This application claims priority to Chinese Patent Application No. 201710111992.9, filed on Feb. 28, 2017, which is hereby incorporated by reference in its entirety.
This disclosure relates to the field of microstrip antenna technologies, and in particular, to an antenna and a communications device.
A microstrip antenna is an antenna fabricated on a printed circuit board by using a microstrip technology. A common microstrip antenna is formed by a thin dielectric substrate, for example, a polytetrafluorethylene fiberglass layer, with metal foil attached on one surface as a ground plane, and with a metal patch of a specific shape that is made by using a method such as photoetching on the other surface as an antenna.
This disclosure provides an antenna and a communications device, and a method of making an antenna.
According to a first aspect, an antenna is provided. The antenna may include: multiple feeders, a microstrip antenna array, and at least one energy attenuation circuit. The microstrip antenna array may include multiple array elements, where each of the multiple array elements is connected to a cable feeding port by using one of the multiple feeders; each of the at least one energy attenuation circuit may be located at a feeder and divides the feeder into two segments, where the feeder is one of the multiple feeders and is connected to an array element, and the array element is located at a periphery of the multiple array elements.
The antenna may also include a first end of the energy attenuation circuit that is connected to the cable feeding port by using one segment of the feeder, a second end of the energy attenuation circuit that is connected to the array element by using the other segment of the feeder, and a third end of the energy attenuation circuit that is grounded. The energy attenuation circuit may include a resistor, where the resistor is grounded, and the resistor is configured to consume a part of energy in the to-be attenuated feeder when the resistor is grounded.
According to a second aspect, a communications device is provided. The communications device may include an antenna, and a signal source; the signal source may be connected to a feeding port of the antenna; and the signal source is configured to use the antenna to send and receive a radio signal.
The antenna of the communications device may include: multiple feeders, a microstrip antenna array, and at least one energy attenuation circuit. The microstrip antenna array may include multiple array elements, where each of the multiple array elements is connected to a cable feeding port by using one of the multiple feeders; each of the at least one energy attenuation circuit may be located at a feeder and divides the feeder into two segments, where the feeder is one of the multiple feeders and is connected to an array element, and the array element is located at a periphery of the multiple array elements.
The antenna may also include a first end of the energy attenuation circuit that is connected to the cable feeding port by using one segment of the feeder, a second end of the energy attenuation circuit that is connected to the array element by using the other segment of the feeder, and a third end of the energy attenuation circuit that is grounded. The energy attenuation circuit may include a resistor, where the resistor is grounded, and the resistor is configured to consume a part of energy in the to-be attenuated feeder when the resistor is grounded.
According to a third aspect, a method of making an antenna is provided. The method may include forming a microstrip antenna array that may include multiple array elements, where each of the multiple array elements is connected to a cable feeding port by using one of multiple feeders; providing at least one energy attenuation circuit, where each of the at least one energy attenuation circuit is located at a feeder and divides the feeder into two segments, where the feeder is one of the multiple feeders and is connected to an array element, and the array element is located at a periphery of the multiple array elements; providing a first end of the energy attenuation circuit that is connected to the cable feeding port by using one segment of the feeder, providing a second end of the energy attenuation circuit that is connected to the array element by using the other segment of the feeder, and providing a third end of the energy attenuation circuit that is grounded; and providing a resistor that is comprised in the energy attenuation circuit, where the resistor is grounded, and consuming a part of energy in the feeder by the resistor when the resistor is grounded.
It is to be understood that both the forgoing general description and the following detailed description are exemplary and illustrative only, and are not restrictive of the present disclosure.
The drawings are incorporated in, and formed a part of, the specification to show examples in conformity with the disclosure, and are for the purpose of illustrating the principles of the disclosure along with the specification.
A microstrip array antenna is a two-dimensional array that includes multiple patch antennas.
The antenna array shown in
This uniform array antenna may implement balanced energy distribution between array elements, or may implement unbalanced energy distribution. When energy distribution between the array elements is balanced, wiring of feeders of this antenna is simple and clear. However, this antenna with balanced energy distribution has a low side lobe suppression (SLS) ratio, and is difficult to meet a design requirement.
An example of this disclosure provides an antenna. An energy attenuation circuit is added based on an original antenna, and the energy attenuation circuit is configured to attenuate energy of a peripheral array element of a microstrip antenna array, thereby increasing a side lobe suppression ratio of the antenna, and improving an effect of the antenna.
