JPS63131089A - Radar responder - Google Patents

Abstract

PURPOSE:To enable the realization of an improved electric characteristic, by providing a receiving section and a transmitting section in respective harmetic- structured cobalt alloy containers. CONSTITUTION:Radio wave from a radar is received with a receiving slot antenna 6a in a receiving module 6 and then, detected directly with a receiver built into a receiver housing section 6b. A direct detection output from the receiver is amplified with a video amplifier while a signal for driving response transmission and a signal for modulated transmission frequency are formed therefrom with a signal control circuit simultaneously with the reception of the radio wave and these signals are inputted into a transmitter built into a transmitter housing section 7b of a transmitting module 7. When the signals are inputted, the transmitter outputs a high frequency response signal to be transmitted to a radar or the like from a transmitting slot antenna section 7a. Here, the modules 6 and 7 are built in a harmetic construction with joints put together completely by electric welding or the like thereby enabling the realization of an improved electric characteristic as antenna.

Description

DETAILED DESCRIPTION OF THE INVENTION [Field of Industrial Application] The present invention relates to a radar response device that transmits a high frequency response signal in synchronization with a high frequency signal such as a microwave signal received from a radar.

[Prior Art] FIG. 4 is a perspective view showing a conventional radar response device (radar transponder), and FIG. 5 is a perspective view showing a cross section of a main part of the conventional device. In these figures, 1 is a reception slot antenna section that receives radio waves (high frequency signals) from a radar (not shown), and 2 is a transmission slot antenna section that transmits a response signal in response to reception of high frequency signal No. 18 in the reception slot antenna section 1. , 3 is an antenna structure, and as shown in FIGS. 4 and 5, this antenna structure 3 integrates and reinforces the receiving slot antenna section 1 and the transmitting slot antenna section 1-antenna section 2 in series. And,
Each joint is soldered.

The slot antenna portion 1.2 is made of brass and is constructed by soldering the joint portions, and has slot portions (slit-like elongated holes) 11 formed on its upper and lower surfaces.

Further, reference numeral 4 denotes a shielding plate for preventing radio waves from going around, and this shielding plate 4 is provided at the boundary between the receiving slot antenna section 1 and the transmitting slot antenna section 2.

Furthermore, 5 is an end plate for making it possible to attach the device itself to other objects (such as a transmitter or receiver (not shown)), and this end plate 5 includes the receiving slot antenna section 1 and the transmitting slot antenna section 2. provided at each end.

Next, the operation will be explained. Radio waves (high frequency signals) from a radar (not shown) are received by the reception slot antenna section 1 and then directly detected by a receiver (not shown) connected to the reception slot antenna section 1.

The direct detection output from the receiver is amplified by a video amplifier, and at the same time as the radio wave is received, a response transmission driving signal and a transmission frequency modulation signal are formed in the signal control circuit, and these signals are is input to a transmitter (not shown) connected to the transmission slot antenna unit 2.

When this transmitter receives the above signal, it outputs a high frequency response signal and transmits the response signal to the transmission slot antenna section 2.
It is then propagated into space and transmitted to radar, etc.

[Problems to be Solved by the Invention] The conventional radar response device is configured as described above, and since the structure of the slot antenna parts 1 and 2 is formed by soldering, it is possible to avoid defects in the soldering. If the antenna is completely damaged, its electrical characteristics as an antenna may be impaired. Furthermore, complete soldering requires a great deal of effort and extremely difficult work.

In addition, the slot portions 11 of the receiving slot antenna portion 1 and the transmitting slot antenna portion 2 are formed by penetrating a metal plate (brass) and are exposed to the outside air, so outside air flows in through the slot portions 11. As a result, the microwave electronic components used in the receiver and transmitter connected to the slot antenna sections 1 and 2, respectively, are contaminated, which poses problems such as adversely affecting the reliability of the device.

Therefore, it is possible to seal the slot part 11 with glass, but since the slot antenna parts 1 and 2 are made of Yellow 8, and the expansion coefficients of brass and glass are different, it is impossible to seal the slot part 11 with glass. there were.

This invention was made to solve the above-mentioned problems, and it enables the formation of a structure without soldering work, achieves good electrical characteristics, and prevents contamination from outside air. [Means for Solving Problems] A radar response device according to the present invention includes a receiving section that receives a high frequency signal from a radar; A transmitting section that transmits a response signal in response to reception by the receiving section is provided in each cobalt alloy container having a hermetic structure.

[Function] In the radar response device of the present invention, the receiving section and the transmitting section are provided in a cobalt alloy container and have a hermetic structure in which the joints are completely joined by electric welding etc., so it is suitable as an antenna. In addition to realizing excellent electrical characteristics, the inside of the container becomes completely airtight, thereby preventing the inside of the container from being contaminated by outside air.

Furthermore, in the container in the receiving section and the transmitting section,
When a slot antenna is constructed by forming a slot portion exposed to the outside air, since the container is made of cobalt alloy, the slot portion can be sealed with glass without causing problems with the coefficient of expansion. Become.

[Embodiment of the Invention] Hereinafter, an embodiment of the present invention will be described with reference to the drawings. 1st
Figures 1 to 3 show a radar response device according to an embodiment of the present invention. Figure 1 is a perspective view thereof, Figure 2 is a perspective view showing a cross section of its main parts, and Figure 3 is a receiving section and a transmitting section thereof. FIG. In these figures, 6 is a receiving module as a receiving unit that receives radio waves (high frequency signals) from a radar (not shown), and 7 is a transmitting unit that transmits a response signal in response to the reception of the high frequency signal in the receiving module 6. The module 8 is an antenna structure, and the antenna structure 8 is a rectangular tube-shaped structure that houses a receiving module 6 and a transmitting module 7 in series, as shown in FIGS. 1 and 3. Note that the antenna structure 8 is made of resin.

