KR100358976B1 - ASK Transceiver - Google Patents

Abstract

The present invention relates to an ASK transceiver for an NRD guide capable of both transmitting and receiving in an ASK method using an NRD guide. The oscillator is configured by a gun diode mount with a gun diode mounted between upper and lower conductor plates with a half-wavelength or less of the frequency used, and half of the power is transferred to the primary circulator through a 3dB coupler. Modulated, radiated from the antenna via the secondary circulator, and received signals are passed through the secondary circulator, input to one terminal of the balance mixer, and when the local oscillation wave is transmitted, a Schottky with two Schottky diodes, respectively. It is configured to obtain IF by diode mount.

Description

ASSK Transceiver {ASK Transceiver}

The non-radioactive dielectric waveguide is made less than half the wavelength of the desired frequency of the conductive parallel plate, and a new concept waveguide is formed by inserting the non-radioactive dielectric line therebetween.

Non-radioactive dielectric waveguides have lower transmission losses than microstrip lines for high frequencies above 30 GHz. In addition, compared with the conventional waveguide, the processing is easier and the circuit configuration is easier.

Because of the low loss in the millimeter wave band of non-radioactive waveguides and the ease of circuit configuration, they are used in radars, local area networks, and the like, and bidirectional communication is required rather than unidirectional communication such as broadcasting. In addition, the use of a single module (Module) requires a specification that can simultaneously transmit and receive.

In the present invention, to implement the NRD guide ASK transceiver of the 60GHz band. In the 60 GHz NRD guide, the distance between the upper and lower conductor plates should be less than half the wavelength, so the height of the NRD guide line was 2.25 mm and the width was 2.5 mm. Therefore, other millimeter wave band transceiver implementations can be applied using the transceiver system of the present invention.

According to the present invention, an oscillation wave is transmitted through a 3 dB coupler for sending an oscillation part and an oscillation wave of the gun diode mount 5 equipped with the gun diode 30 for generating oscillation in the 60 GHz band to the modulator and the balance mixer. The secondary circulator is used to transmit the modulated signal to the ASK modulator with air gaps. The modulated signal is passed to the antenna by the secondary circulator through the primary circulator and constituted as a transmitter. Receiving section which is guided by the antenna and delivered by the secondary circulator to one input terminal of the 3dB coupler of the balance mixer section and mixed with the local oscillation wave transmitted through the 180 degree bend from the oscillator section to obtain IF by two Schottky diode mounts. It consists of.

The present invention constitutes a transmitter in which no gap exists between the Schottky diode mount of the ASK modulator and one terminal of the primary circulator.

In the balance mixer of the receiver of the present invention, a receiver is provided in which there is no gap between the two Schottky diode mounts and the 3 dB coupler.

1 is a perspective view of an ASK transceiver for an NRD guide of the present invention.

2 is a plan view of an ASK transceiver for an NRD guide.

3 is a block diagram for explaining the operation of the ASK transceiver for NRD guide.

Fig. 4: Gun diode mount and strip resonator with gun diode, mode

Perspective view of the oscillator including the sprayer.

Fig. 5: Internal projection of the mode compressor for suppressing the TE mode and the LSE mode

Perspective view.

6 is a change of the center frequency according to the length of the strip resonator.

7 shows the oscillation of the oscillation unit to the balance mixer on the receiving side and the modulator of the transmitter.

3dB coupler conceptual diagram for equal delivery.

8: Change of center frequency according to the distance between two bends of the 3dB coupler

graph.

9: deliver the oscillation wave of the oscillator to the modulator, output the modulated signal,

Primary circulators and antennas with the role of transmitting modulated signals to antennas

Secondary to transfer the signal received from the tena to the balance mixer

Perspective view of the circulator.

10 is a perspective view of a ferrite resonator inserted into primary and secondary circulators.

11 is an internally projected perspective view of the antireflection terminal.

12 is a perspective view of a modulator including a Schottky diode mount for ASK modulation.

Degree.

FIG. 13 is a plan view of an ASK modulator including a flow of incident and reflected waves

14 is a cross-sectional view of an ASK modulator including a flow of incident and reflected waves.

