall transfer scattering matrix of the switch housing module and the frequency-matching port component modules is the product of the corresponding transfer scattering matrices. This can be converted to the scattering parameters matrix format as:
The optimization consists in finding the parameters n, gi, Di, si such as to minimize
in the desired frequency range.
At a fourth step 220, the manufacturer installs the appropriate frequency-matching port component modules 54 with the ports 26, and engages the transmission lines 36 with the frequency-matching port component modules 54.
While certain features of the various embodiments have been illustrated and described herein, many modifications, substitutions, changes, and equivalents will now occur to those of ordinary skill in the art. It is, therefore, to be understood that the appended claims are intended to cover all such modifications and changes that fall within the scope of the embodiments described herein.
Number | Name | Date | Kind |
---|---|---|---|
3478282 | Smith | Nov 1969 | A |
4780692 | Kiedrowski | Oct 1988 | A |
5132644 | Knorr | Jul 1992 | A |
5434548 | Thompson et al. | Jul 1995 | A |
6043440 | Sun et al. | Mar 2000 | A |
6252473 | Ando | Jun 2001 | B1 |
6650210 | Raklyar et al. | Nov 2003 | B1 |
6856212 | Kwiatkowski et al. | Feb 2005 | B2 |
6870454 | Vladimirescu et al. | Mar 2005 | B1 |
6951941 | Kwiatkowski | Oct 2005 | B2 |
20040113714 | Kwiatkowski et al. | Jun 2004 | A1 |
20040155725 | Kwiatkowski | Aug 2004 | A1 |
20050052265 | Vladimirescu et al. | Mar 2005 | A1 |
20060176124 | Mansour et al. | Aug 2006 | A1 |
Number | Date | Country |
---|---|---|
1 431 991 | Jun 2004 | EP |
1 445 819 | Aug 2004 | EP |
1 513 176 | Mar 2005 | EP |
56-076601 | Jun 1981 | JP |
Number | Date | Country | |
---|---|---|---|
20090033444 A1 | Feb 2009 | US |