KR20180043417A - Optical waveguide element and millimeter wave bidirectional interconnects using the same - Google Patents

Abstract

Disclosed are an optical waveguide element and a millimeter wave bidirectional interconnect using the same. The millimeter wave bidirectional interconnect of the present invention includes an uplink transmission/reception part including an uplink transmitter for transmitting a first frequency signal of a millimeter wave and a downlink receiver for receiving a second frequency signal of a millimeter wave, a downlink transmission/reception part including an uplink receiver for receiving a first frequency signal and a downlink transmitter for transmitting a second frequency signal; and an optical waveguide element made of a plastic optical fiber and connecting the uplink transmission/reception part and the downlink transmission/reception part. It is possible to transmit the transmission rate of millimeter communication over 10 Gbps at a low cost.

Description

[0001] Optical waveguide element and millimeter wave bidirectional interconnect using same [0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an interconnect, and more particularly, to an optical waveguide device and a millimeter-wave bidirectional interconnect using the same, which improve transmission distance and transmission speed of millimeter wave communication.

Millimeter wave technology is a technology to transmit and receive data using carrier frequency of 30GHz ~ 300GHz band, and it is an active area of research and development with wireless communication technology.

The millimeter wave has a short wavelength, which enables miniaturization of circuits and parts, and it can have a very high data transmission capacity because it uses much higher frequency than the frequency used in microwave. Therefore, millimeter wave can achieve super-multiple communication, which is much higher than current communication, but the loss caused by transmission in wireless space is very difficult to commercialize.

Particularly, when line-of-sight is not secured, a transmission loss of 10 dB or more is added. To overcome this, a beam forming technique has been studied. However, expensive parts are required.

Therefore, it is necessary to study the advantages of millimeter-wave technology and to overcome the disadvantages of transmission loss.

Korean Patent Publication No. 10-2013-0132538 (Apr.

SUMMARY OF THE INVENTION An object of the present invention is to provide an optical waveguide device having a transmission loss of 1 to 2 dB while transmitting a transmission distance of millimeter-wave communication in a free space of 1 m or more, and a millimeter-wave bidirectional interconnect using the optical waveguide device.

It is another object of the present invention to provide an optical waveguide device which transmits a transmission rate of millimeter communication in a free space at a low cost at 10 Gbps or more and a millimeter wave bidirectional interconnect using the optical waveguide device.

In order to achieve the above object, a millimeter wave bidirectional interconnect according to the present invention includes: an uplink transceiver including an uplink transmitter for transmitting a first frequency signal having a millimeterfine and a downlink receiver for receiving a second frequency signal having a millimeter- A downlink transceiver including a downlink transmitter for transmitting the first frequency signal and a downlink transmitter for receiving the first frequency signal, and a plastic optical fiber, wherein the uplink transceiver and the downlink transceiver And an optical waveguide element.

The optical waveguide device may further include a plurality of antennas for transmitting and receiving the first frequency signal and the second frequency signal and one of the plurality of antennas at both ends, And a plurality of optical waveguides guiding transmission.

The plurality of antennas may include a first antenna connected to the uplink transmitter and transmitting the first frequency signal, a second antenna connected to the uplink receiver, the second antenna receiving the first frequency signal, A third antenna connected to the transmitter and transmitting the second frequency signal, and a fourth antenna connected to the downlink receiver and receiving the second frequency signal.

The plurality of optical waveguides may include a first optical waveguide having one end connected to the first antenna and the other end connected to the second antenna to guide transmission of the first frequency signal, And a second optical waveguide whose other end is connected to the fourth antenna to guide transmission of the second frequency signal.

The plurality of optical waveguides are characterized by determining a length and a width so that a transmission loss of the first frequency signal and that of the second frequency signal are minimized, respectively.

Further, the optical waveguide device has a coupling loss of 2 to 3 dB when the plurality of antennas and the plurality of optical waveguides are coupled.

The optical waveguide device is characterized in that the first frequency signal and the second frequency signal are transmitted through 1 to 3 m.