15 is a Schottky diode having a Schottky diode mounted on a dielectric substrate.

Mount top view.

FIG. 16: plane of a balanced mixer showing the flow of RF, LO, and IF

Degree

17 shows characteristics of the conversion loss when the balance mix is used.

graph.

(Explanation of symbols for the main parts of the drawing)

1: Upper conductor plate.

2: Lower conductor plate.

3, 21, 23, 25, 32, 33, 35, 40, 41, 42: NRD guideline.

4: rod antenna.

5: Gun diode mount with gun diode.

6. The oscillation wave generated from the gun diode mount is fed to the NRD guide line.

Strip resonator for

<24> 7: End of antireflection.

<25> 8, 22, 24, 26, 31: mode sprayer.

9: bend 180 degrees.

10: primary circule consisting of ferrite disks (27, 28) and Teflon tube (29)

Ferrite resonator constituting the rotor.

11: between the Schottky diode mount of the modulator and the void of the primary circulator

Equipped with anterior teflon.

12: Schottky diode mount with Schottky diode of modulator.

13: A rear teflon placed behind the Schottky diode mount of the modulator.

14: A ferrite resonator constituting a secondary circulator.

15, 16: behind the Schottky diode mount mounted on the balance mixer

Posterior teflon set.

17, 18: Schottky diode equipped with a Schottky diode of the balance mixer

Mount.

19, 20: 3dB coupler with balanced mixer and two Schottky diode mounts

Anterior teflon placed between.

27, 28: ferrite disk.

29: teflon tube.

30: gun diode.

34: A metal (copper) thin film having a choke shape with different widths at intervals of λ / 4.

36, 38, 39: for impedance matching of NRD guide line and dielectric substrate

High Permittivity Sheet.

37: Schottky diode.

43: Resistive film inserted horizontally and parallel to the NRD guide line.

1 and 2 show a perspective view and a plan view of an ASK transceiver for an NRD guide according to the present invention. In addition, a block diagram is shown in FIG. 3 to explain the operation of the ASK transceiver for the NRD guide. The block diagram of FIG. 3 will be described and each part will be described in detail.

In the block diagram of FIG. 3, oscillation is generated using the gun diode 30, and the oscillated signal is sent to the modulator and the balance mixer using the 3dB coupler. In order to be transmitted to the modulator through a 3 dB coupler, a modulated signal is obtained by using a primary circulator to an ASK modulator with voids, and a modulated signal is passed through a primary circulator to a antenna by a secondary circulator. The signal to be transmitted and received is guided to the antenna and transmitted by the secondary circulator to one input terminal of the 3dB coupler of the balance mixer, and the oscillation wave transmitted from the oscillator is mixed with the local oscillation wave to obtain IF.

In order to generate the oscillation of the 60 GHz band, the gun diode 30 is used as shown in FIG. 4, and the gun diode mount 5 is mounted to dissipate heat generated when the gun diode 30 operates. A bias is applied to 30 to use the strip resonator 6 to supply the oscillated radio wave to the NRD guide line. At this time, in order to suppress the unnecessary mode which occurs, the mode compressor shown in FIG. 5 is inserted.

FIG. 6 is a graph showing the change of the oscillation center frequency according to the rectangular metal thin film length of the strip resonator 6 having a rectangular metal thin film pattern of a dielectric substrate having a dielectric constant of 2.56 and a thickness of 0.3 mm.

In FIG. 7, when a 3dB coupler is formed using two bends having a radius of curvature of 25 mm and a radio wave having an output of a is input, the coupled output is reduced by half. In this case, the change in the frequency that can be combined according to the distance between the two bend is shown in FIG.

The 3dB coupler described above is used as a carrier wave at the transmitter by transmitting an oscillation wave having the same output to the transmitter and the receiver, and is used as a local oscillation wave at the receiver.

9 shows a signal transmitted through a 3dB coupler to an ASK modulator, and a modulated signal transmitted from a primary circulator 10 and a primary circulator for outputting a modulated signal to an antenna 4. Represents the structure of the circulator used in the secondary circulator 14 for transmitting the received signal RF guided to the secondary circulator 14 and the antenna 4 for transmission to the balance mixers 15 and 16. Perspective view.

