RU2721587C1 - Multi-mode radio frequency sensor - Google Patents

Abstract

FIELD: radio equipment.

SUBSTANCE: present invention relates to a multimode radio frequency sensor to enable simultaneous implementation of several different functions. Multimode radio frequency sensor is configured to be mounted on a movable platform and comprises a fixed base, a rotating portion which is rotatable relative to fixed base 110, wherein on rotating part 120 RF radar 130 is installed, which contains transmitting and receiving channels with antennas with different aperture, and a monitoring and processing device 140 configured to control the operation modes of the multi-mode RF sensor to induce the multi-mode RF sensor 100 to the operation of RF radar 130 at certain times through the antennas with the first aperture, and at other certain time moments through antennas 132.2, 134.2 with a second aperture.

EFFECT: simple design of the end product, simple circuit of interaction between components of the end product, provision of multimodality using a single RF radar.

13 cl, 3 dwg

Description

Technical field

[0001] The present disclosure relates to radio frequency sensors and, more particularly, to radio frequency sensors that can be mounted on a mobile platform to enable the mobile platform to simultaneously implement at least two functions, for example, a navigation function and an object detection function, such as, for example , obstacles, people, etc.

State of the art

[0002] Today, sensors are widely used to implement navigation in various mobile platforms, such as robots, vehicles, and the like. A specific example of a moving platform is a robot cleaner. Different sensors have different restrictions that increase the likelihood of losing orientation in space and complicate the design of the final product, as well as the interaction scheme between the components of this final product. To solve these technical problems, this application proposes a single multi-mode radio frequency (RF) sensor that can be mounted on a mobile platform to enable the mobile platform to simultaneously implement at least two functions, for example, navigation functions and object detection functions.

[0003] US Patent Application Publication No. US 2018/0098676 A1 (Publication Date: 04/12/2018) addressed to Samsung Electronics Co. Ltd., entitled “CLEANING ROBOT AND METHOD OF CONTROLLING THE SAME”, discloses a cleaning robot and a method for controlling it, and more specifically, a cleaning robot connected to a station based on a radio frequency (RF) signal. The cleaning robot disclosed in this publication, as in the present disclosure, contains a rotating part (antenna), which is configured to receive an RF signal transmitted from the station. Then, the movement of this robot cleaner can be controlled based on the indicator value of the intensity of the received signal extracted from the RF signal to the docking station. However, the decision to cite the publication of a US patent application does not disclose the use of a rotating antenna to enable the simultaneous implementation of a rotating antenna mounted on a moving platform of at least two functions, for example, a navigation function and an object detection function. Obviously, the solution disclosed in the US publication could be supplemented with an additional antenna, but one should understand that such an addition will inevitably complicate the design of the final product, as well as complicate the interaction scheme between the components of this final product.

[0004] According to the authors of the present invention, the closest analogue for the multi-mode RF sensor proposed in this application is the radar system disclosed in patent document CN104316925 (A) (publication date: 01/28/2015) in the name of WUHAN UNIVERSITY, entitled "AZIMUTH SYNTHETIC APERTURE RADAR SYSTEM BASED ON ROTATABLE ANTENNAS . " The specified radar system uses several separate and rotating antennas, but does not disclose a multi-mode RF sensor, as in the present application, which has a single antenna structure and is configured to simultaneously implement a mobile platform on which it is installed at least two functions, for example, functions navigation and feature detection features. In view of the foregoing, one skilled in the art will appreciate that the technical solution from said CN patent document is characterized by a complicated design of the final product, as well as a complicated interaction scheme between the components of this final product. In addition, the technical solution from the said CN patent document does not support multi-mode within a single antenna design, i.e. this solution is not adapted to enable the simultaneous implementation by the moving platform of at least two functions using a single antenna design.

