SE528829C2 - Antenna efficiency measurement method and system therefore - Google Patents

Abstract

The present invention relates to a method for determining antenna efficiency for an electrically small multi band antenna, comprising the following steps: measuring a complex S<SUB>11,fs </SUB>parameter value of said electrically small multi band antenna, when said electrically small multi band antenna is arranged in free space, for a plurality of frequencies; measuring a complex S<SUB>11,c</SUB>(d) parameter value of said electrically small multi band antenna, when said electrically small multi band antenna is arranged in a cavity, for a plurality of volumes V(d) of said cavity, for said plurality of frequencies; determining, for each frequency of said plurality of frequencies, the outermost values of said complex S<SUB>11,c</SUB>(d) parameter values, wherein the imaginary part of the S<SUB>11,c</SUB>(d) parameter values are plotted against the real part of the S<SUB>11,c</SUB>(d) parameter values for said plurality of volumes V(d) of said cavity; fitting, for each frequency of said plurality of frequencies, said outermost values to a circle; and determining, for each frequency of said plurality of frequencies, said antenna efficiency based on said circle and said complex S<SUB>11,fs </SUB>parameter value.

Description

U1 RJ Ca C, Ä- uu This object, among others, is obtained by a net method and a system for determining antenna efficiency for an electrically small multiband antenna according to the appended claims.

Antenna efficiency can be accurately determined for different types of small antennas and especially for different frequencies, due to the use of plotted outermost values, which are then adapted to a circle.

The method according to the invention can be carried out by using a storage means, a vector network analysis unit (VNA) and a cavity with a movable wall.

Additional features and advantages of the present invention will become apparent from the following description.

Brief Description of the Drawings The present invention will be described below in the detailed description of embodiments given in connection with the following figures, which are given by way of illustration only and are thus not limiting of the present invention, in which: Figure 1 illustrates a complex Su parameter plotted for a frequency for an electrically small multiband antenna, according to the present invention, Figure 2 schematically illustrates the determination of ASWW and ASmN values according to the present invention, Figure 3 schematically illustrates an equipment used to perform the method according to the present invention; and LW NJ CS O? w! Figure 4 schematically illustrates a cross section of a cavity with a movable wall.

Detailed Description of Embodiments In the following description, for explanatory and non-limiting purposes, specific details, such as particular techniques and applications, are provided to provide a thorough understanding of the present invention. However, it will be apparent to one skilled in the art that the present invention may be practiced in other embodiments that depart from these specific details. In other cases, detailed description of well-known methods and apparatus is omitted so as not to obscure the description of the present invention with unnecessary details.

A first embodiment of the present invention will now be described with reference to Figures 1-4.

The antenna efficiency of an electrically small multiband antenna, i.e. an antenna having its largest dimension less than / / 4 of the desired resonant frequencies, typically one used in a. portable radio communication apparatus, such as a mobile telephone, a portable telephone, a laptop computer or similar device, such as antennas used for cars or desktops, shall be determined. Both the overall efficiency nmt P (nm ==? Ï) of the antenna and the radiation efficiency of the antenna nad Ill P (Um, = ;; - ï--) can be easily obtained by the present invention.

The antenna is first connected to a vector network analysis unit (VNA), through which the Sn parameter is measured for the antenna in free space.

The Su parameter is the coefficient of reflection from VNA. This is done for a plurality of frequencies, for example 800-2500 MHz or any other desired frequency to obtain a plurality of complex Sun values for mounting in free space of the antenna. The measured complex values are preferably stored in a storage means, such as the memory in a computer.

Next, the antenna is mounted in a cavity 1 with a volume V with a movable wall 2, see figure 4. The antenna 3 is positioned near the wall opposite the movable wall 2. The wall opposite the movable wall 2 is fixed under the mesh but is removable for mounting of the antenna 3 in the cavity 1. The antenna is preferably mounted in the chassis which one intends to use during the measurement to provide as accurate measurements as possible.

Due to the use of the cavity 1 according to the present invention, the position of the antenna near the wall opposite the movable wall is not particularly sensitive with respect to measurement accuracy.

