This application is a national stage of PCT/KR2015/005505 filed on Jun. 2, 2015, which claims priority to Korean Patent Application No. 10-2015-0029742 filed on Mar. 3, 2015, the entire contents of which are incorporated by reference.
Embodiments of the present invention relate to a chip-to-chip interface using a microstrip circuit and a dielectric waveguide.
Demand for bandwidth is increasing in wired communications, which requires high speed, low power, and low cost I/O. In conventional copper interconnects, attenuation due to skin effect or the like limits system performance. In order to compensate for losses in the conventional copper interconnects, penalties are applied in terms of power, cost and the like, and the penalties are exponentially increased as a data rate, transmission distance, or the like is increased.
Since a microstrip circuit according to the embodiments of the invention may provide a transmission signal close to a single sideband signal to a receiver through interaction with a waveguide, it may utilize a twice wider available bandwidth compared to a dual sideband demodulation scheme, and may perform effective data transmission with a wider bandwidth compared to a RF wireless technique due to cutoff channel characteristics exhibiting high roll-off.
Further, the waveguide enables high-speed data communication, and the microstrip circuit including a microstrip-to-waveguide transition (MWT) may transmit a wideband signal while minimizing reflection at a discontinuity. The waveguide may reduce radiation losses and channel losses by enclosing a dielectric with a metal cladding.
Furthermore, although the microstrip circuit according to one embodiment of the invention is described as being used for a board-to-board interface employing a waveguide, the present invention is not limited thereto and may be applied to various fields where a transmission signal may be transmitted with a microstrip line.
For example, the present invention may be applied to an RF transmission or reception antenna system, or to a transmitter and a receiver wired to each other.
A board-to-board interconnect apparatus according to one embodiment of the invention comprises: a waveguide which transmits a signal from a board on the side of a transmitter to a board on the side of a receiver and has a metal cladding; and a microstrip circuit which is connected to the waveguide and has a microstrip-to-waveguide transition (MWT), wherein the microstrip circuit matches a microstrip line and the waveguide, and adjusts a bandwidth of a first predetermined frequency band among frequency bands of the signal to provide the signal to the receiver.
The microstrip circuit may comprise: a microstrip feeding line which supplies the signal in a first layer; a probe element which adjusts the bandwidth of the first frequency band; a slotted ground plane including a slot for minimizing a ratio of reverse-traveling waves to forward-traveling waves in a second layer; a ground plane including vias for forming an electrical connection between the slotted ground plane and the ground plane in a third layer; and a patch for radiating the signal at a resonance frequency.
The probe element may have a characteristic impedance greater than a characteristic impedance of the microstrip feeding line.
The probe element may be connected to an end of the microstrip feeding line, and may have a predetermined width and length.
The length of the probe element may be determined based on a wavelength of the resonance frequency, and the width of the probe element may be 40 to 80% of the width of the microstrip feeding line.
The probe element may adjust the bandwidth of the first frequency band by adjusting a slope of an upper cutoff frequency band.
A microstrip circuit according to one embodiment of the invention comprises: a microstrip feeding line which supplies a signal in a first layer; a probe element which adjusts a bandwidth of a first predetermined frequency band among frequency bands of the signal; a slotted ground plane including a slot for minimizing a ratio of reverse-traveling waves to forward-traveling waves in a second layer; a ground plane including vias for forming an electrical connection between the slotted ground plane and the ground plane in a third layer; and a patch which radiates the signal at a resonance frequency.
The probe element may have a characteristic impedance greater than a characteristic impedance of the microstrip feeding line.
The probe element may be connected to an end of the microstrip feeding line, and may have a predetermined width and length. The length of the probe element may be determined based on a wavelength of the resonance frequency.
The width of the probe element may be 40 to 80% of the width of the microstrip feeding line.
The probe element may adjust the bandwidth of the first frequency band by adjusting a slope of an upper cutoff frequency band.
