Patent Description:
As one of the core devices that implements the mobile communication network coverage, the base station antenna is an important part of the mobile communication system, which is used to convert high frequency electromagnetic energy in the transmission line into electromagnetic waves in free space or convert electromagnetic waves in the free space to high frequency electromagnetic energy, whose design directly affects the quality of the entire mobile communication system.

With the increase of mobile communication users and the occurrence of new applications and demands, the demand for base station antennas is becoming larger and larger, and the requirements for the base station antennas are increasingly strict, which is often required to meet the requirements of the circuit parameters and radiation parameters, such as standing wave ratio meeting the indicator requirements, stable gain, and stable radiation pattern, within a wide frequency band, such as <NUM> ~ <NUM>, so that <NUM>, <NUM>, and <NUM> and other communication system requirements can be satisfied.

The amplitude provided by the conventional feeding network in its operating frequency band for the radiating unit is a constant value, i.e., the amplitude does not vary with frequency or varies lightly. The amplitude allocation makes the lobe width of the wideband antenna change greatly in its operating frequency band, which presents the change tendency that the larger the frequency, the narrower the lobe width. When the frequency is sufficiently high, the antenna width becomes narrow, and ultimately the antenna coverage is insufficient, which seriously affects the quality of the communication system. <CIT> discloses a power coupler including a differential phase shifter for differentially adjusting the relative phase between signals on a pair of signal lines, and a hybrid coupler which is coupled to the pair of signal lines. Document "<NPL>, discloses a phase shifter covering the whole UWB frequency range with small phase error. Document "<NPL>, discloses an analysis method of wideband loaded-stub phase shifters and a fast designing procedure.

The object of the present invention is to overcome the deficiencies of the prior art and to provide a feeding network for improving a convergence of a lobe width of a wideband antenna.

In order to achieve the above object, the present invention provides the following technical solutions: a feeding network for improving a convergence of a lobe width of a wideband antenna according to claim <NUM>, wherein the feeding network comprises a first power divider, a delay line, a <NUM>° electric bridge and a second power divider,.

The delay line includes a transmitting microstrip line body and a U-shaped portion formed by bending the transmitting microstrip line body.

A distance of a bottom end of the transmitting microstrip line body from a bottom end of the U-shaped portion is greater than a wavelength of a feeding network input signal.

Or, the delay line includes a first main transmitting microstrip line and a short-circuit microstrip line connected in a T-shape, and a non-short-circuit end of the short-circuit microstrip line is connected to the first main transmitting microstrip line, and a short-circuit end of the short-circuit microstrip line is provided with a grounding vias.

A length of the short-circuit microstrip line is one quarter of the wavelength of the signal input to the feeding network.

Or, the delay line includes a second main transmitting microstrip line and an open-circuit microstrip line connected in a T-shape, and a non-open-circuit end of the open-circuit microstrip line is connected to the second main transmitting microstrip line.

A length of the open-circuit microstrip line is one-half of the wavelength of the signal input to the feeding network.

Preferably, phases of the two signals input to the <NUM>° electric bridge are reduced as the frequency increases.

Preferably, the first power divider and the second power divider are 3dB Wilkinson power dividers.

Preferably, an output power distribution ratio of the second power divider is <NUM>:N, wherein N is a natural number greater than <NUM>.

The beneficial effect of the present invention is:.

Reference numerals: <NUM>. feeding network, <NUM>. first power divider, <NUM>. delay line, 121a. transmitting microstrip line body, 121b. U-shaped portion, 122a. first main transmitting microstrip line, 122b. short-circuit microstrip line, 122c. grounding vias, 123a. second main transmitting microstrip line, 123b. open-circuit microstrip line, <NUM>. <NUM>° electric bridge, <NUM>. second power divider, <NUM>. first radiating unit, <NUM>. second radiating unit, <NUM>. third radiating unit.

The technical solution of the embodiments of the present invention will be described in connection with the drawings of the present invention below.

The feeding network disclosed in the present invention applied to a single beam antenna changes the phase of any one of the signals input to a <NUM>° electric bridge <NUM> by using the delay line <NUM>, thereby adjusting the phase difference between the signals input to the <NUM>° electric bridge <NUM> to change the amplitude allocation of the signals output from the <NUM>° electric bridge <NUM>, such that different amplitudes are allocated to each radiating unit of the wideband antenna respectively, and the amplitude obtained by each radiating unit can vary as the frequency varies, which effectively improves the convergence of horizontal lobe width of the wideband antenna and improves the coverage of the base station.

