Photonically routed transmission line

A method of dynamically routing a transmission line in a photosensitive layer including optically switching elements and a system to dynamically route a transmission line are described. The method includes determining dimensions of the transmission line based on a radio frequency signal for transmission through the transmission line. The method also includes controlling a light source to illuminate a portion of the optical switching elements of the photosensitive layer according to the dimensions to route the transmission line.

BACKGROUND

The present disclosure relates to switchable conductivity. In many applications, mechanical supports are used for electrical connections. For example, a printed circuit board (PCB) provides mechanical support for the electrical connections between components. The PCB includes conductive traces that are placed onto an insulating substrate. The form of each conductive trace is fixed after the design is complete, while the function of the traces can be controlled using discrete components such as switches. Jumper wires may be added to implement the alternate routing as an alternative, but these connections can become loose and affect the integrity of the conductive traces such that only pathways that were anticipated during the design and layout phase of the PCB are practicable.

SUMMARY

According to one embodiment, a method of dynamically routing a transmission line in a photosensitive layer including optically switching elements includes determining dimensions of the transmission line based on a radio frequency signal configured for transmission through the transmission line; and controlling a light source to illuminate a portion of the optical switching elements of the photosensitive layer according to the dimensions to route the transmission line.

According to another embodiment, a system to dynamically route a transmission line includes a photosensitive layer disposed on at least a portion of at least one side of a mechanical support; a controller configured to output dimensions of the transmission line based on a radio frequency signal configured for transmission through the transmission line; and a light source configured to controllably illuminate a portion of the photosensitive layer according to the dimensions to route the transmission line.

DETAILED DESCRIPTION

As noted above, when alternative conductive paths (e.g., electrical connections, radio frequency pathways) are needed, they must be pre-placed and additional components, such as switches, must be included to facilitate any change in connectivity. For example, when a PCB is fabricated, the placement of the components and the connections between them are planned, and the connectivity paths between components are deposited. These connectivity paths carry the current from one component to another, for example. During operation of the circuit, if the connectivity paths need to be changed to modify the circuit for any reason, the change is possible if the PCB was fabricated with the additional connectivity paths as well as switches that facilitate the change. If no such additional paths and switching elements were implemented during fabrication of the PCB, the PCB must be modified to facilitate the change. Embodiments of the system and method detailed herein relate to dynamically configurable conductivity paths based on optically switchable elements. These switchable connectivity paths do not require pre-planning or additional components like switches. The system and method discussed herein apply to any surface or mechanical support with conductive traces or paths (e.g., circuit board, radome lining).

Additional embodiments described herein relate specifically to photonically routed transmission lines for transmission of radio frequency (RF) energy. Because the propagation of RF energy through a transmission line is affected by the cross-sectional geometry of the line and the conductivity of the material from which it is made, the switchable connectivity pathways defining transmission lines additionally include a determination of specific dimensions for the photoexcitation described below.

FIG. 1is a cross-sectional view of a device with dynamically configurable conductivity pathways according to an embodiment of the invention. The embodiment shown inFIG. 1includes a substrate110to mechanically support a photosensitive layer120with the configurable conductivity paths, but the exemplary embodiment does not limit the mechanical supports and shapes contemplated for the device. The substrate110is non-conductive and may be a dielectric layer. While the photosensitive layer120is shown as being deposited over one entire surface of the substrate110inFIG. 1, the photosensitive layer120may be deposited over at least a portion of at least one side of the substrate110. The photosensitive layer120includes at least one type of optical switching element (OSE)130, and may also include at least one type of field transmission element (FTE)140, and one or more types of an immobilizing material (IM)150. When the IM150is present, the OSE130and FTE140are fillers in the IM150, which is the body of the film making up the photosensitive layer120. The IM150is made from a material or a blend of materials that are transparent to high energy photons and provides mechanical and environmental stability to the fillers (OSE130and FTE140). For example, the IM150may be a polymethyl methacrylate (PMMA), poly isobutylene (PIB), or poly ether imide (PEI). When the IM150is present, the filling factor must be sufficiently high for the fillers (OSE130and FTE140) to be in electrical contact with one another but must also be sufficiently low such that the integrity of the resulting film is upheld. A ratio of FTE140to OSE130is material-dependent. A lower ratio (increasingly more OSE130than FTE140) provides for higher resolution of conductive features when the photosensitive layer120is illuminated but higher transparency (radio frequency transparency) when the photosensitive layer120is not illuminated, while a higher ratio (increasingly more FTE140than OSE130) provides for higher conductivity when the photosensitive layer120is illuminated and lower transparency (radio frequency transparency) when the photosensitive layer120is not illuminated.

The OSE130is a nanostructured semiconductor material that is sensitive to high energy photons. For example, the OSE130may include quantum dots (IIB-VIA, IVA-VIA, or IIIA-VA), vanadium oxide (VO2), silicon nanoparticles, a semiconducting polymer, or other semiconducting material. The OSE130material can be induced to an electrically conductive state by the absorption of the photon. That is, when a light source illuminates the OSE130, causing photoexcitation, the illuminated OSE130becomes conductive. Accordingly, a path of OSE130material may be illuminated to define a conductivity path within the photosensitive layer120. The structure of the OSE130includes one or more materials that passivate the surface of the OSE130and thereby alter the material properties of the OSE130. The FTE140is an inherently conductive nanostructured material. For example, the FTE130may include silver, copper, or gold nanoparticles (or another intrinsically conductive material) and may define the nano-particulate equivalent of a transmission line. Exemplary materials that may be used as FTE130(and may also be used as passivating material or IM150) include poly(3,4-ethylenedioxythiophene) poly(styrenesulfonate) (PEDOT:PSS), polyaniline (PANI), and poly(3-hexylthiophene) (P3HT). The FTE140may also include one or more passivating materials. These passivating materials may or may not be the same as the passivating materials in the structure of the OSE130. Exemplary passivating materials include n-butylamine (n-But), ethanedithiol (EDT), and ethanediamine (EDA).

