Method for recovering phase in antenna measurement system through amplitude of lens defocusing plane
1. A method for recovering phase in an antenna measurement system by amplitude of a defocus plane of a lens, wherein a dielectric lens is disposed in a quiet zone plane of the antenna measurement system, the method comprising:
the computer obtains actual amplitude values in at least two preset defocusing planes of the medium lens, which are acquired by the probe;
generating an initial phase and an initial amplitude, and taking the initial amplitude and the initial phase as the field intensity of an initial field in a target region in the quiet zone plane;
calculating the frequency domain phases of the initial field transmitted to the at least two preset defocusing planes through an angular spectrum after passing through the medium lens;
the computer calculates the frequency domain amplitude values of the initial field transmitted to the at least two preset defocusing planes through the angular spectrum after the initial field passes through the medium lens; respectively taking the frequency domain amplitude and the frequency domain phase of the at least two preset defocusing planes as the field intensity of the frequency domain field of the defocusing plane;
acquiring field intensity corresponding to the spatial field based on the field intensity of the frequency domain field, wherein the field intensity of the spatial field comprises a spatial amplitude and a spatial phase; taking the actual amplitude and the spatial phase in the at least two preset defocusing planes as the field intensity of the actual field in the defocusing plane;
calculating the field intensity of the initial field based on the field intensity of the actual field and the field intensity of the airspace field, and taking the solved field intensity of the initial field as the field intensity of the heterogeneous input field; the field intensity of the heterogeneous input field comprises a heterogeneous input phase and a heterogeneous input amplitude;
performing iterative computation on the field intensity of the heterogeneous input field for preset times by adopting a GS-HIO algorithm to obtain a target recovery phase;
judging whether the GS-HIO algorithm is converged, and if so, taking a target recovery phase obtained in the convergence as a phase recovery result; and if not, returning to the step of generating the initial phase and the initial amplitude, and taking the initial amplitude and the initial phase as the field intensity of the initial field in the target area in the quiet zone plane.
2. The method of claim 1, wherein prior to the step of calculating the field strength of the initial field based on the field strength of the actual field and the field strength of the spatial field, the method further comprises:
calculating an amplitude error between the actual amplitude and the spatial amplitude based on the actual amplitude and the spatial amplitude;
judging whether the amplitude error is larger than a preset threshold value or not;
if the amplitude error is not larger than a preset threshold value, taking the initial phase as a phase recovery result;
and if the amplitude error is larger than a preset threshold value, executing the step of calculating the field intensity of the initial field based on the field intensity of the actual field and the field intensity of the airspace field.
3. The method of claim 2, wherein the step of calculating a magnitude error between the actual magnitude and the spatial magnitude based on the actual magnitude and the spatial magnitude comprises:
the amplitude error is calculated according to the following equation:
wherein i is the number of the preset defocusing plane, n is the number of the preset defocusing plane, | Aix | represents the spatial amplitude of the spatial field of the preset defocusing plane, | biAnd | represents the actual amplitude of the actual field of the preset defocusing plane.
4. The method of claim 1, wherein the step of calculating the field strength of the initial field based on the field strength of the actual field and the field strength of the spatial field comprises:
and calculating the field intensity of the initial field by adopting a least square method based on the field intensity of the actual field and the field intensity of the airspace field.
5. The method of claim 1,
the step of performing iterative computation of preset times on the field intensity of the heterogeneous input field by adopting a GS-HIO algorithm to obtain a target recovery phase comprises the following steps:
judging whether the number of times of executing the GS algorithm reaches a second preset number of times;
if the number of times of executing the GS algorithm does not reach a second preset number of times, performing iterative calculation on the field intensity of the heterogeneous input field by adopting the GS algorithm;
if the number of times of executing the GS algorithm reaches a second preset number of times, carrying out iterative computation on the field intensity of the heterogeneous input field for a third preset number of times by adopting an HIO algorithm to obtain a recovery phase;
judging whether the sum of the times of executing the GS algorithm and the HIO algorithm reaches the preset times or not;
if the sum of the times of executing the GS algorithm and the HIO algorithm reaches the preset times, taking the recovery phase as a target recovery phase;
and if the sum of the times of executing the GS algorithm and the HIO algorithm does not reach the preset times, returning to the step of judging whether the times of executing the GS algorithm reaches a second preset time.
6. The method of claim 5, wherein the step of iteratively calculating the field strength of the heterogeneous input field using the GS algorithm comprises:
taking the field intensity of the heterogeneous input field as the field intensity of a new initial field; returning to the step of calculating the frequency domain phases of the initial field passing through the medium lens and transmitting the angular spectrum to the at least two preset defocusing planes;
the step of performing iterative computation on the field intensity of the heterogeneous input field for a third preset number of times by adopting an HIO algorithm to obtain a recovery phase comprises the following steps:
taking the field intensity of the heterogeneous input field in the target area as the field intensity in the target area of the new initial field; subtracting the field intensity of the heterogeneous input field of the current time from the field intensity of the heterogeneous input field obtained last time outside the target area to obtain a field intensity difference, and taking the field intensity difference as the field intensity outside the target area of the new initial field;
and returning to the step of calculating the frequency domain phase of the initial field passing through the medium lens, and transmitting the angular spectrum to the at least two preset defocusing planes.
7. The method according to any one of claims 1 to 6,
the dielectric lens is formed by splicing a plurality of lens unit modules capable of generating preset phase shift;
each lens unit module is a cuboid metamaterial dielectric block; or the like, or, alternatively,
each lens unit module is a cuboid metamaterial medium block with a cylindrical air cavity with a preset size on the top surface.
8. An apparatus for recovering phase in an antenna measurement system by amplitude of a defocus plane of a lens, wherein a dielectric lens is disposed in a quiet zone plane of the antenna measurement system, the apparatus comprising:
the actual amplitude acquisition module is used for acquiring actual amplitudes in at least two preset defocusing planes of the medium lens acquired by the probe through a computer;
the initial amplitude-phase generation module is used for generating an initial phase and an initial amplitude, and the initial amplitude and the initial phase are used as the field intensity of an initial field in a target area in the quiet zone plane;
the frequency domain phase calculation module is used for calculating the frequency domain phases of the initial field transmitted to the at least two preset defocusing planes through the angular spectrum after passing through the medium lens;
the frequency domain amplitude calculation module is used for calculating frequency domain amplitudes of the initial field transmitted to the at least two preset defocusing planes through angular spectrum transmission after the initial field passes through the medium lens by a computer; respectively taking the frequency domain amplitude and the frequency domain phase of the at least two preset defocusing planes as the field intensity of the frequency domain field of the defocusing plane;
the spatial domain field intensity acquisition module is used for acquiring the field intensity of a corresponding spatial domain field based on the field intensity of the frequency domain field, and the field intensity of the spatial domain field comprises a spatial domain amplitude and a spatial domain phase; taking the actual amplitude and the spatial phase in the at least two preset defocusing planes as the field intensity of the actual field in the defocusing plane;
the heterogeneous input field intensity calculation module is used for calculating the field intensity of the initial field based on the field intensity of the actual field and the field intensity of the airspace field, and taking the solved field intensity of the initial field as the field intensity of the heterogeneous input field; the field intensity of the heterogeneous input field comprises a heterogeneous input phase and a heterogeneous input amplitude;
the iterative computation module is used for carrying out iterative computation on the field intensity of the heterogeneous input field for preset times by adopting a GS-HIO algorithm to obtain a target recovery phase;
the judging module is used for judging whether the GS-HIO algorithm is converged, and if so, the target recovery phase obtained in the convergence process is used as a phase recovery result; and if not, returning to the step of generating the initial phase and the initial amplitude, and taking the initial amplitude and the initial phase as the field intensity of the initial field in the target area in the quiet zone plane.