Since a microstrip circuit according to the embodiments of the invention may provide a transmission signal close to a single sideband signal to a receiver through interaction with a waveguide, it may utilize a twice wider available bandwidth compared to a dual sideband demodulation scheme, and may perform effective data transmission with a wider bandwidth compared to a RF wireless technique due to cutoff channel characteristics exhibiting high roll-off.
Hereinafter, embodiments of the present invention will be described with reference to the accompanying drawings. Although the limited embodiments are described in the following, these embodiments are examples of the invention and those skilled in the art may easily change the embodiments.
The embodiments of the invention may implement single sideband demodulation by adjusting a bandwidth of an upper cutoff frequency band of a transmission signal. For example, a slope of the upper cutoff frequency band may be adjusted through a microstrip circuit that well matches a microstrip line with a waveguide. When a carrier frequency is brought close to the upper cutoff frequency while link frequency characteristics are made to have a sharp roll-off at the upper cutoff frequency, an upper sideband signal is suppressed so that a lower sideband signal may be outputted from the microstrip circuit on the transmitter side and demodulation using the lower sideband signal may be implemented on the receiver side.
Further, the embodiments of the invention may include all the contents related to the invention among those disclosed in Korean Patent Application No. 10-2013-0123344 of the same assignee.
For example, the embodiments of the invention may provide improved interconnects instead of electrical wired lines. The waveguide may be a dielectric waveguide having a metal cladding, and may replace conventional copper lines.
Further, the waveguide uses a dielectric with frequency-independent attenuation characteristics, and thus may achieve a high data rate even with no or little additional compensation at a receiver side or a receiving end. Parallel channel data transmission may be feasible through a vertical combination of the waveguide and a PCB. A PCB having a waveguide for a board-to-board interconnect between the transceiver I/O may be defined as a board-to-board interconnect apparatus.
For example, an interconnect apparatus according to one embodiment of the invention may comprise a waveguide, a transmitting-end board, a receiving-end board, a board-to-fiber connector, a microstrip feeding line, a probe element, a slotted ground plane, a ground plane, and a patch. Here, the interconnect apparatus may further comprise vias connecting the two ground planes to each other.
The board-to-fiber connector is provided to maximize space (area) efficiency by securely fixing a plurality of waveguides to the PCB to bring the waveguides as close to each other as possible. Physically, the flexible nature of the waveguide may support connecting any endpoints at any location in free space. The metal cladding of the waveguide may keep the overall transceiver power consumption constant regardless of the length of the waveguide. Further, the metal cladding may isolate interference of signals in other channels and adjacent waveguides. Here, the interference may cause bandwidth-limiting problems.
The patch-type microstrip-to-waveguide transition (MWT) coupled to a slot may minimize reflection between the microstrip and the waveguide. The microstrip-to-waveguide transition transmits a microstrip signal as a waveguide signal, which may have the advantage of low cost. This is because it may be manufactured through a general PCB manufacturing process.
A microstrip circuit according to one embodiment of the invention may comprise a microstrip feeding line, a probe element, a slotted ground plane, a ground plane, and a patch. The probe element may be provided in the microstrip circuit that well matches the microstrip line and the waveguide so as to adjust a slope of an upper cutoff frequency band. When the microstrip circuit brings a carrier frequency close to the upper cutoff frequency while causing link frequency characteristics to have a sharp roll-off at the upper cutoff frequency, an upper sideband signal is suppressed so that a lower sideband signal may be outputted from the microstrip circuit at the receiving end. Accordingly, the signal outputted to the receiver through the waveguide and the microstrip circuit may be a lower sideband signal, and demodulation may be implemented using the lower sideband signal at the receiver.
As described above, the microstrip circuit according to one embodiment of the invention may match the microstrip line and the waveguide to provide only single sideband data or data focused on the single sideband as an output of the microstrip circuit at the receiving end, without reflection in a predetermined band.
Referring to
Here, the waveguide signal outputted by the MWT may be transmitted along the waveguide 101, and may be converted into a microstrip signal in an MWT 105 on a receiver-side board. Similarly, a signal received by the MWT on the receiver-side board may be transmitted along a transmission line 106 and may proceed to a 50 ohm-matched receiver input 107. Here, the dielectric waveguide may transmit the signal from the transmitter-side board to the receiver-side board.