Further, the optical waveguide device is characterized in that the transmission loss generated in the transmission is 1 to 2 dB.

The optical waveguide device transmits the first frequency signal and the second frequency signal at a transmission rate of 10 to 30 Gbps.

The optical waveguide device for a millimeter wave bidirectional interconnect according to the present invention includes a first antenna connected to an uplink transmitter and transmitting a first frequency signal having a millimeterfine, a second antenna connected to an uplink receiver, A third antenna connected to the downlink transmitter and transmitting a second frequency signal having a millimeterfine, a fourth antenna connected to the downlink receiver and receiving the second frequency signal, and a plastic optical fiber, And a first optical waveguide connected to the second antenna and guiding transmission of the first frequency signal and a plastic optical fiber, one end of which is connected to the third antenna, and the other end of which is connected to the fourth antenna And a second optical waveguide connected to the second optical waveguide and guiding transmission of the second frequency signal.

The optical waveguide device and the millimeter-wave bidirectional interconnect using the optical waveguide device according to the present invention can transmit a transmission distance of millimeter-wave communication in a free space of 1 m or more while having a transmission loss of 1 to 2 dB.

In addition, the transmission speed of millimeter communication can be transmitted over 10Gbps in free space at low cost.

1 is a conceptual diagram illustrating a millimeter-wave bidirectional interconnect according to the present invention.
2 is a diagram for describing a millimeter-wave bidirectional interconnect according to the present invention.
3 is a view for explaining an optical waveguide device according to the present invention.
4 is a diagram illustrating a transmitter of a millimeter wave bidirectional interconnect according to the present invention.
5 is a diagram illustrating a receiver of a millimeter wave bidirectional interconnect according to the present invention.
FIG. 6 is a diagram for explaining the receiving buffer shown in FIG. 5 in detail.

Conventional millimeter wave communications typically transmit millimeter waves to a wireless channel using millimeter wave technology. As a result, the conventional millimeter wave communication has a limitation in transmission distance due to a high transmission loss occurring in free space.

Therefore, the present invention was invented in consideration of the fact that a high transmission rate can be achieved with a wide bandwidth of a millimeter wave in order to solve such a problem. The present invention can be applied to a chip-to-chip interconnect and a board-to-board interconnet, which are required for a high-speed and high-capacity transmission system. It is possible to gain advantage in price competitiveness.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. In the drawings, the same reference numerals as used in the appended drawings denote like elements, unless indicated otherwise. In the following description of the present invention, a detailed description of known functions and configurations incorporated herein will be omitted when it may make the subject matter of the present invention rather obvious or understandable to those skilled in the art.

FIG. 1 is a conceptual view for explaining a millimeter wave bidirectional interconnect according to the present invention, FIG. 2 is a view for explaining a millimeter wave bidirectional interconnect according to the present invention, and FIG. 3 is a diagram for explaining an optical waveguide device according to the present invention FIG.

Referring to FIGS. 1 to 3, a millimeter wave bidirectional interconnect (hereinafter referred to as an interconnect) 10 has a transmission loss of 1 to 2 dB while transmitting a transmission distance of millimeter wave communication in a free space up to 1 m. Also, the interconnect 10 is transported at 10 Gbps or higher in transmission rate of millimeter communication in free space at low cost. The interconnect 10 includes an uplink transceiver 100, an optical waveguide element 200, and a downlink transceiver 300.

The uplink transceiver 100 includes an uplink transmitter 110 and a downlink receiver 120.

The uplink transmitter 110 transmits a first frequency signal that is millimeterfine. The uplink transmitter 110 includes a first oscillator 111, a first upmixer 113, and a first power amplifier 115. The first oscillator 111 oscillates a first carrier signal having a first frequency. The first oscillator 111 may be an LC-type voltage-controlled oscillator. The first up mixer 113 loads a first base band signal on the first carrier signal. That is, the first up-mixer 113 mixes the first baseband signal and the first carrier signal to generate a first frequency signal. The first frequency signal has a first frequency and comprises a first baseband signal. The first power amplifier 115 amplifies the first frequency signal so that it can be transmitted. At this time, the first power amplifier 115 can amplify the first frequency signal so that the first Doppler antenna 310, which will be described later, can be driven.