9. An electronic device is characterized by comprising a processor, a communication interface, a memory and a communication bus, wherein the processor and the communication interface are used for realizing mutual communication by the memory through the communication bus;
a memory for storing a computer program;
a processor for implementing the method steps of any of claims 1-6 when executing a program stored in the memory.
10. A computer-readable storage medium, characterized in that a computer program is stored in the computer-readable storage medium, which computer program, when being executed by a processor, carries out the method steps of any one of claims 1 to 6.
Background
Currently, antenna measurements are typically achieved by compact field systems. The compact range antenna measuring system is a testing system which converts spherical waves emitted by a feed source into approximate plane waves finally through the focusing and conversion of a reflector. The method applies a near-field focusing principle to generate a quasi-plane wave area in the near area of a measuring antenna, wherein the quasi-plane wave area is a quiet area, and the amplitude and phase conditions of plane waves in the quiet area range meet the basic requirements of antenna measurement on the plane wave irradiation environment. The compact range antenna measurement system can meet the requirements of radiation characteristic tests of antennas of various wave bands on three aspects of measurement distance, electromagnetic environment and measurement equipment.
Before measurement is performed using a compact range antenna measurement system, it is necessary to evaluate how similar a quasi-plane wave in its quiet zone is to an ideal plane wave, that is, it is necessary to measure amplitude-phase data of the quasi-plane wave in the quiet zone and evaluate the quality of the quiet zone based on the amplitude-phase data.
However, in actual operation, due to the existence of many influencing factors, such as disturbance of a cable, temperature change, probe position error and the like, amplitude distortion is not serious, but phase distortion is serious, and the measurement requirement cannot be met. Therefore, a phase-free measurement method that recovers phase by amplitude is an important application in compact range antenna measurement systems.
The method for recovering the phase through the amplitude in the existing compact range antenna measurement system is mostly suitable for a lower frequency band, and when the method is used for a higher frequency band, a large amount of unknown information can appear after a formula is unfolded, a larger phase recovery error can appear, and the accuracy of recovering the phase through the amplitude is lower.
Disclosure of Invention
An object of the embodiments of the present invention is to provide a method, an apparatus, an electronic device, and a storage medium for recovering a phase in an antenna measurement system through an amplitude of a defocus plane of a lens, so as to improve accuracy of recovering a phase through the amplitude. The specific technical scheme is as follows:
in an aspect of the embodiments of the present invention, there is provided a method for recovering a phase in an antenna measurement system through an amplitude of a defocus plane of a lens, where a dielectric lens is disposed in a quiet zone plane of the antenna measurement system, the method may include:
the computer obtains actual amplitude values in at least two preset defocusing planes of the medium lens, which are acquired by the probe;
generating an initial phase and an initial amplitude, and taking the initial amplitude and the initial phase as the field intensity of an initial field in a target region in the quiet zone plane;
calculating the frequency domain phases of the initial field transmitted to the at least two preset defocusing planes through an angular spectrum after passing through the medium lens;
the computer calculates the frequency domain amplitude values of the initial field transmitted to the at least two preset defocusing planes through the angular spectrum after the initial field passes through the medium lens; respectively taking the frequency domain amplitude and the frequency domain phase of the at least two preset defocusing planes as the field intensity of the frequency domain field of the defocusing plane;
acquiring field intensity corresponding to the spatial field based on the field intensity of the frequency domain field, wherein the field intensity of the spatial field comprises a spatial amplitude and a spatial phase; taking the actual amplitude and the spatial phase in the at least two preset defocusing planes as the field intensity of the actual field in the defocusing plane;
calculating the field intensity of the initial field based on the field intensity of the actual field and the field intensity of the airspace field, and taking the solved field intensity of the initial field as the field intensity of the heterogeneous input field; the field intensity of the heterogeneous input field comprises a heterogeneous input phase and a heterogeneous input amplitude;
performing iterative computation on the field intensity of the heterogeneous input field for preset times by adopting a GS-HIO algorithm to obtain a target recovery phase;
judging whether the GS-HIO algorithm is converged, and if so, taking a target recovery phase obtained in the convergence as a phase recovery result; and if not, returning to the step of generating the initial phase and the initial amplitude, and taking the initial amplitude and the initial phase as the field intensity of the initial field in the target area in the quiet zone plane.
In another aspect of the present invention, there is also provided an apparatus for recovering a phase in an antenna measurement system by using an amplitude of a defocus plane of a lens, where a dielectric lens is disposed in a quiet zone plane of the antenna measurement system, the apparatus including:
the actual amplitude acquisition module is used for acquiring actual amplitudes in at least two preset defocusing planes of the medium lens acquired by the probe through a computer;
the initial amplitude-phase generation module is used for generating an initial phase and an initial amplitude, and the initial amplitude and the initial phase are used as the field intensity of an initial field in a target area in the quiet zone plane;
the frequency domain phase calculation module is used for calculating the frequency domain phases of the initial field transmitted to the at least two preset defocusing planes through the angular spectrum after passing through the medium lens;
the frequency domain amplitude calculation module is used for calculating frequency domain amplitudes of the initial field transmitted to the at least two preset defocusing planes through angular spectrum transmission after the initial field passes through the medium lens by a computer; respectively taking the frequency domain amplitude and the frequency domain phase of the at least two preset defocusing planes as the field intensity of the frequency domain field of the defocusing plane;
the spatial domain field intensity acquisition module is used for acquiring the field intensity of a corresponding spatial domain field based on the field intensity of the frequency domain field, and the field intensity of the spatial domain field comprises a spatial domain amplitude and a spatial domain phase; taking the actual amplitude and the spatial phase in the at least two preset defocusing planes as the field intensity of the actual field in the defocusing plane;
the heterogeneous input field intensity calculation module is used for calculating the field intensity of the initial field based on the field intensity of the actual field and the field intensity of the airspace field, and taking the solved field intensity of the initial field as the field intensity of the heterogeneous input field; the field intensity of the heterogeneous input field comprises a heterogeneous input phase and a heterogeneous input amplitude;
the iterative computation module is used for carrying out iterative computation on the field intensity of the heterogeneous input field for preset times by adopting a GS-HIO algorithm to obtain a target recovery phase;
the judging module is used for judging whether the GS-HIO algorithm is converged, and if so, the target recovery phase obtained in the convergence process is used as a phase recovery result; and if not, returning to the step of generating the initial phase and the initial amplitude, and taking the initial amplitude and the initial phase as the field intensity of the initial field in the target area in the quiet zone plane.
In another aspect of the embodiments of the present invention, an electronic device is further provided, which includes a processor, a communication interface, a memory, and a communication bus, where the processor, the communication interface, and the memory complete communication with each other through the communication bus;
a memory for storing a computer program;
and the processor is used for realizing any one of the steps of the method for recovering the phase in the antenna measurement system through the amplitude of the defocused plane of the lens when executing the program stored in the memory.