The circulator is a representative irreversible element. That is, since the asymmetrical form, an unnecessary mode may occur. Since this unnecessary mode causes transmission loss to decrease, the mode sprayers 22 and 24 are disposed between the NRD guide lines 21, 23 and 25 and the ferrite resonators 10 and 14 arranged at 120 degree intervals of the circulator. , 26) can prevent the loss of transmission loss due to the unnecessary mode.

FIG. 10 shows that the ferrite resonators 10 and 14 inserted into the circulator are composed of the ferrite disks 27 and 28 and the Teflon tube 29. The diameters of the ferrite disks 27 and 28 used in the 60 GHz band were 2.8 mm, the thickness was 0.78 mm, and the height of the Teflon tube 29 was 1.69 mm.

FIG. 11 is an antireflection terminal for absorbing reflected waves that may occur in a primary circulator and a 3dB coupler. The groove length shown in the resistive film 43 was 10 mm and the total length was 15 mm. The result was a return loss of 25 dB or less.

12, 13, and 14 are a plan view and a cross-sectional view showing a perspective view and a flow of radio waves together with a modulator for ASK modulation according to the present invention. A gap between the NRD guide line 35 and the Schottky diode mount 12 provides a sharp difference in absorption and reflection so that the front teflon 11 is 1.5 mm, the high dielectric constant sheet is 0.14 mm and the rear teflon is 1.5 mm. It was set as.

FIG. 15 shows a structure in which the Schottky diode 30 is mounted on a 0.3 mm dielectric substrate 12 having a dielectric constant of 2.56.

The balanced mixer of FIG. 16 includes a 3dB coupler and two Schottky diode mounts 17 and 18. Like the ASK modulator, a gap is placed between the two NRD guide lines of the 3dB coupler and the Schottky diode mounts 17 and 18, with the front Teflon 19 and 20 interposed therebetween, and the high dielectric constant sheets 38 and 39 therebetween. The impedance matching was performed to insert the rear Teflon 15 and 16 into the rear of the Schottky diode mounts 17 and 18.

FIG. 17 is a graph showing results of conversion loss according to the IF frequency of a signal received using a balance mixer. A conversion loss of less than 10dB was obtained up to about 800MHz.

When the ASK modulation unit having no gap exists in the modulation unit of the above structure, it is possible to obtain good modulation characteristics over a wide bandwidth.

The conversion loss characteristic for the case where the air gap of the balance mixer of the structure does not exist was able to obtain a value of 10 dB or less up to about 1.2 GHz.

Nowadays, the use of frequency is diversified, attracting attention in various fields such as LAN for millimeter wave band, short range wireless communication for traffic control and various sensors. Each of these systems can meet the requirements of realizing a compact and high performance millimeter wave integrated circuit.

In addition, the present invention has proved the possibility of configuring an integrated circuit in the millimeter wave band. In addition, since a single terminal (Module) can be used for both transmission and reception, two-way communication using a small terminal is possible.

Claims (3)

Mount a gun diode mount to cause millimeter wave oscillation; A 3dB coupler for sending to the ASK modulator and the balance mixer on the receiving side; A primary circulator for sending a millimeter wave of the oscillation unit to the ASK modulation unit and outputting a modulated signal; Mounting an ASK modulator having a gap for obtaining ASK modulation using a millimeter wave transferred from the primary circulator as a carrier wave; Mounting a secondary circulator to transmit a modulated signal transmitted from the primary circulator to an antenna or to send a received RF signal to a balance mixer; An antenna for radiating a modulated signal transmitted from the secondary circulator or for receiving an RF signal; In order to detect the IF signal by mixing the RF signal received from the antenna and the RF signal transmitted through the secondary circulator from the oscillator, an air gap exists between the NRD guide line and the two diode mounts to form a balance mixer. ASK transceiver, characterized in that. The method of claim 1, Between the Schottky diode mount of the ASK modulator and one terminal of the primary circulator An ASK transceiver comprising an ASK modulator with no gaps. The method of claim 1, And a schottky diode mount mounted on the balance mixer of the receiver and a balance mixer having no gap between the NRD guide lines.