The downlink receiver 120 receives a second frequency signal that is millimeterfine. The downlink receiver 120 includes a first low noise amplifier 121, a first injection path 123, a second oscillator 125, a first down mixer 127 and a first output buffer 129. The first low-noise amplifier 121 amplifies the second frequency signal received through the fourth Doppler antenna 340 described later. In this case, the first low-noise amplifier 121 can amplify the data included in the second baseband signal. The output of the first low-noise amplifier 121 is input to the second oscillator 125 through the first injection path 123. Thereby, the second oscillator 125 can quickly oscillate the second carrier signal having the second frequency. The second oscillator 125 may be an LC-type voltage-controlled oscillator. The first down mixer 127 separates the second baseband signal and the second carrier signal included in the second frequency signal. The first output buffer 129 converts and amplifies the separated second baseband signal to be output. Preferably, the first output buffer 129 can convert and amplify the second baseband signal with a voltage signal that is easy to process.

The downlink transceiver 200 includes a downlink transmitter 210 and an uplink receiver 220.

The downlink transmitter 210 transmits a second frequency signal that is millimeterfine. The downlink transmitter 210 includes a third oscillator 211, a second upmixer 213, and a second power amplifier 215. The third oscillator 211 oscillates a second carrier signal having a second frequency. The third oscillator 211 may be an LC-type voltage-controlled oscillator. Here, the second frequency may be a frequency lower than the first frequency. The second upmixer 213 loads the second baseband signal on the second carrier signal. That is, the second upmixer 213 mixes the second baseband signal and the second carrier signal to generate a second frequency signal. The second frequency signal has a second frequency and comprises a second baseband signal. The second power amplifier 215 amplifies the second frequency signal so that it can be transmitted. At this time, the second power amplifier 215 can amplify the second frequency signal so that the third Doppler antenna 330, which will be described later, can be driven.

The uplink receiver 220 receives a first frequency signal that is millimeterfine. The uplink receiver 220 includes a second low noise amplifier 221, a second injection path 223, a fourth oscillator 225, a second down mixer 227 and a second output buffer 229. The second low-noise amplifier 221 amplifies the first frequency signal received through the second Doppler antenna 320 described later. At this time, the second low-noise amplifier 221 can amplify the data included in the first baseband signal. The output of the second low-noise amplifier 221 is input to the fourth oscillator 225 through the second injection path 223. Thereby, the fourth oscillator 225 can rapidly oscillate the first carrier signal having the first frequency. The fourth oscillator 225 may be an LC-type voltage-controlled oscillator. The second down mixer 227 separates the first baseband signal included in the first frequency signal and the first carrier signal. The second output buffer 229 converts and amplifies the separated first baseband signal to be output. Preferably, the second output buffer 229 can convert and amplify the first baseband signal with a voltage signal that is easy to process.

The optical waveguide device 300 connects the uplink transmission / reception unit 100 and the downlink transmission / reception unit 200. The optical waveguide device 300 transmits and receives the first frequency signal and the second frequency signal using the plastic optical fiber. The optical waveguide device 300 includes a plurality of antennas for transmitting and receiving a first frequency signal and a second frequency signal and a plurality of antennas for transmitting a first frequency signal and a second frequency signal, Of the optical waveguide. Here, the antenna may be a Doppler antenna, and the optical waveguide may be a plastic optical waveguide. At this time, since the optical waveguide uses the plastic optical waveguide, the loss caused by the coupling with the antenna can be reduced to 2 to 3 dB.