In yet another aspect of the embodiments of the present invention, there is further provided a computer readable storage medium having stored therein a computer program, which when executed by a processor, implements any of the above-mentioned method steps for recovering phase in an antenna measurement system through magnitude of a lens defocus plane.
Embodiments of the present invention also provide a computer program product containing instructions which, when run on a computer, cause the computer to perform any of the above-described methods for recovering phase in an antenna measurement system by amplitude at a plane through which a lens is out of focus.
The embodiment of the invention has the following beneficial effects:
according to the method for recovering the phase in the antenna measurement system through the amplitude of the defocusing plane of the lens, provided by the embodiment of the invention, the dielectric lens is arranged in the quiet zone plane of the antenna measurement system; the method comprises the steps of firstly collecting actual amplitude values in at least two preset defocusing planes of a medium lens through a probe, then generating an initial amplitude value and an initial phase value as field intensity of an initial field, calculating the frequency domain phase value of the initial field transmitted to the preset defocusing planes through an angle spectrum after the initial field passes through the medium lens and a corresponding frequency domain amplitude value, taking the frequency domain amplitude value and the frequency domain phase value as the field intensity of a frequency domain field, then obtaining the field intensity of a space domain field corresponding to the frequency domain field, taking the space domain phase value and the actual amplitude value as the field intensity of the actual field, solving the field intensity of the initial field based on the field intensity of the actual field and the field intensity of the space domain field, taking the field intensity of the initial field as the field intensity of a heterogeneous input field, and then carrying out preset times of iterative calculation on the field intensity of the heterogeneous input field by adopting a GS-HIO algorithm to obtain a phase recovery result. In the embodiment of the invention, the GS-HIO algorithm is adopted to recover the phase through the amplitude, so that the convergence speed of the algorithm is accelerated, and the accuracy of phase recovery through the amplitude is improved through repeated iterative calculation.
Of course, not all of the advantages described above need to be achieved at the same time in the practice of any one product or method of the invention.
Drawings
In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, and it is obvious that the drawings in the following description are only some embodiments of the present invention, and it is obvious for those skilled in the art that other embodiments can be obtained by using the drawings without creative efforts.
Fig. 1a is a schematic structural diagram of a unit module constituting a dielectric lens in an antenna measurement system according to an embodiment of the present invention;
fig. 1b is a schematic structural view of a dielectric lens formed of 3 × 3 unit modules of fig. 1 a;
fig. 1c is a plan view of the dielectric lens formed of 3 × 3 unit modules in fig. 1 b;
FIG. 1d is a schematic structural diagram of another dielectric lens provided in an embodiment of the present invention;
FIG. 2a is a flow chart of a method for recovering phase in an antenna measurement system through the amplitude of the defocus plane of the lens according to an embodiment of the present invention;
FIG. 2b is a graph showing the convergence error variation of the GS-HIO algorithm with the number of iterations in the embodiment of the present invention;
FIG. 3 is a second flowchart of a method for recovering phase in an antenna measurement system by the amplitude of the defocus plane of the lens according to an embodiment of the present invention;
FIG. 4 is a third flowchart of a method for recovering phase in an antenna measurement system by the amplitude of the defocus plane of the lens according to an embodiment of the present invention;
FIG. 5a is a graph comparing the recovered phase on the x-axis with the original phase obtained using the method in an embodiment of the present invention;
FIG. 5b is a graph comparing the recovered phase on the y-axis with the original phase obtained using the method in an embodiment of the present invention;
FIG. 6 is a schematic diagram of an apparatus for recovering phase in an antenna measurement system through the amplitude of the defocused plane of a lens according to an embodiment of the present invention;
fig. 7 is a schematic structural diagram of an electronic device according to an embodiment of the present invention.
Detailed Description
The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.
The embodiment of the invention provides a method and a device for recovering a phase in an antenna measurement system through an amplitude value of a defocused plane of a lens, electronic equipment and a storage medium.
The following first describes a method for recovering the phase in the antenna measurement system through the amplitude of the defocused plane of the lens according to the embodiment of the present invention. The method provided by the present invention can be implemented by a program installed in a computer.
In the embodiment of the invention, the dielectric lens is arranged in the quiet zone plane of the antenna measuring system.
The dielectric lens is composed of a plurality of unit modules capable of generating a predetermined phase shift. Each unit module can be a rectangular-parallelepiped metamaterial dielectric block, which refers to a kind of artificial materials having special properties, which are not available in the natural world, such as: the metamaterial medium can change common properties of light, electromagnetic waves and the like, the initial research on the metamaterial medium is a negative-refractive-index metamaterial, in the embodiment of the invention, the medium of the dielectric lens is ideal without insertion loss and reflection, and the dielectric constant is 2.66. The upper surface and the lower surface of the cuboid unit module forming the dielectric lens can be both square, and the side length of the square is consistent with the half wavelength corresponding to the frequency of the measured signal.
For example, if the frequency of the signal to be measured is 220GHz, the side length of the upper and lower squares of each unit module constituting the dielectric lens may be a half wavelength of 0.68mm corresponding to 220 GHz.
As a specific implementation manner, as shown in fig. 1a, fig. 1a is a schematic diagram of a unit module constituting a dielectric lens in an embodiment of the present invention. A cylindrical dielectric block can be dug on the top surface of the unit module of the metamaterial dielectric, so that a cylindrical air cavity is formed on the top surface of the unit module of the dielectric lens, and the air cavity can reduce the reflection of waves on the surface of the dielectric lens, thereby achieving better experimental effect. The thickness of the air cavity of the unit module can be determined according to the phase shift required to be generated by the corresponding unit module; as another specific embodiment, the thickness of the air cavity may be fixed, and the height of the unit module may be determined based on the phase shift required to be generated by each unit module.
For example, in the implementation of the present invention, the diameter of the air cavity in the unit module may be 0.48mm, and the height of the air cavity may be 0.306 mm.
Based on the above example, as shown in fig. 1b, fig. 1b is a schematic structural diagram of a dielectric lens constructed by using 3 × 3 unit modules.
The phase shift generated by each unit module is calculated before the experiment, and specifically, the phase shift required to be generated by different unit modules can be calculated by adopting the following formula:
in formula I, m and n are corresponding labels of unit modules, phimnThat is, the phase shift required to be generated by the corresponding module, F is the distance from the preset focus to the center of the lens, F is the frequency of the electromagnetic wave measured by using the dielectric lens, λ is the wavelength of the corresponding electromagnetic wave, c is the speed of light, and Φ 00 is the phase shift of the unit module at the center of the dielectric lens.
For example, as shown in fig. 1c, fig. 1c is a schematic top view of a dielectric lens composed of 3 × 3 unit modules based on the above-mentioned example of the dielectric lens composed of 3 × 3 unit modules. The center of the lens is placed at the coordinate center of the plane coordinate, the most central module is marked as m-0, n-0, that is, the coordinate of the most central module is (0,0), because the lens is symmetrical, only the modules marked as (0,0), (0,1), (1,0), (1,1) need to be designed, and each module corresponds to the coordinate of (λ/2 × m, λ/2 × n). For example, for an electromagnetic wave of 220GHz, the coordinates corresponding to each unit module are (0.00068 × m, 0.00068 × n), and the unit is meter. φ 00 can be the phase shift, typically a negative number, that needs to be produced by the center module, determined according to actual requirements. The phase shifts φ mn of the other modules are determined based on the above equation.