VNA is connected to the antenna 3 through two connections 4, 5 through the cavity 1. If the chassis on which the antenna is mounted is small, with a minimum dimension of about 60 mm, the currents in the connections 4, 5 are noticeably affected by the measurement. However, this can be taken care of by attaching ferrites to the connections 4, 5 to stop these currents from propagating into the cavity 1 and influence the measurements.

For a measurement of 800-2500 MHz is a base area of 200x200 μm? of the cavity suitable. The distance d from the antenna to the movable wall is for such frequencies suitably between 100 and 600 mm, reaching a plurality of volumes V (d) between 0.04 and 0.24 nf. However, the propagation path along the distance d is much more important for the measurement compared to the volume V (d), as why a cavity with only one movable wall is used.

The antenna is reconnected to the VNA, through which the Su parameter is now measured for the antenna arranged inside the cavity. This is performed for 528 Éš29 a plurality of distances d for the same plurality of frequencies as for the measurement in free space, in order to obtain a plurality of complex Sn, c (d) values for cavity mounting of the antenna. The measured complex values are preferably stored in the memory of the computer. In order to accurately determine the antenna efficiency of an antenna covering 800-2500 MHz, it is necessary to measure approximately 50 complex values S11, (d) for each plurality of frequencies. In addition, approximately 30-40 frequencies are measured for the frequency range to accurately determine the antenna efficiency of an antenna covering 800-2500 MHz.

To determine the outermost values of the complex S1,, c (d) values, the imaginary parts of the complex S11, c (d) values are plotted against the real parts of the complex S11, c (d) values of each frequency of the majority of frequencies, see figure 1. These values are presented, for example, in polar coordinates or in Cartesian coordinates. However, experiments have shown that presentation in Cartesian coordinates gives a more accurate result of the antenna efficiency compared to plotting in polar coordinates.

The outermost values are preferably determined as the complex S, 1, c (d) values furthest from the complex center thereof, which are preferably determined in the following manner. The complex midpoint of the values is determined in two steps. The real part of the complex midpoint is determined by dividing by two the highest positive real value added to the highest negative real value, (Re {midpoint} = Reås * l '° (d)} (max): Reismüløxmln)). the main part of the complex center is determined by dividing by two the highest positive imaginary value added to the highest negative imaginary value, (ÜfÅmíflfPlm / ff fi Imßw Imislhxdn fi nin)). Then check in a straight line from the center the complex value (_71 FJ CC »CTC Wi furthest from the center. This is done in several directions, for example every 1 ° of the circle.

The outermost values are then adjusted numerically, minimizing the square root of the mean square deviation to a circle for each frequency of the plurality of frequencies, see Figure 1. An initial condition for adapting the outermost values to a circle uses the midpoint determined above as the center of the circle . Another initial condition for fitting the outermost values to a circle uses a radius of the circle determined as a quarter of the distance between the highest and lowest real values added to a quarter of the distance between the highest and lowest imaginary values, («f: šfxn fl n1 + | hn {s ..,> ¿kn {s.wmmmx) o Next, the antenna activity is determined based on the matched circle and the complex Slhü value of the antenna in free space for each frequency of the plurality of frequencies.

The total antenna efficiency is preferably determined by the following equation: 2 (77 1 =) I '° (ASMAX) * + (ASM, ~) * where Asmm is the maximum distance between the circumference of the circle and the complex Sn fifl value and ASHN is the minimum distance between the circumference of the circle and the complex S value, see Figure 2. 11, fs "'The antenna beam efficiency is preferably determined by the following equation: C fi PG G3 CC' B \ Q 2 1 (Um = _ _ 'd I + (ASMIN) X l-ISUJJ 2)! Where ASM * is the maximum distance between the circumference of the circle and the complex SILÜ value, and ASMN is the minimum distance between the circumference of the circle and the complex SILÜ value , see figure 2.

The method described above provides a system that can be fully automated and that nwcket effectively measures antenna efficiency accurately. Such industrial applicability has not been provided by any previous systems. A system according to the present invention is even more accurate than a dedicated measuring room, at least in the long run, because it comprises fewer components and thereby is more stable and mechanically robust.

A second embodiment of the present invention is now described, which is identical to the first embodiment described above except for the following.