More specifically, the optical waveguide device 300 includes four antennas 310, 320, 330, 340 and two optical waveguides 350, 360. That is, the optical waveguide device 300 is connected to the uplink transmitter 110, and is connected to the first antenna 310 and the uplink receiver 220, which transmit the first frequency signal, A second antenna 320 is coupled to the downlink transmitter 210 and is coupled to a third antenna 330 and a downlink receiver 120 that transmit a second frequency signal, And an antenna 340. The optical waveguide device 300 further includes a first optical waveguide 350 having one end connected to the first antenna 310 and the other end connected to the second antenna 320 to guide transmission of the first frequency signal, And a second optical waveguide 360 connected to the third antenna 330 and the other end connected to the fourth antenna 340 to guide the transmission of the second frequency signal.

In general, an antenna has a smaller size and a difficulty in coupling with an optical waveguide. However, when a signal is transmitted through an optical waveguide, a higher frequency has a lower loss. Therefore, the present invention can set the first frequency and the second frequency in consideration of the size of the antenna and the correlation between the antenna and the coupling of the optical waveguide. The first optical waveguide 250 and the second optical waveguide 260 can determine the length and width so that the transmission loss of the first frequency signal and the second frequency signal is minimized.

Accordingly, the optical waveguide device 300 can transmit the first frequency signal and the second frequency signal at a transmission rate of 10 Gbps or more, transmit at a transmission distance of 1 m or more, and preferably at a transmission rate of 10 to 30 Gbps , And a transmission distance of 1 to 3 m. Also, the optical waveguide device 300 can lower the transmission loss caused by the transmission of the first frequency signal and the second frequency signal to 1 to 2 dB.

4 is a diagram illustrating a transmitter of a millimeter wave bidirectional interconnect according to the present invention.

Referring to FIG. 4, based on the optical waveguide, the interconnect 10 can use a common circuit for uplink and downlink transmitters. That is, the transmitter 400 of the interconnect includes a transmission oscillator 410, a transmission up mixer 420, and a transmission power amplifier 430.

The transmission oscillator 410 is configured using an LC-type voltage-controlled oscillator, and is capable of frequency tuning through an analog control signal (V _tune ). The transmission up mixer 420 is configured using a balun and is applicable to both uplink and downlink. Here, in order to implement a common circuit diagram of the uplink and the downlink, the lower balun 421 applies only to the downlink, i.e., the second frequency signal, which is relatively lower in frequency than the first frequency signal. The transmitting power amplifier 430 of the final stage is configured using a general millimeter wave power amplifier and may have a lower power gain than a millimeter wave transmitter in free space.

FIG. 5 is a view for explaining a receiver of a millimeter-wave bidirectional interconnect according to the present invention, and FIG. 6 is a diagram for explaining a reception output buffer of FIG. 5 in detail.

Referring to FIG. 5 and FIG. 6, it is possible to use a common circuit for uplink and downlink receivers based on optical waveguides. That is, the receiver 500 of the interconnect includes a receiving low noise amplifier 510, a receiving injection path 520, a receiving oscillator 530, a receiving down mixer 540, a receiving DC offset 550, And an output buffer 560.

The receiving low noise amplifier 510 amplifies the inputted first frequency signal or the second frequency signal. The receiving oscillator 530 is configured using an LC-type voltage-controlled oscillator, and can be controlled by both analog and digital control signals. At this time, the receiver needs to be finely tuned to the same frequency as the transmitter, unlike the transmitter. Therefore, the reception low-noise amplifier 510 is provided with a reception injection path 529 separately and transmits the frequency information of the signal inputted through the reception low noise amplifier 510 to the reception oscillator 530. The receiving downmixer 540 includes a receiving DC offset 550 that compensates for the down-converted baseband signal through negative feedback as it is accompanied by a DC offset error between the differential signals Compensation. Therefore, the output current of the receiving down mixer 540 is converted into a voltage signal that is easy to process the signal through the receiving buffer 560, amplified, and transmitted to the receiving side.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is clearly understood that the same is by way of illustration and example only and is not to be taken by way of limitation in the embodiment in which said invention is directed. It will be understood by those skilled in the art that various changes in form and detail may be made therein without departing from the scope of the appended claims.