As a specific implementation manner, as shown in fig. 1d, fig. 1d is a schematic diagram of a side surface of a dielectric lens composed of 59 × 59 unit modules, where 101 is a focal plane of the dielectric lens, a frequency of an incident signal of the dielectric lens is 220GHz, and a corresponding half wavelength is 0.68 mm; the distance from the focal plane to the media lens can be set to 30mm, i.e. the focal length of the media lens is 30mm, and accordingly 102 is a defocusing plane of the media lens. Putting the coordinate center to the center module of the dielectric lens, for the dielectric lens along the y direction, the distance from the center module 103 to the focal point is 30mm, the number of the center module in the y direction is 0, the distance from the module 104 with the number of 2 to the focal point is 30.031mm, and the distance from the unit module 105 with the number of 29 to the focal point is 35.901 mm. Accordingly, the phase shift required to be generated by the central module 103 is set to-200 °, and based on the above formula, the phase shift required to be generated by the unit module 104 is-191.87 °, and the phase shift required to be generated by the unit module 105 is-82.136 °. The dielectric lens formed by the 59 × 59 unit modules can generate one-to-one corresponding phase shift for the corresponding 59 × 59 electromagnetic wave signals.
The top surface of the dielectric lens receiving the signal is a working surface of the dielectric lens, and for convenience of calculating the phase shift generated by each unit module, the working surface of the dielectric lens may be a horizontal surface, and of course, the dielectric lens may also be an inclined surface, which is not limited herein.
In the embodiment of the invention, the dielectric lens can convert the field intensity value of the electromagnetic field in the airspace into the field intensity value of the electromagnetic field in the corresponding frequency domain, namely, the Fourier transform can be realized on the electromagnetic field.
As shown in fig. 2a, fig. 2a is a flowchart of a phase recovery method in an antenna measurement system according to an embodiment of the present invention, and the specific steps of the phase recovery method include:
step 201, a computer obtains actual amplitude values in at least two preset defocusing planes of the medium lens collected by a probe;
step 202, generating an initial phase and an initial amplitude, and taking the initial amplitude and the initial phase as the field intensity of an initial field in a target area in the quiet zone plane;
step 203, calculating the frequency domain phases of the initial field transmitted to the at least two preset defocusing planes through the angular spectrum after passing through the medium lens;
step 204, the computer calculates frequency domain amplitude values of the initial field transmitted to the at least two preset defocusing planes through the angular spectrum after the initial field passes through the medium lens; respectively taking the frequency domain amplitude and the frequency domain phase of the at least two preset defocusing planes as the field intensity of the frequency domain field of the defocusing plane;
step 205, acquiring a field intensity corresponding to the spatial field based on the field intensity of the frequency domain field, wherein the field intensity of the spatial field comprises a spatial amplitude and a spatial phase; taking the actual amplitude and the spatial phase in the at least two preset defocusing planes as the field intensity of the actual field in the defocusing plane;
step 206, calculating the field intensity of the initial field based on the field intensity of the actual field and the field intensity of the airspace field, and taking the solved field intensity of the initial field as the field intensity of the heterogeneous input field; the field intensity of the heterogeneous input field comprises a heterogeneous input phase and a heterogeneous input amplitude;
step 207, adopting a GS-HIO algorithm to carry out iterative computation of preset times on the field intensity of the heterogeneous input field to obtain a target recovery phase;
step 208, judging whether the GS-HIO algorithm is converged, and if so, executing step 209; if not, return to step 202;
in step 209, the target recovery phase obtained at the time of convergence is used as a phase recovery result.
According to the method for recovering the phase in the antenna measurement system through the amplitude of the defocusing plane of the lens, provided by the embodiment of the invention, the dielectric lens is arranged in the quiet zone plane of the antenna measurement system; the method comprises the steps of firstly collecting actual amplitude values in at least two preset defocusing planes of a medium lens by using a probe, then generating an initial amplitude value and an initial phase value by using a computer as field intensity of an initial field, calculating the initial field, transmitting an angle spectrum to the frequency domain phase value of the preset defocusing planes and the corresponding frequency domain amplitude value after the initial field passes through the medium lens, using the frequency domain amplitude value and the frequency domain phase value as field intensity of a frequency domain field, then obtaining field intensity of a space domain field corresponding to the frequency domain field, using the space domain phase value and the actual amplitude value as field intensity of the actual field, solving the field intensity of the initial field based on the field intensity of the actual field and the field intensity of the space domain field, using the field intensity of the initial field as field intensity of a heterogeneous input field, and then carrying out preset times of iterative calculation on the field intensity of the heterogeneous input field by using a GS-HIO algorithm to obtain a phase recovery result. In the embodiment of the invention, the GS-HIO algorithm is adopted to recover the phase through the amplitude, so that the convergence speed of the algorithm is accelerated, and the accuracy of recovering the phase through the amplitude is improved through multiple iterative computations.
The shape of the quiet zone can be various according to the actual measurement requirements, for example, the shape of the quiet zone can be a sphere, a cylinder, a cuboid and the like.
The probe may be a device for receiving electromagnetic wave signals and conducting the signals, such as a horn antenna.
As described above, the dielectric lens in the embodiment of the present invention can generate a predetermined phase shift. In the embodiment of the invention, the position of the defocusing plane needing to acquire the actual amplitude can be selected in advance. The out-of-focus plane of the media lens refers to a plane other than the focal plane of the media lens. For example, for a media lens composed of 59 × 59 unit modules with a focal length of 30mm, the focal plane is the plane where the focal point is located, and there may be multiple out-of-focus planes of the media lens. In the embodiment of the invention, the number of the preselected defocusing planes is more than or equal to two, so that the actual test requirement can be met.
For example, when a measurement is performed using a media lens having a focus of 30mm, the two preset defocus planes may be selected to be defocus planes having focuses of 40mm and 60mm from the media lens.
As described above, when the actual amplitudes are collected at the preset at least two defocus planes, the actual amplitudes may be collected by using the probe, and meanwhile, in order to reduce the amount of calculation and meet the requirement of the test, the actual amplitudes may be collected by using a half-wavelength collection step. For example, for an electromagnetic wave having a frequency of 220GHz, the corresponding half wavelength is 0.68 mm. Of course, the collection may be performed by other reasonable methods, and is not particularly limited herein. The number of actual amplitudes that need to be acquired can be determined according to the area of the target region where phase recovery is needed and the actual measurement requirements.
In the embodiment of the present invention, both the initial phase and the initial amplitude in the target region of the quiet zone plane may be randomly generated by a computer. Number of initial amplitudes and initial phases generatedRelated to the area of the target region. For example, for an area of 40.12 x 40.12mm2When measuring electromagnetic waves with a frequency of 220GHZ, the corresponding dielectric lens may be formed by 59 × 59 unit modules, that is, the dielectric lens formed by 59 × 59 unit modules may generate a one-to-one phase shift for the initial phase in the target region. Therefore, for this example, the number of initial amplitudes and initial phases that need to be generated is 59 × 59.