FIG. 2shows a system to dynamically configure a conductive pathway according to an embodiment of the invention. As noted with reference toFIG. 1, the exemplary arrangement of the photosensitive layer120on the substrate110is not intended to limit the arrangement of the device. Both the OSE130and FTE140are shown as part of the photosensitive layer120. The OSE130that are illuminated by a light source230(e.g., ultraviolet light. x-ray, visible, or other high energy light) are indicated by210. While the light source230is shown separated from the photosensitive layer120inFIG. 2for clarity, the light source230may be disposed directly on the photosensitive layer120to accurately control the areas of the photosensitive layer120that are illuminated. In alternate embodiments, backlighting or projection may be used to illuminate the OSE130. A controller240may be used to control the light source230. The controller240includes an input interface242(e.g., keyboard, output of another circuit), one or more processors244, one or more memory devices246, and an output interface248that outputs the signal to control the light source230. The OSE130(210) that is illuminated forms conductive layers while the unilluminated OSE130(dark regions) are insulating. The specific regions that are conductive or that create conductive pathways between components when the device shown inFIG. 2is incorporated in a circuit, for example, can be altered dynamically by changing the pattern of illumination. Thus, without apriori knowledge of conductive paths needed in the device, for example, the illumination by the light source230may be adjusted to dynamically form the conductivity path in the photosensitive layer120.

FIG. 3is a process flow of a method of forming a dynamically configurable conductivity pathway according to an embodiment of the invention. At block310, disposing a mechanical support includes disposing a substrate110for a circuit, for example. As noted above, the mechanical support may be any non-conductive surface on which the photosensitive layer120may be disposed. The mechanical support may be a radome, for example. At block320, disposing the photosensitive layer120includes depositing the photosensitive layer120on at least part of at least one side of the mechanical support. As detailed above, the photosensitive layer120may include OSE130and FTE140that may be fillers in an IM150. Controlling a light source230at block330facilitates changing conductivity of the OSE130in the photosensitive layer120to dynamically configure conductivity paths.

As noted above, additional embodiments relate specifically to dynamically routing RF energy in a transmission line. For example, the device shown inFIG. 2may be a circuit board for an antenna, and the substrate110may be transparent to RF and include an internal ground plane. Components and connectors may be mounted to the surface or edge of the device. The dimensions (e.g., width, depth) of a transmission line (e.g.,220inFIG. 2) affect the propagation of transmitted RF energy through the line. That is, the transmission line dimensions must be chosen based on the wavelength of RF energy to be transmitted, because the dimensions affect impedance, and impedance matching maximizes power transfer by preventing reflections. Thus, un-optimized transmission line dimensions will result in higher loss of signal. Accordingly, unlike the transmission of direct current through a conductive pathway, which is unaffected by the shape of the conductivity pathway trace, for example, the transmission of RF energy through a transmission line requires a determination of the proper dimensions for the transmission link. As noted above, the light source230may be used (controlled by a controller240) to illuminate OSE130and thus initiate conductivity within the illuminated area of the photosensitive layer120. As described below, when the necessary dimensions for the illuminated area are determined and the light source230is used to illuminate OSE130within the determined dimensions, a transmission link for routing of RF energy may be dynamically configured. The conductive traces created by the light source230form adaptable planar microwave circuits. Exemplary applications for the resulting device include filters, limiters, phase shifters, matching networks, patch radiators, and power dividers. Just as the conductivity pathways discussed above may be added or removed based on illumination by the light source230, transmission lines may also be added or removed. In addition, the transmission lines may be modified (based on a modification in RF energy to be transmitted) by changing the dimensions of illumination with the same area of the photosensitive layer120.

FIG. 4is a process flow of a method of dynamically routing a transmission line according to an embodiment of the invention. At block410, modeling may be conducted. At block420, experimenting may be used. A combination of modeling and experimentation (e.g., modelling experimentally) may also be used for determining the dimensions needed for the transmission line (at block430) based on the RF energy to be transmitted. Determining the dimensions of the transmission line may be done by the same controller240(FIG. 2) that controls the light source230or by one or more other controllers that provide input to the controller24that controls the light source230. At block440, illuminating the photosensitive layer120(the OSE130) initiate conductivity in the illuminated area of the photosensitive layer120which corresponds with the dimensions determined for the transmission line (430). The illuminated OSE130are conductive to alternating current during photoexcitation. The OSE130are insulating to alternating current when not illuminated. Noting that radio frequency signals are carried by alternating currents with frequencies in the range of 3 kilohertz to 300 gigahertz, the excitation of OSE130within the photosensitive layer120with particular dimensions facilitates dynamic creation of transmission lines for routing radio frequency energy. Accordingly, dynamically creating the proper transmission line (through the illumination at block440) for impedance matching facilitates inserting RF energy for transmission at block450.