JPH0687525B2 - Planar antenna - Google Patents

Description

Detailed Description of the Invention

TECHNICAL FIELD The present invention relates to a planar antenna for receiving satellite broadcasting. [Background Art] In general, a receiving system for receiving a satellite broadcast includes, as shown in FIG. 4, a flat antenna 3 including a flat antenna main body 1 and a down converter 2, a tuner 4, and a television receiver 5. Has been done. Here, the state of the received image reproduced by the television receiver 5 is greatly influenced by the input signal level-to-noise ratio (C / N) input to the tuner 4, and as shown in FIG. When the signal level-to-noise ratio (C / N) falls below 9 dB (threshold level), the overall SN ratio deteriorates sharply and the image becomes extremely bad. This relationship is derived by C / N = G / T + EIRP-51.5 [dB]. Where EIRP
Is a numerical value (reception electric field strength) represented by the product of the transmission power of the broadcasting satellite and the gain of the transmission antenna in the direction of the reception point. The antenna performance index G / T is , G is the gain of the planar antenna body 1, Ta
/ l is the antenna noise of the antenna itself, (1-1 / l) 290
Is noise of the power supply line output from the power supply line, and (NF-1) × 290 is converter noise generated by the down converter 2. As is clear from the above relational expression, if the input signal level to noise ratio (C / N) input to the tuner 4 is to be increased, the antenna gain G is increased or each noise (antenna noise, feed line It can be seen that it is better to reduce the noise (converter noise). However, antenna noise (Ta / l)
Is almost determined by the type of antenna (parabolic type, array type, etc.) and the feed line noise ((1-1 / l) × 290) is determined by the material used, so to obtain a satisfactory received image It is necessary to increase the antenna reception area by increasing the antenna reception area, or decrease the noise figure NF of the down converter 2 to reduce the converter noise. For example, if the input signal level-to-noise ratio C / N = 14 dB is required to obtain a satisfactory received image, the noise figure N
If either F or antenna gain G is determined, the other is also determined. Here, the antenna gain G becomes large as shown in FIG. 6 (however, the relationship between the parabolic antenna diameter D and the antenna gain G). However, if the receiving area of the antenna becomes large, the antenna body becomes large and the weight becomes large, and the installation work of the antenna becomes troublesome, which causes inconvenience for general household use. . Therefore, it is desirable that the receiving area of the antenna be as small as possible, and it is required to lower the noise figure NF of the down converter 2 accordingly. By the way, the down converter 2 is composed of a plurality of active circuits, but as shown in FIG.
When C ₁ , C ₂ ... Cn are connected in series, the noise figure NF of the entire device is NF = F ₁ + (F ₂ −1) / G ₁ + (F ₃ −1) / G ₁ G ₂ + ... (Fn-1) / G ₁ G ₂ ... Gn, and the NF of the entire device is greatly influenced by the NF of the active circuit (front-end low-noise amplifier) C ₁ in the first stage, and the active circuit C _{1 in the} first stage The smaller the loss is, the smaller the NF of the entire device. Therefore, the same input signal level to noise ratio C /
To obtain N, the active circuit C in the first stage with a low noise figure NF
It turns out that it is desirable to use ₁ with low loss. However, in the conventional example, as shown in FIG. 8, the planar antenna body 1 and the down converter 2 are connected via the connector 2a, and the down converter 2 is an active circuit at the first stage. Since the use condition that the amplifying device of the low noise amplifier (eg, GaAs FET, HEMT, etc.) operates with the minimum noise figure NF has not been realized, it is satisfactory when the flat antenna main body 1 having a small receiving area is used. There is a problem that the reception performance for obtaining a possible reception image cannot be obtained. That is, the characteristic impedance of the connector 2a is generally 50
Since the output impedance of the planar antenna body 1 and the input impedance of the down converter 2 are both 50 Ω so that no reflection loss occurs at the connector connection part, the amplification used for the low noise amplifier of the down converter 2 The noise figure characteristic (NF characteristic) of the device (GaAs FET) is as shown in Fig. 9, and the best point (NF = 1.2dB) is not in the vicinity of 50Ω (center part), but at a considerably shifted position (approximately 20 + j20Ω). It has become. Therefore, in the conventional example, an impedance matching circuit that performs impedance matching is added to the signal input section at the front end of the down converter 2, but a loss due to the impedance matching circuit occurs in addition to the loss due to the connector 2a. There was a problem that the noise figure (NF) deteriorates and the reception performance deteriorates. For example, even when using a low-noise amplification device with a noise figure NF of about 1.2 dB at around 12 GHz, the noise figure NF of the downconverter 2 actually deteriorates to 1.6 dB or more, which causes high-definition When trying to obtain a high quality received image, sufficient receiving performance cannot be obtained, so that there is a problem that the receiving area of the planar antenna body 1 must be increased to increase the antenna gain G. there were. [Object of the Invention] The present invention has been made in view of the above points, and an object of the present invention is to enable an amplification device of a low noise amplifier to operate in a state where the noise figure is minimum, and to provide a planar antenna body. It is an object of the present invention to provide a planar antenna which can obtain a sufficient receiving performance even when the receiving area is reduced, and has a simple structure and a low cost.