Referring to
That is, as shown in
From this simplified model, the relationship between the reflected waves and the transmitted waves may be modeled by Equations (1) to (3) as below.
Here, s denotes attenuation along the waveguide; r1ejα1 denotes a complex reflection coefficient at the transition from the transmission line to the waveguide (hereinafter, “R1”); t1ejβ1 denotes a complex transmission coefficient at the transition from the transmission line to the waveguide (hereinafter, “T1”); r2ejα2 denotes a complex reflection coefficient at the transition from the waveguide to the transmission line (hereinafter, “R2”); and t2ejβ2 denotes a complex transmission coefficient at the transition from the waveguide to the transmission line (hereinafter, “T2”).
A scattering matrix (e.g., S-parameter) for the interconnect modeled as a two-port network may be represented by Equations (4) to (7) as below.
In Equations (4) to (7), S11 is a reflection coefficient at port 1; S12 is a voltage gain from port 2 to port 1; S21 is a voltage gain from port 1 to port 2; S22 is a reflection coefficient at port 2; E is defined as ejkl where k denotes a wavenumber of a propagating wave and l denotes a length of the interconnect; Img{x} denotes the imaginary part of x; and Re{x} denotes the real part of x.
Here, the E-tube refers to a combination of a transmitting-end board including a microstrip circuit, a waveguide, and a receiving-end board including a microstrip circuit.
As can be seen from the S-parameter results indicating the characteristics of the E-tube channel shown in
Since the waveguide is a dispersive medium, the boundary condition of the waveguide may be expressed in terms of the relationship between a propagation constant β and a frequency w. It can be seen that a group delay dβ/dw for the waveguide is inversely proportional to the frequency as shown in
The graphs shown in
The oscillation present in the results for the S-parameters and the group delay may be caused by the following facts. The reflected waves that occur in an impedance discontinuity undergo some attenuation as they are propagated, which may create a phenomenon similar to what happens in a cavity resonator. These waves may be scattered back and forth within the waveguide to stabilize standing waves.
These problems may be resolved by methods or strategies including 1) making a reflection coefficient (r2) as small as possible, 2) ensuring a relatively small level of channel loss while making accurate attenuation along the waveguide, and 3) constructing a waveguide using a material with low permittivity.
These strategies may be verified by Equations (5) to (7). Therefore, the MWT in the present invention may be used for the purpose of making a lower reflection coefficient (r2).
Further, as can be seen from a graph of a simulation result for a group delay (in seconds s) vs. frequency (in Hz) of the waveguide as shown in
As shown in
That is, the microstrip circuit according to one embodiment of the invention may well match the microstrip line and the waveguide to adjust a slope of an upper cutoff frequency band, and may bring a carrier frequency close to an upper cutoff frequency while causing link frequency characteristics to have a sharp roll-off at the upper cutoff frequency, thereby providing the receiver with the transmission signal focused on a lower sideband signal having a less delay change.
The embodiments of the invention may provide a transmission signal focused on a lower sideband signal to a receiver, and thus may utilize an available bandwidth twice wider than that of a dual sideband demodulation scheme.
Further, the embodiments of the invention may perform effective data transmission with a bandwidth wider than that of a RF wireless technique due to cutoff channel characteristics exhibiting high roll-off.
The high roll-off may be achieved by mutual interaction of a microstrip circuit including an MWT of a transmitting end, a waveguide, and a microstrip circuit including an MWT of a receiving end.
Referring to
The waveguide 700 includes a metal cladding 710 and may be connected to the microstrip circuit 800 as shown in
Here, the metal cladding 710 may enclose the waveguide 700. For example, the metal cladding 710 may include a copper cladding, and the patch element 803 may include a microstrip line. The patch element 803 may radiate a signal to the waveguide 700 at a resonance frequency, or may radiate a signal to an RF circuit at a resonance frequency when it is wired to the RF circuit.