Referring to
The antenna provided in this example includes: multiple feeders 100, a microstrip antenna array, and at least one energy attenuation circuit 300. The microstrip antenna array includes multiple array elements 200, and each of the multiple array elements 200 is connected to a cable feeding port A by using one of the multiple feeders. The cable feeding port A is an interface connecting the antenna and a signal source. A radio signal sent by the signal source is transmitted to the antenna by using the interface, and a radio signal received by the antenna is transmitted to the signal source by using the interface. The microstrip antenna array is an array formed by the array elements 200, and the array elements 200 are patches in the antenna.
The microstrip antenna array in the antenna provided in this example of this disclosure may be N*1 or N*M, where both N and M are integers greater than or equal to 2, and N may be equal to M, or may not be equal to M.
In this example, the microstrip antenna array shown in
Each of the at least one energy attenuation circuit is located at a to-be-attenuated feeder and divides the to-be-attenuated feeder into two segments, the to-be-attenuated feeder is a feeder that is of the multiple feeders and that is connected to a to-be-attenuated array element, and the to-be-attenuated array element is an array element located at a periphery of the multiple array elements.
As shown in
The energy attenuation circuit 300 is inserted into an entrance feeder of the array element 200. An entrance feeder of an array element means that this feeder is connected only to the array element. That is, the entrance feeder is a branch feeder corresponding to the array element, and another array element does not share this branch feeder. If at least two to-be-attenuated array elements share one branch feeder, and array elements other than these array elements do not share the branch feeder, this branch feeder is an entrance feeder of these array elements. That is, the energy attenuation circuit in this example of this disclosure is inserted into an entrance feeder of an array element that requires energy attenuation. The energy attenuation circuit 300 is not connected to the entrance feeder in parallel. A feeder connected to the to-be-attenuated array element is cut off, and the energy attenuation circuit is inserted. The cut-off feeder includes two ends. A first end and a second end of the energy attenuation circuit are respectively connected to the two ends of the cut-off feeder, and a third end of the energy attenuation circuit is grounded.
The energy attenuation circuit 300 includes a resistor, the resistor is grounded, and the resistor is configured to consume a part of energy in the to-be attenuated feeder in a grounded manner.
When a current passes through the resistor, electrical energy can be converted into thermal energy, and the thermal energy can be consumed in the grounded manner, so that energy that enters the to-be-attenuated array element can be attenuated.
A specific location of an array element at a periphery of an array is not limited in this example. Schematically,
To enable a person skilled in the art to better understand technical solutions in this example of this disclosure, the following still uses the 4*4 array as an example for description with reference to
Distances between any two adjacent array elements in the microstrip patch array shown in
As shown in
To enable a person skilled in the art to better understand beneficial effects brought by the examples of this disclosure, the following first describes a non-uniform design manner of increasing a side lobe suppression ratio of a microstrip patch antenna. Referring to
Because energy of an array element is related to a resistance of a feeder corresponding to the array element, the energy distributed to the array element may be changed by changing a resistance of the feeder. In addition, the resistance is decided by a length and a thickness of the feeder. Therefore, to change the resistance of the feeder, a shape of the feeder needs to be changed, that is, the feeder needs to be redesigned. As shown in
However, a design of such unbalanced energy distribution in
The antenna provided in this example of this disclosure is an improvement made based on balanced energy distribution between array elements. An original feeder wiring design is reserved, and unbalanced energy distribution between the array elements is implemented by inserting an energy attenuation circuit, thereby increasing the side lobe suppression ratio.
As shown in
The antenna is an improvement made based on the balanced energy distribution between the array elements in the original antenna, and the energy attenuation circuit is inserted into the feeder connected to the array element located at a periphery of the antenna array. The energy attenuation circuit includes a resistor, one end of the energy attenuation circuit is grounded, and energy is consumed as heat in a grounded manner. Therefore, the original array elements with balanced energy distribution change to array elements with unbalanced energy distribution. In this way, the side lobe suppression ratio can be increased. The side lobe suppression ratio of the antenna can be increased by directly inserting the energy attenuation circuit based on the original antenna. In this way, new feeders do not need to be designed, thereby reducing design difficulty.
The antenna provided in this example of this disclosure is not limited to a specific antenna type, and may be a uniform array, or may be an equi-amplitude array. “Uniform array” and “balanced energy distribution between array elements” are different concepts, that is, array elements in a uniform array may have balanced energy distribution, or may have unbalanced energy distribution.