As shown in <FIG>, a feeding network <NUM> for improving a convergence of a lobe width of a broadband antenna disclosed in the present invention includes a first power divider <NUM>, a delay line <NUM>, a <NUM>° electric bridge <NUM>, and a second power divider <NUM>, wherein an input end of the first power divider <NUM> is used as the input port of the feeding network, one of the output ends of the first power divider <NUM> is coupled to an input end of the delay line <NUM>, and the other of the output ends of the first power divider <NUM> is directly coupled to one of the input ends of the <NUM>° electric bridge <NUM> for converting a signal input to the feeding network into two signals with the same amplitude and the same phase; an output end of the delay line <NUM> is coupled to the other of the input ends of the <NUM>° electric bridge <NUM> for changing a phase of one of the two signals output from the first power divider <NUM> and then input the changed signal to the <NUM>° electric bridge <NUM>, such that the two signals input to the <NUM>° electric bridge <NUM> have the same amplitude and different phases; one of the output ends of the <NUM>° electric bridge <NUM> is directly coupled to a radiating unit of the wideband antenna and the other of the output ends of the <NUM>° electric bridge <NUM> is coupled to the input end of the second power divider <NUM>, so as to convert the two signals with same amplitude and different phases into two signals with different amplitudes and same phase; the output ends of the second power divider <NUM> are directly coupled to radiating units of the wideband antenna for converting a signal output from the <NUM>° electric bridge <NUM> into multiple signals.

In particular, the first power divider <NUM> converts the signal input to the feeding network into two signals, and the phase of one of the two signals is changed by the delay line <NUM> to be input to the <NUM>° electric bridge <NUM>, while the other of the two signals is directly input to the <NUM>° electric bridge <NUM>, the <NUM>° electric bridge <NUM> changes the received two signals into the two signals with same phase and different amplitudes, and sends one of the two signals with same phase and different amplitudes to radiating units via the second power divider14, and the other of the two signals with same phase and different amplitudes to a radiating unit directly.

In the present embodiment, one output end of the <NUM>° electric bridge <NUM> is coupled to a first radiating unit <NUM> and a third radiating unit <NUM>, via the second power divider14, respectively, and the other output end is coupled directly to a second radiating unit <NUM>. In other embodiments, the two output ends of the <NUM>° electric bridge <NUM> can be coupled to a plurality of radiating units via a power divider. Further, both the first power divider <NUM> and the second power divider <NUM> are 3dB Wilkinson power dividers, wherein the output power distribution ratio of the second power divider <NUM> is <NUM>: N (N is a natural number greater than <NUM>). In this embodiment, N is <NUM>, and in other embodiments, N can be determined based on the number of radiating units in the wideband antenna.

In order to enable the wideband antenna to achieve a better lobe width convergence, the phase distribution of the two signals input to the <NUM>° electric bridge <NUM> should satisfy the linear relationship as shown in <FIG>. It can be seen from <FIG> that as the frequency increases, the phases of the two signals present a downward trend, and the phase difference between the two signals input to the <NUM>° electric bridge <NUM> varies as the frequency varies, e.g., at <NUM>, the phase of one signal is A, the phase of the other signal is B, the phase difference between the two signals is C, and e.g., at <NUM>, the phases of the two signals are same, the phase difference between the two signals is <NUM>, and e.g., at <NUM>, the phase of one signal is A', the phase of the other signal is B', and the phase difference between the two signals is C'. By adjusting the phase difference between the signals input to the <NUM>° electric bridge <NUM>, the phase difference varies as the frequency varies, and the amplitude distribution of the signal output from the <NUM>° electric bridge <NUM> varies as the frequency varies, such that the lobe width of the wideband antenna presents extreme convergence in the entire frequency band. As shown in the table below, the amplitude and phase table of three radiating units allocated by the <NUM>° electric bridge <NUM> at different frequencies.

It can be seen from the above table, at the same frequency, the amplitudes allocated for the different radiating units are different, meanwhile at different frequencies, the amplitudes allocated for the different radiating units are also different. It can be seen that the amplitude allocation of the signals output from the <NUM>° electric bridge <NUM> is changed effectively by changing the phase differences between signals input to the <NUM>° electric bridge <NUM> at different frequencies. This amplitude allocation way variation as the frequency varies can cause the lobe width of the wideband antenna to present extreme convergence in <NUM> - <NUM>.

In connection with <FIG>, the delay lines <NUM> of three different structures are used to adjust the phase differences of signals input to the <NUM>° electric bridge <NUM> at different frequencies. Specifically, as shown in <FIG>, a delay line <NUM> formed by a conventional microstrip line includes a transmitting microstrip line body 121a and a U-shaped portion formed by bending the transmitting microstrip line body downward. In order that one of the signals satisfies the phase distribution as shown in <FIG>, a distance of a bottom end of the transmitting microstrip line body away from a bottom end of the U-shaped portion is greater than a wavelength of the signal input to the feeding network.

As shown in <FIG>, a delay line <NUM> formed by a short-circuit microstrip line 122b includes a first main transmitting microstrip line 122a and a short-circuit microstrip line 122b, wherein one end of the short-circuit microstrip line 122b is connected to the first main transmitting microstrip line 122a, and the opposite end is a short-circuit end, and the short-circuit end is provided with a grounding vias 122c. In this embodiment, the first main transmitting microstrip line 122a and a short-circuit microstrip line 122b are preferably connected in a T-shape. Further, in order that one of the signals satisfies the phase distribution as shown in <FIG>, the length of the short-circuit microstrip line 122b is a quarter of the wavelength of the signal input to the feeding network.