10: Interconnect 100: Uplink transmission /
110: uplink transmitter 111: first oscillator
113: first up mixer 115: first power amplifier
120: downlink receiver 121: first low-noise amplifier
123: first injection path 125: second oscillator
127: first down mixer 129: first output buffer
200: downlink transmitter / receiver 210: downlink transmitter
211: third oscillator 213: second up mixer
215: second power amplifier 220: uplink receiver
221: second low noise amplifier 223: second injection path
225: fourth oscillator 227: second down mixer
229: second output buffer 300: optical waveguide element
310: first antenna 320: second antenna
330: Third antenna 340: Fourth antenna
350: first optical waveguide 360: second optical waveguide
400: Transmitter of the interconnect 410: Transmitter oscillator
420: Transmission Up Mixer 421: Balun
430: transmitting power amplifier 500: receiver of the interconnect
510: receiving low-noise amplifier 520: receiving injection path
530: Receiving oscillator 540: Receiving down mixer
550: Receive DC offset 560: Receive output buffer

Claims (10)

An uplink transceiver including an uplink transmitter for transmitting a first frequency signal having a millimeterfine and a downlink receiver for receiving a second frequency signal having a millimeterfine;
A downlink transceiver including an uplink receiver for receiving the first frequency signal and a downlink transmitter for transmitting the second frequency signal; And
An optical waveguide formed of a plastic optical fiber and connecting the uplink transceiver and the downlink transceiver;
Lt; RTI ID = 0.0 > interconnect. ≪ / RTI > The method according to claim 1,
The optical waveguide device includes:
A plurality of antennas for transmitting and receiving the first frequency signal and the second frequency signal; And
A plurality of optical waveguides connected to one of the plurality of antennas at both ends and guiding transmission of the first frequency signal and the second frequency signal;
Wherein the first and second interconnects comprise a first and a second interconnect. 3. The method of claim 2,
Wherein the plurality of antennas comprises:
A first antenna connected to the uplink transmitter and transmitting the first frequency signal;
A second antenna coupled to the uplink receiver, the second antenna receiving the first frequency signal;
A third antenna coupled to the downlink transmitter, the third antenna transmitting the second frequency signal; And
A fourth antenna coupled to the downlink receiver, the fourth antenna receiving the second frequency signal;
Wherein the first and second interconnects comprise a first and a second interconnect. The method of claim 3,
The plurality of optical waveguides include:
A first optical waveguide having one end connected to the first antenna and the other end connected to the second antenna to guide transmission of the first frequency signal; And
A second optical waveguide having one end connected to the third antenna and the other end connected to the fourth antenna to guide transmission of the second frequency signal;
Wherein the first and second interconnects comprise a first and a second interconnect. 3. The method of claim 2,
The plurality of optical waveguides include:
Wherein the length and width are determined such that transmission losses of the first frequency signal and the second frequency signal are minimized, respectively. 3. The method of claim 2,
The optical waveguide device includes:
And wherein coupling between the plurality of antennas and the plurality of optical waveguides has a coupling loss of 2 to 3dB. The method according to claim 1,
The optical waveguide device includes:
Wherein the first frequency signal and the second frequency signal are transmitted from 1 to 3 m. 8. The method of claim 7,
The optical waveguide device includes:
Wherein the transmission loss generated in the transmission is 1 to 2dB. The method according to claim 1,
The optical waveguide device includes:
Wherein the first frequency signal and the second frequency signal are transmitted at a transmission rate of 10 to 30 Gbps. A first antenna coupled to the uplink transmitter and transmitting a millimeter-first frequency signal;
A second antenna coupled to the uplink receiver for receiving the first frequency signal;
A third antenna coupled to the downlink transmitter to transmit a millimeter-order second frequency signal;
A fourth antenna coupled to the downlink receiver for receiving the second frequency signal;
A first optical waveguide formed of a plastic optical fiber and having one end connected to the first antenna and the other end connected to the second antenna to guide transmission of the first frequency signal; And
A second optical waveguide formed of a plastic optical fiber and having one end connected to the third antenna and the other end connected to the fourth antenna to guide transmission of the second frequency signal;
And an optical waveguide element for the millimeter wave bidirectional interconnect.

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