DISCLOSURE OF THE INVENTION

(Structure) According to the present invention, a grounded conductor plate, a feeding circuit board having a feeding circuit pattern formed thereon, and a radiation circuit board having a radiation circuit pattern formed thereon are stacked at appropriate intervals to form a suspended triplate type planar antenna body. And a low noise amplifier circuit is mounted in the gap between the ground conductor plate and the feeding circuit plate so as to be orthogonal to both plates, and a substrate equipped with an auxiliary ground conductor on the back surface is interposed, The signal input terminal is provided at the end of the board on the side of the power supply circuit board, the signal input terminal is connected to the power supply point of the power supply circuit, and the ground terminal of the amplification device is connected to the auxiliary ground conductor through the through hole provided on the board. By connecting, the amplification device of the low-noise amplifier can be operated with the minimum noise figure, and the reception area of the planar antenna body can be reduced. Even if it is, there is provided a planar antenna which can obtain a sufficient reception performance and has a simple structure and a low cost. (Embodiment 1) FIG. 1 and FIG. 2 show an embodiment of the present invention in which a flat antenna body 1 and a low noise amplifier of a down converter 2 for amplifying an antenna output and converting it to a low frequency are integrated. As shown in FIG. 1, the planar antenna body 1 includes a ground conductor plate 10, a feeding circuit board 11 having a feeding circuit pattern formed thereon, and a radiation circuit board 12 having a radiation circuit pattern formed thereon. It is a suspended triplate type in which layers are stacked with appropriate intervals 13a and 13b. Further, the feeding circuit board 11 and the radiating circuit board 12 are formed by forming conductors 11a and 12a of a circuit pattern on the insulating substrates 11b and 12b, respectively, and by covering the insulating sheets 11c and 12c on 11a and 12a. ing. Further, in the gap 13a between the ground conductor plate 10 and the power supply circuit plate 11, a substrate having a low noise amplifier circuit mounted so as to be orthogonal to both plates 10 and 11 and having an auxiliary ground conductor 17 on the back surface.
16 is interposed, and a gate terminal 15g which is a signal input terminal of an amplification device (for example, GaAs FET) 15 of a low noise amplifier is provided at the end of the feed circuit board 11 of the substrate 16 at the end. The gate terminal 15g is connected to the feeding point of the feeding circuit, and the source terminal 15s, which is the ground terminal of the amplification device 15, is connected to the auxiliary ground conductor 17 through the through hole 18 provided in the substrate 16. Here, in the embodiment, the gate terminal 15g of the amplification device 15 connected to the feeding point of the feeding circuit is
Is connected to the conductor 11a exposed by peeling off the insulating sheet at the feeding point portion of the feeding circuit board 11 by soldering. Also,
A negative bias voltage is applied to the gate terminal 15g of the amplification device 15 via the gate bias supply line 19a, and a positive bias voltage is applied to the drain terminal 15d via the drain bias supply line 19b. Therefore, both bias voltages are set so that the amplification device 15 operates at the lowest value of the noise figure NF. Furthermore, the input impedance at the point where the noise figure NF of the amplification device 15 made of GaAaFET operates at the lowest is around (20 + j20) Ω, so that the impedance at the feeding point of the feeding circuit should be the above input impedance in advance. A power supply circuit pattern is designed (an impedance conversion pattern is formed if necessary). The output line 19c is connected to the output connector 20
The down converter 2 is connected to the output connector 20. In this case, it goes without saying that the low noise amplifier at the front end of the down converter 2 can be omitted. Now, in the embodiment, since the gate terminal 15g, which is the signal input terminal of the amplification device 15 of the low noise amplifier for amplifying the antenna output, is directly connected to the feeding point of the feeding circuit without using the connector, Compared to the connected conventional example, loss is reduced, and an impedance matching circuit to match the characteristic impedance of the connector is not required.
Can be operated with a minimum noise figure NF. Therefore, even when the receiving area of the planar antenna body 1 is reduced, a good received image can be obtained, and the receiving performance can be improved. Further, the substrate 16 having the auxiliary ground conductor 17 on the back surface is interposed between the ground conductor plate 10 and the feeding circuit plate 11, and since the substrate 16 and the auxiliary ground conductor 17 function as a spacer, Gap between board 10 and power supply circuit board 11
It is possible to omit the spacers arranged to hold the 13a constant, which simplifies the structure and reduces the cost. (Embodiment 2) FIG. 3 shows another embodiment, in which the gate terminal 15g of the amplifying device 15 is opposed to the conductor 11a at the feeding point of the feeding circuit pattern via the insulating substrate 11b for electrostatic induction coupling. The overlap length is of the wavelength of the received microwave.
It is set to 1/4 (λg / 4). The rest of the configuration and operation are exactly the same as in the first embodiment. Now, in the present embodiment, since the connection between the gate terminal 15g of the amplification device 15 and the conductor 11a at the feeding point of the feeding circuit pattern is performed by electrostatic induction coupling in a non-contact manner, soldering work becomes unnecessary. Can be easily assembled, and moreover,
As the conductor 11a forming the power supply circuit pattern of the power supply circuit board 11, aluminum, which is cheaper than copper and is resistant to corrosion, can be easily connected. [Advantages of the Invention] As described above, according to the present invention, a grounded conductor plate, a feeding circuit board having a feeding circuit pattern formed thereon, and a radiation circuit board having a radiation circuit pattern formed thereon are stacked at appropriate intervals to create a suspended triad. Form a plate type planar antenna body,
A low noise amplifier circuit is mounted in the gap between the grounding conductor plate and the power feeding circuit plate so as to be orthogonal to both plates, and a board equipped with an auxiliary grounding conductor is provided on the back side, and the signal input terminal of the amplification device of the low noise amplifier is inserted. It is provided at the end of the board on the side of the power supply circuit board, the signal input terminal is connected to the power supply point of the power supply circuit, and the ground terminal of the amplification device is connected to the auxiliary ground conductor through the through hole provided on the board. Yes, it is possible to operate the amplification device of the low-noise amplifier in the state where the noise figure is minimum, and it is possible to obtain sufficient reception performance even when the reception area of the planar antenna body is small, and the configuration is simple. There is an effect that a low cost planar antenna can be provided.