As described above, the initial phase may be randomly generated, and in another embodiment, in order to further increase the convergence speed of the algorithm, the initial phase may be set based on the antenna aperture, which is not specifically limited herein.
And after the initial amplitudes and the initial phases with the same number are obtained, taking the initial amplitudes and the initial phases as the field intensity of the initial field. For the above example, 59 × 59 discrete values of the field strength of the initial field are obtained.
Accordingly, the number of actual amplitudes that need to be collected in the preset defocus plane may be a number corresponding to twice the area of the target region, and in addition, for convenience of calculation, the number of the collected actual amplitudes may be selected to be singular. For example, 40.12 x 40.12mm for the target region mentioned above2For the field strength discrete values of 59 × 59 initial fields, the number of actual amplitudes to be collected may be 59 × 2+1, that is, the number of actual amplitudes to be collected is 119 × 119 discrete values, and the corresponding area is 80.92 × 80.92mm2. Of course, for the present example, the number of actual amplitudes collected in each preset defocus plane may also be 59 × 2-1, i.e., 117 × 117 discrete values.
In practical tests, in order to avoid the influence of other areas on signals in the target area, the wave-absorbing material is usually placed in the areas above, below, on the left, and on the right of the dielectric lens, so the actual amplitude outside the target area may be 0.
As mentioned above, 40.12 x 40.12mm for the above target area2For example, the dielectric lens disposed in the plane of the dead zone can be used for at least 59 x 59 of the above-mentioned dielectric lensesDiscrete values of the field strength of the initial field produce a one-to-one phase shift, so that a dielectric lens of 59 × 59 unit modules can be selected. The unit constituting the dielectric lens can be a rectangular solid metamaterial dielectric block with a square top surface with a side length of 0.68mm and an air cavity on the top surface in the above example, and correspondingly, the working surface area of the dielectric lens is 40.12-40.12 mm2. Of course, the area of the dielectric lens may be larger than the area of the target region, for example, for this example, a dielectric lens consisting of 119 × 119 unit modules may be used, and accordingly, the area of the working surface of the dielectric lens is 80.92 × 80.92mm2. The phase shift generated by each unit module of the dielectric lens can be determined by the formula I.
As described above, the dielectric lens in the quiet zone plane can implement a fourier transform, transforming the electromagnetic field in the space domain to the frequency domain. In addition, in the angular spectrum transmission process, only the phase is affected, and the value of the amplitude is not changed, so that the angular spectrum transmission can be performed on the initial field after passing through the dielectric lens in the embodiment, and therefore the effect of only changing the phase without changing the amplitude can be achieved, and the measurement is more accurate. The frequency domain phase within the target region may be obtained by adding the initial phase to the phase shift of the corresponding unit block in the dielectric lens.
Specifically, the above process may be implemented by a program in a computer, that is, the phase shift generated by the lens and the distance between the preset defocus plane and the medium lens are input to the computer, and the computer generates an initial phase and an initial amplitude, so as to obtain the frequency domain phase.
In the region where the actual amplitude is acquired, the frequency domain phase of the area outside the target region may be obtained by:
as described above, in practical tests, the wave-absorbing material can be placed in the regions above, below, on the left, and on the right of the dielectric lens, so as to avoid the influence of signals in other regions on the dielectric lens, and achieve the result that the initial phase of the region is 0. The frequency domain phase may be obtained by adding a phase shift generated by a unit block of the corresponding dielectric lens to the initial phase of 0, and the phase shift may be obtained by the above formula.
Meanwhile, the frequency domain amplitude of the initial amplitude after passing through the medium lens and the angular spectrum transmission can be obtained in the preset defocusing plane. The frequency domain amplitude may be obtained by a program installed in a computer, the specific process is the same as the method for obtaining the frequency domain phase, which is not described herein again, and the initial amplitude outside the target region may be 0.
And after the frequency domain amplitude and the frequency domain phase are obtained, taking the frequency domain amplitude and the corresponding frequency domain phase as the field intensity of the frequency domain field. For the above example, the field strength of the frequency domain field includes 119 × 119 frequency domain amplitudes, and corresponding frequency domain phase discrete values.
And after the field intensity of the frequency domain field is obtained, performing inverse Fourier transform on the field intensity of the frequency domain field, and converting the field intensity into a space domain field, so as to obtain the field intensity value of the space domain field corresponding to each frequency domain field, wherein the field intensity value of the space domain field comprises a space domain amplitude and a corresponding space domain phase. For the above example, the field strength value of each spatial field includes 119 × 119 spatial amplitudes and spatial phases.
And taking the actual amplitude and the corresponding spatial phase as the field intensity of the actual field. For the above example, the actual field strength includes 119 × 119 actual amplitudes and corresponding discrete values of spatial phase.
After the field strengths of the actual field and the spatial field of the at least two preset defocusing planes are obtained, the initial phase of the initial field can be calculated by adopting a least square method for each preset defocusing plane based on the field strengths of the actual field and the spatial field, the solved initial phase is used as a heterogeneous input phase, and the initial amplitude and the corresponding heterogeneous input phase are used as field values of the heterogeneous input field. Specifically, it can be calculated by the following formula:
Qi=(bi-Aix)2formula three
In the above formula, i is the number of the preset defocusing plane, xFor the field strength of the initial field to be determined, the field strength of the initial field comprises an initial amplitude and an initial phase, i.e. x ═ x | ejθWherein | x | is an initial amplitude value, and θ is an initial phase; a. theix is the field intensity of the airspace field corresponding to the defocused plane, and the field intensity of the airspace field includes the airspace amplitude and the airspace phase, and specifically can be expressed by the following formula:
wherein, | Aix | is the airspace amplitude of a preset defocusing plane; thetaiThe spatial phase of the defocusing plane is preset.
biThe field intensity of the actual field in the preset defocusing plane includes an actual amplitude and a spatial phase, and may be specifically expressed by the following formula:
bi=|bi|ejθiformula five
Wherein, | biAnd | is the actual amplitude acquired at the corresponding defocused plane.
In the second to fifth formulas, the spatial domain amplitude and the actual amplitude are known quantities, and the frequency domain phase is obtained by adding the initial phase to the phase shift generated by the unit module of the corresponding dielectric lens, and the spatial domain phase is obtained by performing inverse fourier transform on the frequency domain phase. Therefore, the field strength value of the initial field can be solved through the second formula to the fifth formula, and the solved field strength of the initial field can be recorded as the field strength of the heterogeneous input field.
After the field intensity of the heterogeneous input field is obtained, a GS-HIO joint algorithm can be adopted to carry out iteration calculation on the field intensity of the heterogeneous input field for preset times.
The GS-HIO algorithm comprises a GS algorithm and a HIO algorithm, the GS (Gerchberg-Saxton, Gerchberg-Saxon) algorithm is an iterative algorithm, the traditional GS algorithm mainly comprises a Fourier transform and inverse transform process, and an unknown phase distribution is solved by adopting a multi-iteration method, but the convergence speed of the GS algorithm is low, so that the convergence speed of the GS algorithm can be accelerated by adopting the HIO (hybrid input-output) algorithm in the embodiment of the invention, so that the test can achieve a good effect.