The metal cladding 710 may enclose the waveguide 700 in a predetermined form. For example, the metal cladding 710 may be formed to expose a middle portion of the waveguide 700, or may be punctured to expose a specific portion of the waveguide 700. The form of the metal cladding is not limited thereto the foregoing, and may include a variety of forms.
One end of the waveguide 700 may indicate an isometric projection of a tapered waveguide (not shown), which may enable impedance matching between dielectrics used for the waveguide 700 and the microstrip circuit 800 on the board. For example, the proportionality of the length of the metal cladding 710 in the length of the waveguide 700 may be designed based on the length of the waveguide 700.
Further, since the size of the waveguide 700 determines impedance of the waveguide 700, the optimal impedance may be efficiently found by linearly shaping at least one of both ends of the waveguide 700. That is, at least one of both ends of the waveguide 700 may be tapered for impedance matching between the dielectric waveguide and the microstrip circuit (not shown). For example, at least one of both ends of the waveguide may be linearly shaped to optimize the impedance of the dielectric waveguide with the highest power transfer efficiency.
Furthermore, the waveguide 700 may be firmly fixed to the board using a board-to-fiber connector. For example, the waveguide 700 may be vertically connected to at least one of the transmitter-side board and the receiver-side board through the board-to-fiber connector.
The microstrip circuit may be formed on a board of a three-layer structure.
The microstrip circuit 800 may transmit only single sideband data, e.g., a lower sideband signal of a transmission signal, without reflection in a predetermined band, by matching the microstrip line and the waveguide 700. That is, the microstrip line and the waveguide are matched using the microstrip circuit, and the microstrip circuit of the transmitting end, the waveguide, and the microstrip circuit of the receiving end may interact with each other so that only the lower sideband signal of the transmission signal inputted to the microstrip circuit of the transmitting end is provided to the receiver through the output of the microstrip circuit of the receiving end.
A microstrip feeding line 801 and a probe element 808 may be located in a first layer as shown in
The patch element 803 and a ground plane 804 (
Here, the patch element 803 is coupled to the microstrip feeding line 801 by current induced in the direction in which current on the microstrip feeding line 801 flows, e.g., in the same direction as the direction X as shown in
The microstrip feeding line 801 may supply or feed a transmission signal to the microstrip circuit 800, and the probe element 808 may adjust a bandwidth of a first predetermined frequency band among frequency bands of the transmission signal.
Here, the bandwidth of the first frequency band may be the bandwidth of the frequency band corresponding to an upper sideband signal of the transmission signal, and the bandwidth of the frequency band corresponding to the upper sideband signal may be adjusted by the width and length of the probe element 808.
The probe element 808 is provided in the microstrip circuit that well matches the microstrip line and the waveguide so as to adjust a slope of an upper cutoff frequency band. The microstrip circuit brings a carrier frequency close to the upper cutoff frequency while causing link frequency characteristics to have a sharp roll-off at the upper cutoff frequency, thereby suppressing the upper sideband signal of the transmission signal. Here, the probe element 808 may adjust a slope of the upper cutoff frequency band with respect to the upper sideband signal of the transmission signal such that high roll-off occurs at the upper cutoff frequency, thereby providing only a single sideband signal to the receiver.
That is, the probe element 808 may cause high roll-off to the slope of the upper cutoff frequency band of the E-tube characteristics, so that only a specific frequency band signal (e.g., a lower sideband signal) of the transmission signal may be transmitted to the receiver.
The probe element 808 may have a characteristic impedance greater than a characteristic impedance of the microstrip feeding line 801, and may be connected to an end of the microstrip feeding line 801 and have a predetermined width and length.
The length L (
Further, the width of the probe element 808 (the length parallel to an H-plane) may be 40 to 80% of the width of the microstrip feeding line 808.