[0005] The multi-mode RF sensor disclosed in this application was designed to solve at least some of the above technical problems in the prior art. Thus, the proposed multi-mode RF sensor allows to simplify the design of the final product, to simplify the interaction between the components of this final product, to provide multi-mode using a single RF radar contained in the proposed multi-mode radio frequency sensor. Other favorable effects and advantages associated with the proposed multi-mode RF sensor and the above technical results of the present invention will be clear to experts in this field after reading the following detailed description.

SUMMARY OF THE INVENTION

[0006] In a first aspect of the present invention, there is provided a multimode radio frequency (RF) sensor 100 mounted on a movable platform 200 for simultaneously realizing the movable platform 200 at least two functions in space 20. This multimode RF sensor 100 includes: a fixed base 110, which is mounted on a movable platform 200, capable of moving in space 20, and a rotating part 120, which is mounted on a fixed base 110 and is configured to rotate relative to the fixed base 110 in a horizontal plane. An RF radar 130 is installed on the rotating part 120, which includes: at least one transmit channel 132, including one or more transmit antennas 132.1 with a first aperture and one or more transmit antennas 132.2 with a second aperture; at least one receiving channel 134, including one or more receiving antennas 134.1 with a first aperture and one or more receiving antennas 134.2 with a second aperture. This multi-mode RF sensor 100 also includes a monitoring and processing device 140 configured to control the operation modes of the multi-mode RF sensor 100, the control including causing the multi-mode RF sensor 100 to operate the RF radar 130 at specific times through antennas 132.1, 134.1 with the first aperture, and at other certain points in time through antennas 132.2, 134.2 with the second aperture. This monitoring and processing device 140 is further configured to send data received by the RF radar 130 to a processor (not illustrated in the figures) of the mobile platform to enable the mobile platform 200 to be controlled based on the data with the implementation of the mobile platform 200 at least two functions at the same time, for example, functions of navigation and detection of objects in space 20.

[0007] In the multi-mode RF sensor 100 according to the first aspect, controlling the operating modes of the multi-mode RF sensor 100 includes: switching the operating mode of the RF radar 130 to a first operating mode including radiation, in a first observation area of the multi-mode RF sensor 100, a plurality of RF signals by means of one or more transmitting antennas 132.1 with a first aperture and receiving a first plurality of reflected RF signals by one or more receiving antennas 134.1 with a first aperture, switching the operating mode of the RF radar 130 to a second operating mode including radiation in the second viewing area of the multi-mode RF a sensor 100, a plurality of RF signals through one or more transmitting antennas 132.2 with a second aperture and receiving a second set of reflected RF signals through one or more receiving antennas 134.2 with a second aperture, obtaining a synthesized aperture covering both the first observation area and the second multi-mode observation area RF a sensor 100, based on the first plurality of reflected RF signals to enable the mobile platform 200 to realize the first function, for example, a navigation function, and detecting objects in a second observation area of the multi-mode RF sensor 100 based on the second plurality of reflected RF signals to enable the mobile platform 200 to implement a second function, for example, an object detection function.

[0008] In the multi-mode RF sensor 100, according to the first aspect, the first aperture is larger than the second aperture and the first viewing area is larger than the second viewing area.

[0009] In the multi-mode RF sensor 100, according to the first aspect, the first viewing area and the second viewing area of the multi-mode RF sensor 100 collectively encompasses a 360-degree viewing area around the movable platform 200.

[0010] In the multi-mode RF sensor 100 according to the first aspect, the monitoring and processing device 140 is further configured to determine the position of the rotating part 120 relative to the stationary base 110 and to determine the operating times of the RF radar 130 through antennas 132.1, 134.1 with the first aperture and the RF operating times radar 130 through antennas 132.2, 134.2 with a second aperture.

[0011] In the multi-mode RF sensor 100 according to the first aspect, the operating times of the RF radar 130 through the antennas 132.1, 134.1 with the first aperture correspond to the first viewing area, and the operating times of the RF radar 130 through the antennas 132.2, 134.2 with the second aperture correspond to the second viewing area .