As a specific implementation manner, as shown in FIG. 2b, when the iteration number is greater than 250, the convergence error may be stabilized between 1E ^ 14 to 1E ^ 16, i.e., the error is stabilized at 1E ^ 15, i.e., the convergence error of the algorithm is smaller, which may achieve a better experimental effect, and therefore, the preset number may be set to 400. Of course, the specific preset times can be set according to the requirements of specific experiments.
For a heterogeneous input phase in the heterogeneous input field, after the GS-HIO algorithm is used for the preset number of iterations, a phase value is obtained, and the phase value can be recorded as the value of the corresponding target recovery phase. At this time, if the GS-HIO algorithm converges, the target recovery phase is the final phase recovery result; if the GS-HIO algorithm has not converged, that is, it is stated that the target recovery phase obtained at this time cannot meet the requirement, that is, the value of the corresponding initial phase is not appropriate, so the step of generating the initial phase and the initial amplitude may be returned, that is, a group of the initial phase and the initial amplitude is regenerated, and the initial phase and the corresponding initial amplitude are used as the field strength of the new initial field, and the steps 203 to 208 are continued.
As a specific implementation manner of the embodiment of the present invention, before calculating the field strength of the heterogeneous input field, an error between the spatial amplitude and the actual amplitude may be calculated, based on the embodiment shown in fig. 2a, as shown in fig. 3, fig. 3 is a second flowchart of the phase recovery method in the antenna measurement system according to the embodiment of the present invention, and before the step 206, the specific steps may include:
step 306, calculating the amplitude error between the spatial domain amplitude and the actual amplitude based on the actual amplitude and the spatial domain amplitude;
step 307, judging whether the amplitude error is larger than a preset threshold value;
if the amplitude error is not greater than the preset threshold, executing step 308;
if the amplitude error is greater than the preset threshold, executing the step 206, calculating the field intensity of the initial field based on the field intensity of the actual field and the field intensity of the airspace field, and taking the solved field intensity of the initial field as the field intensity of the heterogeneous input field; the field intensity of the heterogeneous input field comprises a heterogeneous input phase and a heterogeneous input amplitude;
and step 308, taking the initial phase as a phase recovery result.
Specifically, the amplitude error between the spatial amplitude and the actual amplitude can be calculated by the following formula:
wherein, as described above, i is the number of the preset defocus planes, n is the number of the preset defocus planes, | Aix | represents the spatial amplitude of the spatial field, | biAnd | represents the actual amplitude of the actual field of the preset defocusing plane.
As a specific embodiment, the predetermined threshold may be 1E ^ -20.
If the calculated amplitude error is smaller than the preset threshold, the initial phase is properly selected, and the initial phase can be used as a phase recovery result.
And if the calculated amplitude error is larger than a preset threshold value, returning to the step of calculating the field intensity of the initial field based on the field intensity of the actual field and the field intensity of the airspace field.
By judging the error, the initial phase can be directly used as a phase recovery result under the condition of reasonable initial phase selection, so that the calculation amount is greatly reduced.
As a specific implementation manner of the embodiment of the present invention, based on fig. 2a, as shown in fig. 4, in step 207, performing iterative computation on the field strength of the heterogeneous input field for a preset number of times by using a GS-HIO algorithm to obtain a target recovery phase, which may specifically include the following steps:
step 407, determining whether the number of times of executing the GS algorithm reaches a second preset number of times: if not, go to step 408, and if so, go to step 409;
step 407 determines whether the condition for starting the GS algorithm is met. The second preset number of times for executing the GS algorithm may be considered to be set according to specific test requirements, for example, as a specific embodiment, the second preset number of times may be 2, that is, when the GS-HIO algorithm is started to be executed, it is required to first determine whether the number of times for executing the GS algorithm reaches two times. Of course, the second preset number of times may be 3, 4, 5, 6, etc., and is not limited herein.
Here, the determination of whether the number of times of executing the GS algorithm reaches the second preset number of times may be performed by a remainder operation, and specifically, refer to the following description of step 408.
Step 408, iterative calculation is carried out on the field intensity of the heterogeneous input field by adopting a GS algorithm; step 410 is executed;
and if the number of times of executing the GS algorithm in the current cycle does not reach the second preset number of times, calculating the field intensity of the heterogeneous input field by adopting the GS algorithm. Meanwhile, in the embodiment of the present invention, the dielectric lens may implement conversion from an electromagnetic field space domain to a frequency domain, that is, may implement fourier transform, and therefore, the GS algorithm in the embodiment of the present invention may specifically include the following steps:
taking the field intensity of the heterogeneous input field as the field intensity of a new initial field, returning to the step 203, calculating the frequency domain phases of the initial field transmitted to the at least two preset defocusing planes through the angular spectrum after the initial field passes through the dielectric lens; the field strength of the new initial field may be expressed as x ═ xkWhere k is the number of times the GS-HIO algorithm is currently executed, xkNamely the heterogeneous input fieldOf the field strength of (a).
409, performing iterative computation on the field intensity of the heterogeneous input field for a third preset time by adopting an HIO algorithm to obtain a recovery phase; step 410 is executed;
and if the number of times of executing the GS algorithm reaches a second preset number of times, performing iterative calculation on the field intensity of the heterogeneous input field by adopting an HIO algorithm. The third preset number of times for performing iterative computation on the field strength of the heterogeneous input field by using the HIO algorithm may be preset according to a specific test requirement, and meanwhile, for convenience of testing, the preset number of times may be an integral multiple of the sum of the second preset number of times and the third preset number of times. For example, when the preset number is 400 and the second preset number is 2, the third preset number may be 38, and in this case, the sum of the second preset number and the third preset number is 40, and 400 is an integer multiple of 40. It can be understood that: the execution of the GS-HIO algorithm includes two loop processes, for example, for the above-mentioned, for example, 2 times of the GS algorithm and 38 times of the HIO algorithm, a small loop process is formed, and the execution of the GS-HIO algorithm with the predetermined number of times of 400 is to execute the loop process 10 times.
Accordingly, for this example, the above-described determination of whether the number of times the GS algorithm is continuously executed reaches a second predetermined number of times may be a determination of whether mod (1,40) > 2 is satisfied.
The HIO algorithm may specifically include the following steps:
taking the field intensity of the heterogeneous input field in the target region as the field intensity in the new initial field target region, wherein the field intensity outside the new initial field target region can be obtained by the following formula:
x=xk-1-βxkformula seven
In the seventh formula, x is the field intensity of the initial field outside the target area, k is the current number of times of executing the GS-HIO algorithm, and correspondingly, xk-1I.e. the field strength, x, of the last heterogeneous input fieldkThat is, the field strength of the current heterogeneous input field, where β is an artificially set coefficient, and as a specific implementation manner, β may be 1, that is, the field strength outside the target region of the new initial field may be the previous obtained heterogeneous field strengthAnd constructing the field intensity difference value of the field intensity of the input field and the field intensity of the heterogeneous input field.
For the above target area 40.12 x 40.12mm2In the example where the dielectric lens is composed of 119 × 119 unit modules, the target region is a portion of the region corresponding to the dielectric lens except for the target region.
After the field strengths in the target region and outside the target region of the new initial field are obtained, the step 203 may be returned to, and after the initial field is calculated and passes through the dielectric lens, the frequency domain phases of the angular spectrum transmitted to the at least two preset defocusing planes are calculated.