As described above, the microstrip line and the waveguide are matched using the microstrip circuit including the probe element, and the microstrip circuit of the transmitting end, the waveguide, and the microstrip circuit of the receiving end may interact with each other to adjust a slope of an upper cutoff frequency band with respect to an upper sideband signal of the transmission signal inputted to the microstrip circuit of the transmitting end, and to cause high roll-off to occur at the upper cutoff frequency, thereby providing the receiver with only a lower sideband signal, or with the transmission signal focused on the lower sideband signal.
The slotted ground plane 802 may include a slot for minimizing a ratio of reverse-traveling waves to forward-traveling waves in the second layer.
Here, the sizes of the slot and the aperture may be important factors in signal transmission and reflection. The sizes of the slot and the aperture may be optimized by repetitive simulations to minimize the ratio of reverse-traveling waves to forward-traveling waves.
Here, the slot and the patch element 803 form a stacked geometry, and the stacked geometry may be one of the ways to increase the bandwidth.
The ground plane 804 and the slotted ground plane 802 form an electrical connection through vias 807 as shown in
A substrate 805 (
Another core substrate 806 (
The width of the microstrip feeding line 801, substrate thickness, slot size, patch size, via diameter, spacing between the vias, waveguide size, and waveguide material may be changed depending on a specific resonance frequency of the microstrip circuit and modes of traveling waves along the waveguide, which will be apparent to those skilled in the art.
The cutoff frequency and impedance of the waveguide may be determined by the size of an intersecting surface and the type of employed material. As the size of the intersecting surface of the waveguide is increased, the number of TE/TM modes that may be propagated may be increased, which may lead to an improvement in an insertion loss of the transition. In
Further, the characteristics of the transition may be determined by a propagation mode of the waveguide, the slot, and a resonance frequency of the patch element 803.
As shown in
As described above, the microstrip circuit according to one embodiment of the invention may maximize a roll-off for an upper sideband signal of a transmission signal inputted to a microstrip feeding line through interaction between a microstrip circuit of a receiving end, a waveguide, and a microstrip circuit of a transmitting end using a probe element, thereby providing a receiver with the transmission signal focused on a lower sideband signal so that the receiver may receive the transmission signal focused on the lower sideband signal and demodulate only the single sideband signal.
Although the present invention has been described in terms of the limited embodiments and the drawings, those skilled in the art may make various modifications and changes from the above description. For example, appropriate results may be achieved even when the above-described techniques are performed in an order different from the above description, and/or when the components of the above-described systems, structures, apparatuses, circuits and the like are coupled or combined in a form different from the above description, or changed or replaced with other components or equivalents.
Therefore, other implementations, other embodiments, and equivalents to the appended claims will fall within the scope of the claims.
Number | Date | Country | Kind |
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10-2015-0029742 | Mar 2015 | KR | national |
Filing Document | Filing Date | Country | Kind |
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PCT/KR2015/005505 | 6/2/2015 | WO | 00 |
Publishing Document | Publishing Date | Country | Kind |
---|---|---|---|
WO2016/140401 | 9/9/2016 | WO | A |
Number | Name | Date | Kind |
---|---|---|---|
20070085626 | Lee et al. | Apr 2007 | A1 |
20080266196 | Shi | Oct 2008 | A1 |
20100148891 | Sano | Jun 2010 | A1 |
20100225410 | Margomenos et al. | Sep 2010 | A1 |
20130127563 | Gritters et al. | May 2013 | A1 |
20140184351 | Bae et al. | Jul 2014 | A1 |
Number | Date | Country |
---|---|---|
2004530325 | Sep 2004 | JP |
2006500835 | Jan 2006 | JP |
2006191077 | Jul 2006 | JP |
2010141644 | Jun 2010 | JP |
101375938 | Mar 2014 | KR |
2013152191 | Oct 2013 | WO |
2014104536 | Jul 2014 | WO |
Entry |
---|
International Searching Authority, International Search Report issued in PCT/KR2015/005505 dated Jan. 29, 2016, 2 pages. |
Number | Date | Country | |
---|---|---|---|
20180040937 A1 | Feb 2018 | US |