[0012] The multi-mode RF sensor 100 according to the first aspect further includes a photodiode 150 (see FIG. 3) mounted on the rotating part 120 in a predetermined position and facing the fixed base 110, on which is applied a structure indicating the first viewing area and the second area observing a multi-mode RF sensor 100. Said photodiode 150 is configured to: detect, during rotation of the rotating part 120, a structural feature indicating the transition of the multi-mode RF sensor 100 from one said area to another, and outputting a signal based on a detection result that is used to determine the mentioned time instants. .

[0013] The multi-mode RF sensor 100 according to the first aspect further comprises a stepper motor 160 (see FIG. 2) coupled to the rotating part 120 and calibrated based on a predetermined first viewing area and a second viewing area of the multi-mode RF sensor 100, wherein the stepping motor 160 is configured with the possibility of detecting the transition of the multi-mode RF sensor 100 from one of these areas to another, and issuing a signal based on the detection result, which is used to determine the mentioned time instants.

[0014] In the multi-mode RF sensor 100, according to the first aspect, the monitoring and processing device 140 is integrated with the RF radar 130 as a system on a chip (SoC), a system in a case (SVK), a programmable logic integrated circuit (FPGA), a special purpose integrated circuit (ASIC).

[0015] In the multi-mode RF sensor 100 according to the first aspect, obtaining a synthesized aperture covering both the first observation area and the second observation area of the multi-mode RF sensor 100, based on the first set of reflected RF signals, comprises processing the first set of reflected RF signals using the Fast Fourier transform (FFT).

[0016] In the multi-mode RF sensor 100 according to the first aspect, the RF radar 130 includes at least one RF key 132.3 of at least one transmit channel 132 and at least one RF key 134.3 of at least one receive channel 134, wherein at least one RF key 132.3 of at least one transmit channel 132 is configured to switch between one or more transmit antennas 132.1 with a first aperture and one or more transmit antennas 132.2 with a second aperture based on a specific timing of switching the operating mode of the RF radar 130, and at least one RF key 134.3 of at least one receiving channel 134 is configured to switch between one or more receiving antennas 134.1 with a first aperture and one or more receiving antennas 134.2 with a second aperture based on a specific timing of switching the operating mode of the RF radar 130.

[0017] The movable platform 200 on which the multi-mode RF sensor 100 according to the first aspect is mounted is one of a robot cleaner, a quadcopter, a vehicle in which the multi-mode RF sensor is part of a driver assistance system (ADAS) for cleaning / humidifying an air of a robot, life control robot.

[0018] Other embodiments, possible objects, aspects, features and components of the proposed technical solution are described below in the detailed description.

Brief Description of the Drawings

[FIG. 1] FIG. 1 schematically illustrates a movable platform 200 with a multi-mode radio frequency (RF) sensor 100 mounted thereon in accordance with an embodiment of the present invention.

[FIG. 2] FIG. 2 schematically illustrates a multi-mode radio frequency (RF) sensor 100 in accordance with one embodiment of the present invention.

[FIG. 3] FIG. 3 schematically illustrates a multi-mode radio frequency (RF) sensor 100 in accordance with another embodiment of the present invention.