After the third preset number of times of the HIO algorithm, a plurality of phase values within the target area are obtained, and these phase values may be recorded as the recovered phase.
Step 410, judging whether the number of times of executing the GS-HIO algorithm reaches the preset number of times; if yes, go to step 411, otherwise go to step 407;
step 411, taking the recovery phase as a target recovery phase.
As described above, after the small loop is executed once, it may be determined whether the current number of times of executing the GS-HIO algorithm reaches the preset number of times, and if the current number of times of executing the GS-HIO algorithm does not reach the preset number of times, the step 407 is returned to, and the steps 407 to 410 are executed again. And if the preset times are reached, taking the recovery phase obtained by the HIO algorithm as a target recovery phase, and executing the subsequent steps.
As shown in fig. 5a and 5b, fig. 5a and 5b are graphs comparing the phase recovered by the method provided by the embodiment of the present invention with the original phase in the x-axis direction and the y-axis direction, respectively, where the original phase may be obtained by grasp platform simulation. Therefore, the error between the obtained recovered phase and the original phase is within 0.0001 degree, the experimental requirement can be met, and a better effect is achieved.
Based on the same technical concept as the phase recovery apparatus in the antenna measurement system, as shown in fig. 6, an embodiment of the present invention further provides a phase recovery apparatus in an antenna measurement system, and as shown in the figure, the apparatus may include:
an actual amplitude acquisition module 601, configured to obtain, by a computer, actual amplitudes in at least two preset defocus planes of the media lens acquired by a probe;
an initial amplitude and phase generating module 602, configured to generate an initial phase and an initial amplitude, where the initial amplitude and the initial phase are used as field strengths of an initial field in a target region in the quiet zone plane;
a frequency domain phase calculation module 603, configured to calculate frequency domain phases of the initial field that are transmitted to the at least two preset defocused planes through an angular spectrum after passing through the dielectric lens;
a frequency domain amplitude calculation module 604, configured to calculate, by a computer, frequency domain amplitudes of the initial field that are transmitted to the at least two preset defocus planes through an angular spectrum after passing through the dielectric lens; respectively taking the frequency domain amplitude and the frequency domain phase of the at least two preset defocusing planes as the field intensity of the frequency domain field of the defocusing plane;
a spatial field strength obtaining module 605, configured to obtain a field strength of a corresponding spatial field based on the field strength of the frequency domain field, where the field strength of the spatial field includes a spatial amplitude and a spatial phase; taking the actual amplitude and the spatial phase in the at least two preset defocusing planes as the field intensity of the actual field in the defocusing plane;
a heterogeneous input field strength calculation module 606, configured to calculate a field strength of the initial field based on the field strength of the actual field and the field strength of the airspace field, and use the solved field strength of the initial field as the field strength of the heterogeneous input field; the field intensity of the heterogeneous input field comprises a heterogeneous input phase and a heterogeneous input amplitude;
an iterative computation module 607, configured to perform iterative computation for a preset number of times on the field strength of the heterogeneous input field by using a GS-HIO algorithm, so as to obtain a target recovery phase;
a judging module 608, configured to judge whether the GS-HIO algorithm converges, and if so, take a target recovery phase obtained during convergence as a phase recovery result; and if not, returning to the step of generating the initial phase and the initial amplitude, and taking the initial amplitude and the initial phase as the field intensity of the initial field in the target area in the quiet zone plane.
According to the method for recovering the phase in the antenna measurement system through the amplitude of the defocusing plane of the lens, provided by the embodiment of the invention, the dielectric lens is arranged in the quiet zone plane of the antenna measurement system; the method comprises the steps of firstly collecting actual amplitude values in at least two preset defocusing planes of a medium lens by using a probe, then generating an initial amplitude value and an initial phase value by using a computer as field intensity of an initial field, calculating the initial field, transmitting an angle spectrum to the frequency domain phase value of the preset defocusing planes and the corresponding frequency domain amplitude value after the initial field passes through the medium lens, using the frequency domain amplitude value and the frequency domain phase value as field intensity of a frequency domain field, then obtaining field intensity of a space domain field corresponding to the frequency domain field, using the space domain phase value and the actual amplitude value as field intensity of the actual field, solving the field intensity of the initial field based on the field intensity of the actual field and the field intensity of the space domain field, using the field intensity of the initial field as field intensity of a heterogeneous input field, and then carrying out preset times of iterative calculation on the field intensity of the heterogeneous input field by using a GS-HIO algorithm to obtain a phase recovery result. In the embodiment of the invention, the GS-HIO algorithm is adopted to recover the phase through the amplitude, so that the convergence speed of the algorithm is accelerated, and the accuracy of recovering the phase through the amplitude is improved through multiple iterative computations.
As a specific implementation manner of the embodiment of the present invention, the apparatus may further include:
the error calculation submodule calculates the amplitude error between the actual amplitude and the airspace amplitude based on the actual amplitude and the airspace amplitude;
the error judgment submodule is used for judging whether the amplitude error is larger than a preset threshold value or not;
if the amplitude error is not larger than a preset threshold value, taking the initial phase as a phase recovery result;
and if the amplitude error is larger than a preset threshold value, executing the step of calculating the field intensity of the initial field based on the field intensity of the actual field and the field intensity of the airspace field.
As a specific implementation manner of the embodiment of the present invention, the error calculation sub-module may be specifically configured to:
the amplitude error is calculated according to the following equation:
wherein i is the number of the preset defocusing planes, n is the number of the preset defocusing planes, | Aix | represents the spatial amplitude of the spatial field of the preset defocusing plane, | biAnd | represents the actual amplitude of the actual field of the preset defocusing plane.
As a specific implementation manner of the embodiment of the present invention, the heterogeneous input phase calculation module 606 may be specifically configured to: and calculating the field intensity of the initial field by adopting a least square method based on the field intensity of the actual field and the field intensity of the airspace field.
As a specific implementation manner of the embodiment of the present invention, the iterative computation module 607 may specifically include:
the first judgment sub-module may be configured to judge whether the number of times of executing the GS algorithm reaches a second preset number of times;
the GS algorithm calculating sub-module can be used for performing iterative calculation on the field intensity of the heterogeneous input field by adopting a GS algorithm if the number of times of executing the GS algorithm does not reach a second preset number of times;
the HIO algorithm calculation submodule can be used for carrying out iterative calculation of third preset times on the field intensity of the heterogeneous input field by adopting the HIO algorithm if the times of executing the GS algorithm reach second preset times, so as to obtain a recovery phase;
a second determining sub-module, configured to determine whether a sum of the times of executing the GS algorithm and the HIO algorithm reaches the preset times;
if the sum of the times of executing the GS algorithm and the HIO algorithm reaches the preset times, taking the recovery phase as a target recovery phase;
and if the sum of the times of executing the GS algorithm and the HIO algorithm does not reach the preset times, returning to the step of judging whether the times of executing the GS algorithm reaches a second preset time.