The following describes an insertion location of the energy attenuation circuit and an implementation in detail with reference to the accompanying drawings.
The multiple array elements are arranged into an N*1 array, peripheral array elements of the multiple array elements are two array elements located at ends of the N*1 array, and each of the two array elements corresponds to one of the at least one energy attenuation circuit, where N is an integer greater than or equal to 3. The following uses a 4*1 array as an example for description. Referring to
That is, energy attenuation circuits are inserted into feeders connected to two array elements at ends, and energy on the feeders is attenuated, so as to attenuate energy that enters the array elements at the two ends.
The multiple array elements are arranged into an N*M array, peripheral array elements of the multiple array elements are four array elements located at corners of the N*M array, and each of the four array elements corresponds to one of the at least one energy attenuation circuit, where both N and M are integers greater than or equal to 2, and N may be equal to M, or may not be equal to M. For an N*N array, refer to the schematic diagram shown in
When N is not equal to M, for example, when N=4, and M=6, there is a corresponding 4*6 array.
A function of the energy attenuation circuit is merely energy attenuation, and it needs to be ensured that neither signal reflection nor a standing wave exists in the antenna when the energy attenuation circuit is inserted. Therefore, both an input equivalent impedance and an output equivalent impedance of the energy attenuation circuit are required to be equal to a characteristic impedance of the to-be-attenuated feeder.
To ensure that an impedance of an entrance feeder of an array element after insertion of the energy attenuation circuit remains the same as that of the entrance feeder of the array element before the insertion of the energy attenuation circuit, the energy attenuation circuit needs to be a symmetric resistive attenuator, that is, a resistance of an input end of the attenuator is equal to a resistance of an output end of the attenuator. In addition, to prevent signal reflection and a standing wave, both an input equivalent impedance and an output equivalent impedance of the attenuator are equal to the characteristic impedance of the to-be-attenuated feeder.
The symmetric resistive attenuator provided in this example of this disclosure may be any one of the following:
a T-type resistive attenuator, a π-type resistive attenuator, or a bridged T-type resistive attenuator.
When the antenna includes multiple symmetric resistive attenuators, the symmetric resistive attenuators may be same resistive attenuators, or may be different resistive attenuators. For example, a T-type resistive attenuator may be used in one attenuator, and a π-type resistive attenuator may be used in another attenuator. A specific type of a resistive attenuator used in an antenna is not specifically limited in this example of this disclosure.
The following separately describes these symmetric resistive attenuators with reference to the accompanying drawings.
Referring to
The T-type resistive attenuator includes: a first resistor R1, a second resistor R2, and a third resistor R3.
A first end of the first resistor R1 is a first end of the energy attenuation circuit, a second end of the first resistor R1 is connected to a first end of the second resistor R2, a second end of the second resistor R2 is a second end of the energy attenuation circuit, a first end of the third resistor R3 is connected to the second end of the first resistor R1, and a second end of the third resistor R3 is a third end of the energy attenuation circuit.
Resistances of the first resistor R1, the second resistor R2, and the third resistor R3 are respectively:
where R1 is a resistance of the first resistor, R2 is a resistance of the second resistor, R3 is a resistance of the third resistor, A is an energy attenuation coefficient, and R is a characteristic impedance of the to-be-attenuated feeder. A is a ratio of attenuated energy to original energy. For example, if the original energy is 2, and the attenuated energy is 1, A=½. If the original energy is 3, and the attenuated energy is 2, A=⅔.
To ensure that a characteristic impedance of the original antenna remains unchanged after the insertion of the energy attenuation circuit, both the input equivalent impedance and the output equivalent impedance of the energy attenuation circuit can only be designed to be equal to the characteristic impedance. That is, as shown in
Referring to
The π-type resistive attenuator includes a fourth resistor R4, a fifth resistor R5, and a sixth resistor R6.
A first end of the fourth resistor R4 is a first end of the energy attenuation circuit, a second end of the fourth resistor R4 is a second end of the energy attenuation circuit, a first end of the fifth resistor R5 is connected to the first end of the fourth resistor R4, a second end of the fifth resistor R5 is connected to a third end of the energy attenuation circuit, a first end of the sixth resistor R6 is connected to the second end of the energy attenuation circuit, and a second end of the sixth resistor R6 is the third end of the energy attenuation circuit.