Detailed Description of Embodiments of the Present Invention

[0019] FIG. 1 schematically illustrates a movable platform 200 with a multi-mode radio frequency (RF) sensor 100 mounted thereon in accordance with an embodiment of the present invention. The movable platform 200 may be, but not limited to, a robot cleaner, a robot cleaner, a quadcopter, a vehicle in which the multi-mode RF sensor 100 is part of the driver assistance system (ADAS), an air purifying / humidifying robot, and a life control robot. Figure 1 shows that a movable platform 200 with a multi-mode RF sensor 100 mounted on it moves through space 20. Figure 1 also shows two possible radar emission zones 305, 310, respectively, in the second observation region and in the first observation region. Despite the fact that figure 1 simultaneously shows two zones 305, 310 radiation, it should be clear that the RF radar 130 emits radiation with these zones 305, 310 radiation in turn. In other words, first, the RF radar 130 emits radiation with the emission zone 310 when the RF radar rotates throughout the first observation area of the RF radar 130, and then, after switching the mode by the monitoring and processing device 140 to the radiation mode in the second observation region, the RF radar 130 performs radiation with a radiation zone 305 during rotation of the RF radar throughout the second observation area of the RF radar 130. Figure 1 shows that in the first observation area an object is detected - the table leg, the location of which is used to implement the navigation function of the moving platform 200 and / or compilation function navigation maps, and in the second observation area an object is detected - a cat, i.e. potential obstacle to the movement of the movable platform 200, the location of which is used when implementing the function of detecting obstacles and / or the function of controlling the movement of the movable platform 200 to avoid an obstacle. As shown in the figure, these objects are detected by different types of radiation. Thus, the multi-mode RF sensor 100 is capable of realizing multi-mode.

[0020] A multi-mode radio frequency (RF) sensor 100 may be mounted on a movable platform 200 for realizing at least two functions simultaneously by the mobile platform 200. In a preferred embodiment of the present invention, the functions are a navigation function and an obstacle detection function. In other embodiments of the present invention, the implemented functions may include the function of constructing a navigation map of the space 20 in which the movable platform 200 with the multi-mode radio frequency (RF) sensor 100 mounted on it, the function of detecting vehicles and / or pedestrians and / or road obstacles , the function of controlling the heartbeat or respiration of living organisms, such as, for example, people and pets, the function of detecting and / or recognizing the movements of living organisms.

[0021] In the preferred embodiment illustrated in FIG. 1, a multi-mode radio frequency RF sensor 100 comprises a fixed base 110 that is adapted to be mounted on a movable platform 200 capable of moving in space 20. As illustrated in FIG. 1, a fixed base 110 can be mounted in front of the movable platform 200. However, it is not necessary to limit the present invention to such an installation position, since the fixed base 110 can be mounted in other parts of the movable platform 200, for example, in the rear, in the side, in the central part of the upper surface and so on. In addition, the fixed base 110 can be mounted not only on the upper surface of the movable platform 200, but also on the lower surface of the movable platform 200 (i.e., in the gap between the bottom of the movable platform 200 and the surface on which the movable platform 200 moves).

[0022] The space 20 may be any environment in which the movable platform 200 is currently located with a multi-mode radio frequency (RF) sensor 100 mounted thereon, for example, but not limited to, the space of any room, road space, air space, and so on . The specific space will be determined by the type of movable platform 200, i.e. robotic vacuum cleaners and vehicles usually move in spaces of different types.

[0023] The fixed base 110 may have attachment means to any type of movable platform. The fixed base 110 may be rotatably supported by a rotating part 120, which is mounted in any way on the fixed base 110 and is configured to rotate relative to the fixed base 110 in a horizontal plane. It should be understood that in one embodiment, the multi-mode radio frequency RF sensor 100 may not include a fixed base 110. Then, the rotating part 120 may be directly mounted on one of the surfaces of the movable platform 200 with a circular rotation.

[0024] The rotating part 120 and the fixed base 110 may be of any shape that allows rotation of the rotating part 120 to the fixed base 110. Specific methods for such fastening are known in the art. One particular shape of the rotating part may be a cylindrical shape. An RF radar 130 may be mounted on the rotating part 120. The position and installation method of the RF radar 130 on the rotating part 120 is not specifically limited provided that the middle of the cone-shaped emission zone of the RF radar 130 is directed substantially parallel to the motion vector of the movable platform 200, i.e. . The RF radar 130 is mounted on the rotating part perpendicular to the motion vector of the movable platform 200.

