ES2710122B2 - MULTIMODE RESONANT CAMERA WITH MULTIPLE INPUTS AND OUTPUTS FOR THE PERFORMANCE OF WIRELESS DRIVING MEASURES AND TESTS IN LABORATORY WITH CONVERTIBLE WALLS, FLOOR AND CEILING - Google Patents

Description

DESCRIPTION

Field of the Invention

The present invention is an apparatus that allows to control the electromagnetic fields within a chamber formed by one or several multimode resonant cavities in a precise manner in which the walls of one or several cavities are convertible between completely reflective and completely absorbent. The multi-input and multi-output analyzer (MIMO Analyzer) incorporates several elements such as: broadband antennas, the metal part with slots that separates the camera into two cavities, lenses of various kinds, the door, mode shakers Non-metallic removable, the removable rotary table and the walls, which are converted from fully reflective to fully absorbent and vice versa, which together with procedures such as the situation of the elements under test outside the cavity allow to control the electromagnetic fields inside. This control allows to be able to emulate the behavior of wireless communication terminals in different real outdoor and indoor scenarios in a unique way and better emulate the real environment due to the ability of its walls to transform from fully reflective to fully absorbent and vice versa.

Background of the invention

A multi-input and multi-output analyzer is a camera composed of a set of multimode resonant cavities with high Q factor coupled to each other by means of plates with slots that separate them completely, with a very inhomogeneous spatial distribution of the electric and magnetic field. There are various elements and methods to homogenize the field such as: mode agitators, which can be removed and placed, metal parts with grooves, metal and non-metallic mode agitators or the movement of the object under study inside the cavity . So far all mode agitators have been constructed of metallic materials, some with special shapes such as those found in WO200054365. Moreover, pieces Multimode resonant cavities are used in wireless communications applications to perform measurements in the laboratory that emulate those performed for mobile terminals in different propagation environments with an isotropic and Rayleigh distribution. Among the parameters that can be measured are: gain diversity, MIMO capacity, antenna efficiency, absorbed power, correlation between antennas, specific absorption rate, antenna sensitivity, bit error probability (BER), (being revindicated in US Patent 7,286,961 the measurement of the last two in reverberation chamber). Therefore, so far, only isotropic Rayleigh environment measurements could be performed in multimode resonant cavities. In addition, there is the possibility of carrying out measurements with different liquid filled mannequins with losses that simulate different parts of the human body or different tissues allowing, for example, to investigate the effects produced by the user's head on the mobile terminal.

Channel emulators are used in mobile communications applications to inject propagation channel models directly into terminals through cables, regardless of the antennas, or through anechoic chambers (with completely absorbent walls) or reverberation (with completely reflective walls).

US Patent 8,781,797 describes how a channel emulator can be used to import a small number of cells from drive test measurements and add a terrain model and random agitation to reproduce the results obtained directly on the cables of a terminal, calling this process a Virtual Drive Test tool or VDT Tool. In essence in US 8,781,797 it allows to reproduce the fields captured in a drive test in cables, without taking into account the effect of the terminal antennas. As the patent itself says, the repetition of captured data is not enough to try to simulate the real environment and simulations of other parameters such as the terrain model or the density of the network must be added to compensate for such imperfections. It is therefore a simulator.

US 7,324,888 describes a similar technique, this time without using a channel emulator, which uses simulations with different ray tracing to determine the position of a terminal, again by means of simulations.

US 7,349,670 shows the use of a channel emulator connected by a backplane of connectors to a multitude of WiFi terminals for latency measurements using cables, without any camera and without using real results measured outdoors.

Description of the invention

The multi-input and multi-output analyzer object of the invention also incorporates on the multi-input and multi-output analyzer the various elements that allow the introduction and removal of the devices under test continuously or the continuous rotation of multiple devices under test in rotary table and therefore no need to open and close the door, which happens to be used exclusively for cleaning and maintenance. The introduction of several devices under test inside the chamber allows testing in parallel to all of them.

The elements in the ultrafast analyzer with multiple inputs and multiple outputs objects of the invention are:

The first element included in the multi-input and multi-output analyzer is a sampler, which allows samples to be taken from the original drive test signal from time to time, without any modification being made. It is a signal digitizer that must meet the Nyquist criteria. In the case of using mobile phone base station emulators as signal sources this sampler may not be necessary.

The second element included in the multi-input and multi-output analyzer is a channel emulator that allows importing the results of drive test measurements performed abroad sampled from time to time to provide N injection states, and which we will consider a sample of the original signal source, on which no simulation will be added. For the emulation of certain channel models inside the camera, such as the NIST model, it will not be necessary to use this channel emulator, since the camera will perform the emulation in an innate way without signal processing.

The third element included in the multi-input and multi-output analyzer is a calibrator. The calibrator, located between the channel emulator and the multi-input and output analyzer, is responsible for determining for each of the injection states what is the configuration of the analyzer and its path losses that provide a result measured in the identical analyzer to that obtained in the drive test, storing said calibration information for said injection status.

The fourth element included in the multi-input and multi-output analyzer is the set of metal parts with grooves and the parts that open and close said grooves henceforth switching parts. These elements, which separate the transmitters from the receivers, manage to transform the field distribution from one or several antennas or sources with fixed positions into a distribution that has different sources that switch between active and non-active depending on whether the switching elements open and close these slots. In addition, the switching parts can be of different materials, if they are metallic the switching will be on / off by not allowing the signal to pass while if they are made of other materials that can be partially traversed by electromagnetic radiation it will cause a partial activation of said source. Finally, the sources can be partially activated also leaving these slots open.