A standard deviation is calculated between the outermost values and the circle, giving an uncertainty factor for Asmp and Asmn. The treatment error is then calculated from equations 1 and 2.

A third embodiment is preferably used when the memory storage capacity is limited when calculating the antenna efficiency. This can be applied to either of the previous embodiments.

The complex Sn @ (d) values plotted inside the outermost values are identified and removed from the storage means.

The present invention has been described for the use of nml band antennas. When the multiband covers over 500 MHz, the advantage of the method of the present invention is noticeably obvious compared to known methods.

An advantage of the system of the present invention, which is small and inexpensive, is that each laboratory space in a factory can have its own measurement system. In this way can. The development time for a new antenna is shortened as development personnel do not have to wait for access to a common measuring room.

It is obvious that the present invention can be varied in a number of ways. Such variations are not to be construed as departing from the scope of the present invention, such as. is defined by the following requirements. All such variations as would be apparent to one skilled in the art are intended to be included within the scope of the present invention, as defined by the appended claims.

Claims (11)

Patent claims A method for determining antenna efficiency of an electrically small multiband antenna, comprising the steps of: - measuring a complex Slh fl parameter value of said electrically small multiband antenna, when said electrically small multiband antenna is arranged in free space, for a plurality of free - sequences, - measuring a complex Snß (d) parameter value for said electrically small multiband antenna, when said electrically small multiband antenna is arranged in a cavity for a plurality of volumes V (d) of said cavity for said plurality of frequencies, - determining , for each frequency of said plurality of frequencies, the outermost values of said complex Sn fl (d) parameter values, wherein the imaginary part of the Sn ((d) parameter values is plotted against the real part of the 'S1Lc (d) parameter values of said plurality volumes V (d) of said cavity, - adjusting for each frequency of said plurality of frequencies of said outermost values into a circle, and - determining, for each frequency of said plurality of frequencies of said antenna efficiency based on said circle and said complex S1L et parameter value. The method of claim 1, wherein said step of determining the outermost values comprises selecting the complex Sn fl (d) values furthest from the complex midpoint thereof. The method of claim 2, wherein said complex midpoint of said complex SuJ (d) values is determined in two steps, the real part of the complex midpoint is determined by dividing by two the highest positive real value added to the highest negative real value, and - the imaginary part of the complex midpoint is determined by dividing by two the highest positive imaginary value added to the highest negative imaginary value. A method according to claim 3, wherein it is checked in a straight line from said complex node point which complex value is furthest from said center point for a plurality of directions, for example every 3 ° of the circle. A method according to any one of claims 1-4, comprising the step of determining a standard deviation between said complex outermost values and said circle to determine treatment errors. A method according to any one of claims 1-5, comprising the following steps: - identifying complex Suß (d) parameter values plotted within said outermost interpolated curve, and - removing said identified complex Snm (d) parameter values from said complex Sum (d) parameter values. A method according to any one of claims 1-6, wherein the antenna total efficiency is determined, for each frequency of said plurality of frequencies, by the following equation: 2 _1) I (n = --_---- '°' ( ASM * + (ASM, ~ where ASWW is the maximum distance between the circumference of said circle and said complex Suü param parameter values and ASMN is 11 the minimum distance between the circumference of said circle and said complex Slh fi parameter value. A method according to any one of claims 1-7, wherein the antenna beam efficiency is determined for each frequency of said plurality of frequencies of the following equation: 1), 2 1 ("fa i - -. D uVÄmx) l + (ASMm I 1-ßhß) wherein Asm is the maximum distance between the circumference of said circle and said complex Sn, "- parameter value, and ASM" is the minimum distance between the circumference of said circle and said complex Sn, - - parameter value. A method according to any one of claims 1-8, wherein said multiband covers at least 500 MHz, preferably 800-2500 MHz. A method according to any one of claims 1-9, wherein said plurality of volumes V (d) are obtained by moving a wall (2) in said cavity (1) a plurality of distances d from said electrically small multiband antenna (3). System for determining antenna efficiency of an electrically small multiband antenna comprising a storage means, a vector network analysis unit and a cavity (1), characterized in that said electrically small multiband antenna (3) is positioned near a first fixed wall in said cavity during measurement. (1) opposite a second movable wall (2) in said cavity (1).