Further, as shown in FIG. 3, the receiving module 6 includes a receiving slot antenna section 6a having a slot section 11, and a receiver storage section 6 containing microwave electronic components such as a receiver.
Kovar as a cobalt alloy container with b.
The container is made of iron-nickel-cobalt alloy (trade name: iron-nickel-cobalt alloy), and its joints have a hermetic structure that is completely joined by electric welding.

Further, the transmitting module 7 is also constructed of a Kovar container as a cobalt alloy container, which includes a transmitting slot antenna section 7a having a slot section 11, and a transmitter storage section 7b containing microwave electronic components such as a transmitter. The joints have a hermetic structure that is completely joined by electric welding.

Note that 4 is a shielding plate for preventing radio waves from going around, and this shielding plate 4 is provided at the boundary between the receiving module 6 and the transmitting module 7.

Further, 5 is an end plate for enabling attachment of the device itself to another object, and this end plate 5 is provided at each end of the receiving module 6 and the transmitting module 7.

Next, the operation will be explained. Similar to the conventional device, radio waves (high frequency signals) from a radar (not shown) are received by the reception slot antenna section 6a of the reception module 6, and then sent to the receiver storage section 6b of the reception module 6.
The signal is directly detected by the receiver built into the

The direct detection output from the receiver is amplified by a video amplifier, and at the same time as the radio wave is received, a response transmission driving signal and a transmission frequency modulation signal are formed in the signal control circuit, and these signals are is input to the transmitter built in the transmitter storage section 7b of the transmitting module 7.

When this transmitter receives the above signal, it outputs a high frequency response signal, propagates the response signal into space through the transmission slot antenna section 7a of the transmission module 7, and transmits it to a radar or the like.

By the way, in the device of this embodiment, the receiving module 6 and the transmitting module 7 are constructed as a hermetic structure in which the joints are completely joined by electric welding or the like using a container made of Kovar alloy, so that conventional soldering is not necessary. There is no need for any additional parts, making it possible to achieve extremely good electrical characteristics as an antenna.

Furthermore, by housing the receiving module 6 and the transmitting module 7 in the antenna structure 8 in a hermetically sealed manner, even if the slot portion 11 is formed in each slot antenna portion 6a, 7a, the inside of the receiving module 6 and the transmitting module 7 is completely sealed. kept airtight. Therefore, each module 6.7
Outside air flows into the module 6.7, preventing electronic devices such as receivers and transmitters from being contaminated by the outside air, thereby greatly increasing the reliability of the device.

Note that in the above embodiment, the receiving module 6 and the transmitting module 7 are housed within the antenna structure 8;
The antenna structure 3 may be integrated with the antenna structure 3 similar to that of the conventional device.

In this case, the slot portion 11 of each module 6.7 will be exposed to the outside air, but in the device of the present invention, the slot portion 11 is formed in a container made of Kovar alloy, which is suitable as a glass material. Unlike conventional brass, each slot portion 11 can be sealed with glass without causing problems regarding the coefficient of expansion, which has the advantage of ensuring airtightness within each module 6.7.

Further, in the above embodiment, the receiving module 6 and the transmitting module 7 are provided in separate containers, but they may be configured in a common container.

Furthermore, the device of the present invention can be applied to a microwave response device, etc., and produces the same effects as described above.

Further, as the antenna structure 8, a radome made of resin may be used.

[Effects of the Invention] As described above, according to the present invention, the receiving section that receives a high-frequency signal from the radar and the transmitting section that transmits a response signal in response to reception by the receiving section are each constructed with a hermetic structure. Since it is constructed by installing it in a cobalt alloy layered container, it is possible to form the structure without soldering, and it is possible to achieve extremely good electrical characteristics, as well as to achieve complete airtightness inside the container, allowing for contamination from outside air. This will reliably prevent this and greatly improve the reliability of the device.

In particular, when a slot antenna is constructed by forming a slot portion exposed to the outside air in the container, since the container is made of a cobalt alloy, the slot portion can be There is also the advantage that the container can be easily sealed with glass, and the airtightness inside the container can be reliably maintained.

[Brief explanation of the drawing]

1 to 3 show a radar response device according to an embodiment of the present invention. FIG. 4 is a perspective view showing a transmitter, and FIGS. 4-5 show a conventional radar response device. FIG. 4 is a perspective view thereof, and FIG. 5 is a perspective view showing a cross section of a main part thereof. In the figure, 6...--receiving module as a receiving unit, 7...- transmitting module as a transmitting unit. In addition, in the figures, the same reference numerals indicate the same or corresponding parts.

Claims (4)

[Claims] (1) A cobalt alloy container comprising a receiving section that receives a high-frequency signal from the radar and a transmitting section that transmits a response signal in response to reception by the receiving section, and the receiving section and the transmitting section each have a hermetic structure. A radar response device characterized by being provided in. (2) The radar response device according to claim 1, wherein the cobalt alloy container is built into an antenna structure. (3) The radar response device according to claim 1, wherein the receiving section and the transmitting section are each provided in separate containers made of cobalt alloy. (4) The radar response device according to claim 1, wherein the receiving section and the transmitting section are both provided in a common cobalt alloy container.