As shown in <FIG>, a delay line <NUM> formed by an open-circuit microstrip line 123b includes a second main transmitting microstrip line 123a and an open-circuit microstrip line 123b, wherein one end of the open-circuit microstrip line 123b is connected to the second main transmitting microstrip line 123a, and the opposite end is an open-circuit end. In this embodiment, the second main transmitting microstrip line 123a and the short-circuit microstrip line 123b are preferably connected in a T-shape. Further, in order that one of signals satisfies the phase distribution as shown in <FIG>, the length of the open-circuit microstrip line 123b is one-half of the wavelength of the signal input to the feeding network.

The present invention can also effectively reduce the size of the feeding network by using a delay line <NUM> formed by a short- circuit microstrip line 122b or an open-circuit microstrip line 123b.

Compared with the prior art, the feeding network of the present invention adjusts the phase difference between signals input to the <NUM>° electric bridge <NUM> by using the structures of the delay lines <NUM> shown in <FIG>, so that the phase difference between signals input to the <NUM>° electric bridge <NUM> can satisfy the linear relationship as shown in <FIG>, which ultimately causes the <NUM>° electric bridge <NUM> to output the signals with the required amplitude, so that the lobe width of the wideband antenna within <NUM> to <NUM> can be controlled at <NUM>° ± <NUM>°, which greatly improves the convergence of the lobe width, and effectively improves the coverage of the base station.

Further, in connection with <FIG> is a <NUM>° antenna pattern of a conventional feeding network, and <FIG> is a <NUM>° antenna pattern of the feeding network of the present invention. As can be seen from <FIG>, when the conventional feeding network is utilized, the -<NUM> dB lobe width and -<NUM> dB lobe width of wideband antenna at <NUM>, <NUM>, <NUM> and <NUM> GH are shown in the following table:.

It can be seen from the above table that there are significant differences in the lobe width of the antenna of the traditional feeding network in the four frequency points, wherein the difference between the maximum value and the minimum value of the -<NUM> dB lobe width is <NUM>°, the difference between the maximum value and the minimum value of the -<NUM> dB lobe width is <NUM>°, and the lobe width of the wideband antenna within <NUM> to <NUM> can be controlled at <NUM>° ± <NUM>°.

As can be seen from <FIG>, when the feeding network according to the present invention is utilized, the -<NUM> dB lobe width and -<NUM> dB lobe width of the wideband antenna at <NUM>, <NUM>, <NUM> and <NUM> GH are shown in the following table:.

As can be seen from the above table, there are slight differences in the lobe width of the antenna of the feeding network of the present invention in the four frequency points, wherein the difference between the maximum value and the minimum value of the -<NUM> dB lobe width is about <NUM>°, and the difference between the maximum value and the minimum value of the -<NUM> dB lobe width is about <NUM>°, and the lobe width of the wideband antenna within <NUM> to <NUM> can be controlled at <NUM>° ± <NUM>°. Compared to the traditional feeding network, the difference between the maximum value and the minimum value of the -<NUM> dB lobe width and the difference between the maximum value and the minimum value of the -<NUM> dB lobe width are about <NUM>°, which effectively improves the width convergence.

Claim 1:
A feeding network (<NUM>) for improving a convergence of a lobe width of a wideband antenna, wherein the feeding network (<NUM>) comprises a first power divider (<NUM>), a delay line (<NUM>), a <NUM>° electric bridge (<NUM>) and a second power divider (<NUM>),
wherein the first power divider (<NUM>) is configured to convert a signal input to the feeding network (<NUM>) into two signals, such that the phase of one of the two signals is bechanged by the delay line (<NUM>) and then input to the <NUM>° electric bridge (<NUM>), and such that the other of the two signals is input to the <NUM>° electric bridge (<NUM>) directly,
and wherein the <NUM>° electric bridge (<NUM>) is configured to convert the received two signals into two signals with same phase and different amplitudes, output one of them to a radiating unit (<NUM>, <NUM>) via the second power divider (<NUM>) and output the other signal to another radiating unit (<NUM>) directly,
wherein the delay line (<NUM>) includes:
a transmitting microstrip line body (121a) and a U-shaped portion (121b) formed by bending the transmitting microstrip line body (121a), wherein a distance of a bottom end of the transmitting microstrip line body (121a) from a bottom end of the U-shaped portion (121b) is greater than a wavelength of the signal input to the feeding network (<NUM>), or
a first main transmitting microstrip line (122a) and a short-circuit microstrip line (122b) connected in a T-shape, and a non-short-circuit end of the short-circuit microstrip line is connected to the first main transmitting microstrip line, and a short-circuit end of the short-circuit microstrip line (122b) is provided with grounding vias (122c), and wherein a length of the short-circuit microstrip line (122b) is one quarter of the wavelength of the signal input to the feeding network (<NUM>), or
a second main transmitting microstrip line (123a) and an open-circuit microstrip line (123b) connected in a T-shape, and wherein a non-open-circuit end of the open-circuit microstrip line (123b) is connected to the second main transmitting microstrip line (123a), and wherein a length of the open-circuit microstrip line (123b) is one-half of the wavelength of the signal input to the feeding network (<NUM>).