Resistances of the fourth resistor R4, the fifth resistor R5, and the sixth resistor R6 are respectively:
where R4 is a resistance of the fourth resistor, R5 is a resistance of the fifth resistor, R6 is a resistance of the sixth resistor, A is an energy attenuation coefficient, and R is a characteristic impedance.
Referring to
The bridged T-type resistive attenuator includes a seventh resistor, an eighth resistor, a ninth resistor, and a tenth resistor.
A first end of the seventh resistor is a first end of the energy attenuation circuit, a second end of the seventh resistor is connected to a first end of the eighth resistor, a second end of the eighth resistor is a second end of the energy attenuation circuit, two ends of the ninth resistor are respectively connected to the first end and the second end of the energy attenuation circuit, a first end of the tenth resistor is connected to the first end of the seventh resistor, and a second end of the tenth resistor is a third end of the energy attenuation circuit; and
where R7 is a resistance of the seventh resistor, R8 is a resistance of the eighth resistor, R9 is a resistance of the ninth resistor, R10 is a resistance of the tenth resistor, A is an energy attenuation coefficient, and R is a characteristic impedance.
Calculation principles for the resistors in the π-type resistive attenuator and the bridged T-type resistive attenuator are similar to those for the T-type resistive attenuator. Details are not described herein again.
Based on the antenna provided in the foregoing examples, an example of this disclosure further provides a communications device. The following gives a detailed description according to the accompanying drawings.
Referring to
The communications device provided in this example includes an antenna 1201 described in the foregoing examples, and
further includes a signal source 1202.
The signal source 1202 is connected to a cable feeding port of the antenna 1201.
The signal source 1202 may generate a radio signal, the signal source 1202 transmits a radio signal by using the antenna 1201, and the signal source 1202 may also receive a radio signal received by the antenna 1201. The signal source 1202 is connected to the antenna 1201 by using the cable feeding port, and radio signal transmission is implemented by using the cable feeding port.
The signal source 1202 is configured to send and receive the radio signal by using the antenna 1201.
For example, the signal source 1202 may be a transmitter.
Because the antenna is simple in design, and has a relatively high side lobe suppression ratio, the communications device using the antenna can keep good signal communication quality.
This disclosure provides an antenna and a communications device, so as to increase a side lobe suppression ratio of the antenna.
According to a first aspect, an antenna is provided, including: multiple feeders, a microstrip antenna array, and at least one energy attenuation circuit; the microstrip antenna array includes multiple array elements, where each of the multiple array elements is connected to a cable feeding port by using one of the multiple feeders; each of the at least one energy attenuation circuit is located at a to-be-attenuated feeder and divides the to-be-attenuated feeder into two segments, where the to-be-attenuated feeder is a feeder that is of the multiple feeders and that is connected to a to-be-attenuated array element, and the to-be-attenuated array element is an array element located at a periphery of the multiple array elements; a first end of the energy attenuation circuit is connected to the cable feeding port by using one segment of the to-be-attenuated feeder, a second end of the energy attenuation circuit is connected to the to-be-attenuated array element by using the other segment of the to-be-attenuated feeder, and a third end of the energy attenuation circuit is grounded; and the energy attenuation circuit includes a resistor, where the resistor is grounded, and the resistor is configured to consume a part of energy in the to-be attenuated feeder in a grounded manner.
Because the energy attenuation circuit consumes the energy in the grounded manner, energy transmitted to the array element located at a periphery of the antenna array is reduced, thereby implementing unbalanced energy distribution and increasing a side lobe suppression ratio.
Optionally, both an input equivalent impedance and an output equivalent impedance of the energy attenuation circuit are equal to a characteristic impedance of the to-be-attenuated feeder, so that the inserted energy attenuation circuit does not cause a standing wave.
In a first possible implementation of the first aspect, the multiple array elements are arranged into an N*1 array, peripheral array elements of the multiple array elements are two array elements located at ends of the N*1 array, and each of the two array elements corresponds to one of the at least one energy attenuation circuit, where N is an integer greater than or equal to 3.
With reference to any one of the first aspect or the foregoing possible implementation, in a second possible implementation, the multiple array elements are arranged into an N*M array, peripheral array elements of the multiple array elements are four array elements located at corners of the N*M array, and each of the four array elements corresponds to one of the at least one energy attenuation circuit, where
both N and M are integers greater than or equal to 2, and at least one of N or M is greater than or equal to 3.