As a specific implementation manner of the embodiment of the present invention, the GS algorithm calculation sub-module may be specifically configured to:
taking the field intensity of the heterogeneous input field as the field intensity of a new initial field; returning to the step of calculating the frequency domain phase of the initial field after passing through a dielectric lens, and transmitting an angular spectrum to the at least two preset defocusing planes;
the HIO algorithm calculation sub-module may be specifically configured to:
taking the field intensity of the heterogeneous input field in the target region as the field intensity in the target region of the new initial field; subtracting the field intensity of the heterogeneous input field of the current time from the field intensity of the heterogeneous input field obtained last time outside the target area to obtain a field intensity difference, and taking the field intensity difference as the field intensity outside the preset area of the new initial field;
and returning to the step of calculating the frequency domain phase of the initial field after passing through the dielectric lens, and transmitting the angular spectrum to the at least two preset defocusing planes.
An embodiment of the present invention further provides an electronic device, as shown in fig. 7, including a processor 701, a communication interface 702, a memory 703 and a communication bus 704, where the processor 701, the communication interface 702, and the memory 703 complete mutual communication through the communication bus 704,
a memory 703 for storing a computer program;
the processor 701 is configured to implement the following steps when executing the program stored in the memory 703:
the computer obtains actual amplitude values in at least two preset defocusing planes of the medium lens, which are acquired by the probe;
generating an initial phase and an initial amplitude, and taking the initial amplitude and the initial phase as the field intensity of an initial field in a target region in the quiet zone plane;
calculating the frequency domain phases of the initial field transmitted to the at least two preset defocusing planes through an angular spectrum after passing through a medium lens;
the computer calculates the frequency domain amplitude values of the initial field transmitted to the at least two preset defocusing planes through the angular spectrum after the initial field passes through the medium lens; respectively taking the frequency domain amplitude and the frequency domain phase of the at least two preset defocusing planes as the field intensity of the frequency domain field of the defocusing plane;
acquiring field intensity corresponding to the spatial field based on the field intensity of the frequency domain field, wherein the field intensity of the spatial field comprises a spatial amplitude and a spatial phase; taking the actual amplitude and the spatial phase in the at least two preset defocusing planes as the field intensity of the actual field in the defocusing plane;
calculating the field intensity of the initial field based on the field intensity of the actual field and the field intensity of the airspace field, and taking the solved field intensity of the initial field as the field intensity of the heterogeneous input field; the field intensity of the heterogeneous input field comprises a heterogeneous input phase and a heterogeneous input amplitude;
performing iterative computation on the field intensity of the heterogeneous input field for preset times by adopting a GS-HIO algorithm to obtain a target recovery phase;
judging whether the GS-HIO algorithm is converged, and if so, taking a target recovery phase obtained in the convergence as a phase recovery result; and if not, returning to the step of generating the initial phase and the initial amplitude, and taking the initial amplitude and the initial phase as the field intensity of the initial field in the target area in the quiet zone plane.
According to the method for recovering the phase in the antenna measurement system through the amplitude of the defocusing plane of the lens, provided by the embodiment of the invention, the dielectric lens is arranged in the quiet zone plane of the antenna measurement system; the method comprises the steps of firstly collecting actual amplitude values in at least two preset defocusing planes of a medium lens by using a probe, then generating an initial amplitude value and an initial phase value by using a computer as field intensity of an initial field, calculating the initial field, transmitting an angle spectrum to the frequency domain phase value of the preset defocusing planes and the corresponding frequency domain amplitude value after the initial field passes through the medium lens, using the frequency domain amplitude value and the frequency domain phase value as field intensity of a frequency domain field, then obtaining field intensity of a space domain field corresponding to the frequency domain field, using the space domain phase value and the actual amplitude value as field intensity of the actual field, solving the field intensity of the initial field based on the field intensity of the actual field and the field intensity of the space domain field, using the field intensity of the initial field as field intensity of a heterogeneous input field, and then carrying out preset times of iterative calculation on the field intensity of the heterogeneous input field by using a GS-HIO algorithm to obtain a phase recovery result. In the embodiment of the invention, the GS-HIO algorithm is adopted to recover the phase through the amplitude, so that the convergence speed of the algorithm is accelerated, and the accuracy of recovering the phase through the amplitude is improved through multiple iterative computations.
The communication bus mentioned in the electronic device may be a Peripheral Component Interconnect (PCI) bus, an Extended Industry Standard Architecture (EISA) bus, or the like. The communication bus may be divided into an address bus, a data bus, a control bus, etc. For ease of illustration, only one thick line is shown, but this does not mean that there is only one bus or one type of bus.
The communication interface is used for communication between the electronic equipment and other equipment.
The Memory may include a Random Access Memory (RAM) or a Non-Volatile Memory (NVM), such as at least one disk Memory. Optionally, the memory may also be at least one memory device located remotely from the processor.
The Processor may be a general-purpose Processor, including a Central Processing Unit (CPU), a Network Processor (NP), and the like; but also Digital Signal Processors (DSPs), Application Specific Integrated Circuits (ASICs), Field Programmable Gate Arrays (FPGAs) or other Programmable logic devices, discrete Gate or transistor logic devices, discrete hardware components.
In yet another embodiment provided by the present invention, there is also provided a computer readable storage medium having stored therein a computer program which, when executed by a processor, performs the steps of any of the above methods for recovering phase in an antenna measurement system by amplitude at a lens defocus plane.
In yet another embodiment provided by the present invention, there is also provided a computer program product containing instructions which, when run on a computer, cause the computer to perform any of the above embodiments of the method for recovering phase in an antenna measurement system by amplitude of a lens out-of-focus plane.
In the above embodiments, the implementation may be wholly or partially realized by software, hardware, firmware, or any combination thereof. When implemented in software, may be implemented in whole or in part in the form of a computer program product. The computer program product includes one or more computer instructions. When loaded and executed on a computer, cause the processes or functions described in accordance with the embodiments of the invention to occur, in whole or in part. The computer may be a general purpose computer, a special purpose computer, a network of computers, or other programmable device. The computer instructions may be stored in a computer readable storage medium or transmitted from one computer readable storage medium to another, for example, from one website site, computer, server, or data center to another website site, computer, server, or data center via wired (e.g., coaxial cable, fiber optic, Digital Subscriber Line (DSL)) or wireless (e.g., infrared, wireless, microwave, etc.). The computer-readable storage medium can be any available medium that can be accessed by a computer or a data storage device, such as a server, a data center, etc., that incorporates one or more of the available media. The usable medium may be a magnetic medium (e.g., floppy Disk, hard Disk, magnetic tape), an optical medium (e.g., DVD), or a semiconductor medium (e.g., Solid State Disk (SSD)), among others.
It is noted that, herein, relational terms such as first and second, and the like may be used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Also, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus. Without further limitation, an element defined by the phrase "comprising an … …" does not exclude the presence of other identical elements in a process, method, article, or apparatus that comprises the element.
All the embodiments in the present specification are described in a related manner, and the same and similar parts among the embodiments may be referred to each other, and each embodiment focuses on the differences from the other embodiments. In particular, as for the apparatus, the electronic device, the storage medium and the program product, since they are substantially similar to the method embodiments, the description is relatively simple, and in relation to what can be referred to the partial description of the method embodiments.
The above description is only for the preferred embodiment of the present invention, and is not intended to limit the scope of the present invention. Any modification, equivalent replacement, or improvement made within the spirit and principle of the present invention shall fall within the protection scope of the present invention.
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