[Brief description of drawings]

FIG. 1 is an enlarged sectional view of an essential part of an embodiment of the present invention, FIG. 2 is a perspective view of an essential part of the same as above, FIG. 3 is an enlarged sectional view of an essential part of another embodiment, and FIG. Schematic configuration diagram of the system, No. 5
FIGS. 7 to 7 are explanatory diagrams of the same operation, FIG. 8 is a schematic configuration diagram of a conventional example, and FIG. 9 is an explanatory diagram of the same operation. 1 is a plane antenna main body, 2 is a down converter, 3 is a plane antenna, 10 is a ground conductor plate, 11 is a feeding circuit plate, 12 is a radiation circuit plate, 13a and 13b are gaps, 15 is an amplifying device, and 15s is a ground terminal ( Source terminal), 15g is a signal input terminal (gate terminal), 16 is a substrate, 17 is an auxiliary ground conductor, and 18 is a through hole.

Claims (2)

[Claims] 1. A suspended triplate type planar antenna body is formed by laminating a grounding conductor plate, a feeding circuit plate having a feeding circuit pattern formed thereon, and a radiation circuit plate having a radiation circuit pattern formed thereon at an appropriate interval. The low noise amplifier circuit is mounted in the gap between the grounding conductor plate and the power supply circuit board so that it is orthogonal to both plates, and a board with an auxiliary grounding conductor on the back side is interposed, and the signal is input from the amplifier device of the low noise amplifier. A terminal is provided at the end of the power supply circuit board of the board, the signal input terminal is connected to the power supply point of the power supply circuit, and the ground terminal of the amplification device is connected to the auxiliary ground conductor through the through hole provided in the board. A planar antenna characterized by being connected. 2. A power feeding circuit pattern is formed on an insulating substrate to form a power feeding circuit board, and a signal input terminal of an amplifying device is opposed to a conductor at a power feeding point of the power feeding circuit pattern via the insulating substrate to electrostatically. The planar antenna according to claim 1, wherein the planar antenna is inductively coupled.