The fifth element in the multi-input and multi-output analyzer is the manufacture of mode agitators in metallic materials and in materials other than metallic materials. In this way the electromagnetic waves are not only reflected in the metal stirrers, but also are refracted and transmitted. This creates the creation of new useful modes for the various applications.

The sixth element in the analyzer with multiple inputs and multiple outputs is the inclusion of lenses between the signal generation systems and the systems under test. These lenses, for example, will allow modifying the K factor of the simulated environment, that is, the electromagnetic field distribution, focusing on those modes that pass through them. The seventh element in the multi-input and multi-output analyzer is that the signal generating systems are antennas with a characteristic shape that have a large bandwidth thus allowing the use of the multi-input and multi-output analyzer in much of the spectrum.

The eighth element in the analyzer with multiple inputs and multiple outputs is the introduction of elements with losses such as liquids with losses in any position or absorbent elements in the walls, ceiling and floor of the multimode resonant cavities.

The ninth element in the analyzer with multiple inputs and multiple outputs is the door, which allows the introduction of the devices under test into the cavity and is used for cleaning and maintenance, and can be placed on any of the walls of the camera.

The tenth element in the multi-input and multi-output analyzer is the rotary table, which allows homogenizing the electromagnetic field distribution and keeping several devices under test that are going to be tested in parallel.

The first procedure performed by the multi-input and multi-output analyzer is to simultaneously apply the original signal, the sampler, the channel emulator, the calibrator and the multimode resonant chamber to allow measurements, not simulations, to be carried out. Unmodified samples of original drive test signals on any terminal in a laboratory chamber without the need to go outside and with one or more devices under test in parallel. This allows verifying the actual behavior of different terminals, including the effects of their antennas, to the same original drive test signal sample.

The second procedure performed by the multi-input and multi-output analyzer is to remove the stirrers from modes to then place absorbent elements on the walls, floor and ceiling of the chamber, which are metallic and therefore reflective elements, to convert them into absorbent elements The fixing to the floor of the absorbent elements can be done simply by the action of gravity while the fixing to the ceiling and walls can be carried out by means of magnets. In this way the walls, floor and ceiling of the chamber go from being totally reflective to totally absorbent, allowing a wide variety of scenarios of distribution and propagation of modes inside.

The third procedure that the multi-input and multi-output analyzer performs is to remove the absorbents from the walls, ceiling and floor, and place the stirrers so, returning the chamber to a situation with fully reflective walls.

In the drawings:

Figure 1 shows a multi-input and multi-output analyzer (1) comprising the following elements: one or more mode agitators (5), a door (9) for maintenance and cleaning, the sampler (2), the Channel emulator (3), the caliper (4), a grooved metal part (4) and a lens (7).

Figure 2 shows the plant with the view of a mid-height cut of a multi-input and multi-output analyzer (1) comprising the following elements: a removable mode shaker (6), a door (10) located on a side wall, several Broadband antennas (8), absorbent elements (9) on the walls of a single cavity and the rotating table (10).

Figure 3 shows the plant with the view of a mid-height cut of a multi-input and multiple output analyzer (1) of two cavities separated by a grooved metal part (5) in which only one of the two cavities It has the absorbent elements (9) in walls, ceiling and floor.

Embodiment of the invention

The following examples serve to illustrate the invention and should not be considered as limiting its scope.

Example 1: Multi-input and multi-output analyzer for measurements of real drive test samples of wireless communications in the laboratory with different terminals

In the preferred embodiment of the multi-input and multi-output analyzer (1), the number of mode agitators (2) is 2, the sampler (2) can be integrated into the channel emulator (3), the calibrator (4) it acts before carrying out measurements in the analyzer (1), the walls, floor and ceiling of the different cavities that make up the chamber do not have the absorbent elements (9), the door is in the front wall as in figure 1 , the metal part (5) separates two cavities, is grooved and with a lens (7), and has a rotating table (11) inside. This multi-input and multi-output analyzer features the following developments:

The preferred embodiment of the multi-input and multi-output analyzer is designed so that it can be used in the field of wireless communications to measure the behavior of any terminal to the samples of a real drive test signal in the air (over the air) , which has previously been used in the analyzer to calibrate its configuration and trail losses. This provides a competitive advantage over performing new drive tests abroad, which also cannot be repetitive, and allows the design and development of devices to be optimized by observing the measured responses, which are not simulated, that these changes lead to the same real signal of the exterior sampled to a drive test, all without leaving the laboratory.

In this favorite embodiment the absorbent elements could be fixed to the floor, ceiling and walls of one or several cavities, as well as removing the stirrer (s) so that a greater variety of field and propagation distributions could be measured inside of electromagnetic waves.

Claims (4)

1. The multi-input and multi-output analyzer (1) is a multi-mode resonant chamber with one or more cavities comprising the following elements: - A sampler (2) - A channel emulator (3), which can have the sampler (2) incorporated - A caliper (4) - One or more grooved metal parts (5) - One or more mode agitators (6) - One or more lenses (7) - One or several broadband antennas (8) - One or more absorbents (9) - A door (10). - A rotating table (11) 2. An element according to claim 1, characterized in that several terminals can be measured simultaneously, that is, parallel to the same time. 3. An element according to claim 1, characterized in that several wireless communication cells can be measured simultaneously. 3. A method that uses in combination the elements of the multi-input and multi-output analyzer described in claim 1, characterized in that they can be fixed to the walls, ceiling and floor of one or more cavities, one or more elements absorbents in order to convert said walls, ceilings and floors of fully reflective elements into fully absorbent elements. 4. Procedure that uses multiple analyzer elements in combination inputs and multiple outputs described in claim 1 characterized in that it aims to measure, rather than simulate, the response of different wireless terminals to the sample of a signal from a real drive test in the air (over the air), prior calibration.