With reference to any one of the first aspect or the foregoing possible implementations, in a third possible implementation, each of the at least one energy attenuation circuit is a symmetric resistive attenuator.
With reference to any one of the first aspect or the foregoing possible implementations, in a fourth possible implementation, the symmetric resistive attenuator is any one of the following:
a T-type resistive attenuator, a π-type resistive attenuator, or a bridged T-type resistive attenuator.
With reference to any one of the first aspect or the foregoing possible implementations, in a fifth possible implementation, the T-type resistive attenuator includes: a first resistor, a second resistor, and a third resistor, where
a first end of the first resistor is a first end of the energy attenuation circuit, a second end of the first resistor is connected to a first end of the second resistor, a second end of the second resistor is a second end of the energy attenuation circuit, a first end of the third resistor is connected to the second end of the first resistor, and a second end of the third resistor is a third end of the energy attenuation circuit; and
resistances of the first resistor, the second resistor, and the third resistor are respectively:
where R1 is the resistance of the first resistor, R2 is the resistance of the second resistor, R3 is the resistance of the third resistor, A is an energy attenuation coefficient, and R is a characteristic impedance of the to-be-attenuated feeder.
With reference to any one of the first aspect or the foregoing possible implementations, in a sixth possible implementation, the π-type resistive attenuator includes a fourth resistor, a fifth resistor, and a sixth resistor, where
a first end of the fourth resistor is a first end of the energy attenuation circuit, a second end of the fourth resistor is a second end of the energy attenuation circuit, a first end of the fifth resistor is connected to the first end of the fourth resistor, a second end of the fifth resistor is connected to a third end of the energy attenuation circuit, a first end of the sixth resistor is connected to the second end of the energy attenuation circuit, and a second end of the sixth resistor is the third end of the energy attenuation circuit; and
resistances of the fourth resistor, the fifth resistor, and the sixth resistor are respectively:
where R4 is the resistance of the fourth resistor, R5 is the resistance of the fifth resistor, R6 is the resistance of the sixth resistor, A is the energy attenuation coefficient, and R is the characteristic impedance.
With reference to any one of the first aspect or the foregoing possible implementations, in a seventh possible implementation, the bridged T-type resistive attenuator includes a seventh resistor, an eighth resistor, a ninth resistor, and a tenth resistor, where
a first end of the seventh resistor is a first end of the energy attenuation circuit, a second end of the seventh resistor is connected to a first end of the eighth resistor, a second end of the eighth resistor is a second end of the energy attenuation circuit, two ends of the ninth resistor are respectively connected to the first end and the second end of the energy attenuation circuit, a first end of the tenth resistor is connected to the first end of the seventh resistor, and a second end of the tenth resistor is a third end of the energy attenuation circuit; and
where R7 is a resistance of the seventh resistor, R8 is a resistance of the eighth resistor, R9 is a resistance of the ninth resistor, R10 is a resistance of the tenth resistor, A is the energy attenuation coefficient, and R is the characteristic impedance.
In the fifth to the seventh possible implementations of the first aspect, the resistances of the resistors calculated according to the formulas make both the input equivalent impedance and the output equivalent impedance of the energy attenuation circuit equal to the characteristic impedance of the to-be-attenuated feeder. Therefore, the inserted energy attenuation circuit does not cause a standing wave.
With reference to any one of the first aspect or the foregoing possible implementations, in an eighth possible implementation, the feeders in the antenna are feeders corresponding to balanced energy distribution between the array elements.
The antenna is an improvement made based on the balanced energy distribution between the array elements in the original antenna, and the energy attenuation circuit is inserted into the feeder connected to the array element located at a periphery of the antenna array. The side lobe suppression ratio of the antenna can be increased by directly inserting the energy attenuation circuit based on the original antenna. In this way, new feeders do not need to be designed, thereby reducing design difficulty.
According to a second aspect, a communications device is provided, including the antenna, and further including a signal source; the signal source is connected to a feeding port of the antenna; and the signal source is configured to use the antenna to send and receive a radio signal.
In conclusion, the foregoing examples are merely intended for describing the technical solutions of this disclosure, rather than limiting this disclosure. Although this disclosure is described in detail with reference to the foregoing examples, a person of ordinary skill in the art should understand that modifications may still be made to the technical solutions described in the foregoing examples without departing from the scope of the technical solutions of the examples of this disclosure.
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