[0025] In the specific example of FIG. 1, a movable platform 200 is illustrated, in this example a robot cleaner with a multi-mode RF sensor 100 mounted thereon. The illustrated movable platform 200 moves around the room and performs cleaning. In FIG. 1 also illustrates two possible emission zones 305, 310 in some part of the first observation area of the RF radar 130. The emission zone 305 in the vertical plane (when looking at the movable platform 200 from the side) is wider ( n times wider) than the emission zone 310 in vertical plane. In the horizontal plane (when looking at the movable platform 200 from above or from below), the radiation zone 305 and the radiation zone 310 can, but without being limited to, have the same width. Further, when referring to a “wider / wider” emission zone, radiation with a larger aperture in the vertical plane, but with a smaller range, is meant, and when referring to a “narrower / narrower” radiation zone, radiation with a smaller aperture in the vertical plane, but with longer range. Detailed information on the formation of these emission zones 305, 310, on the components that can form such a formation, as well as details on other characteristics of the radiation used, will be described below with a more detailed discussion of the structure of the RF radar 130 and the process of switching the operating modes of the multi-mode radio frequency RF sensor 100. It should be understood that in a preferred embodiment of the present invention, the RF radar 130 emits radiation in a first observation area using a narrower emission zone 310, and in the second observation region switches to using a wider radiation zone 305. However, the present invention should not be limited to such specific correspondences between the areas of observation and types of radiation zones, since the manufacturer of the multi-mode RF sensor 100 may, as necessary, preconfigure other correspondences between the areas of observation and types of radiation zones. In addition, the manufacturer of the multi-mode RF sensor 100 can additionally, as necessary, increase the number of observation areas, increase the number of types of radiation zones, and also adjust the radiation direction of the RF radar 130 of the multi-mode RF sensor 100 so that the corrected direction covers a predetermined higher vertical plane a region or a predetermined region below a vertical plane.

[0026] FIG. 2 schematically illustrates a multi-mode radio frequency (RF) sensor 100 in accordance with an embodiment of the present invention. The movable platform 200 in this FIG. 2 not shown. The multi-mode RF sensor 100 mainly includes those described above with reference to FIG. 1, the fixed base 110 and the rotating part 120, as well as the RF radar 130, the monitoring and processing device 140, which will be described later.

[0027] In a preferred embodiment of the present invention, the RF radar 130 includes one or more transmit channels 132, each of which includes at least one transmit antenna 132.1 with a first aperture and at least one transmit antenna 132.2 with a second aperture. In addition, the RF radar 130 includes one or more receiving channels 134, each of which includes at least one receiving antenna 134.1 with a first aperture and at least one receiving antenna 134.2 with a second aperture.

[0028] The monitoring and processing device 140 is configured to control the operating modes of the RF radar 130 of the multi-mode RF sensor 100 to alternately switch the operating modes of the RF radar 130 of the multi-mode RF sensor 100, as well as to induce an electric motor (not shown in Fig. 2) or other drive mechanism to rotate the rotating part 120 during operation of the RF radar 130 of the multi-mode RF sensor 100. Rotation can occur clockwise or counterclockwise. In a preferred embodiment of the present invention, the control of the operating modes of the RF radar 130 of the multi-mode RF sensor 100 comprises prompting the RF radar 130 of the multi-mode RF sensor 100 to work, at certain times, through antennas 132.1, 134.1 with a first aperture, and at other certain times through antennas 132.2, 134.2 with a second aperture.

[0029] The monitoring and processing device 140 is further configured to send data received by the RF radar 130 to the processor of the mobile platform to enable control of the mobile platform 200 based on the data with the implementation of the mobile platform 200 simultaneously at least two functions, for example, navigation functions and detecting objects in space 20.

[0030] Said control of the operating modes of the RF radar 130 of the multi-mode RF sensor 100 comprises: (i) switching the operating mode of the RF radar 130 to a first operating mode comprising radiation, in a first observation area of the multi-mode RF sensor 100, of a plurality of RF signals by one or more transmitting antennas 132.1 with a first aperture and receiving a first plurality of reflected RF signals through one or more receiving antennas 134.1 with a first aperture; (ii) switching the operating mode of the RF radar 130 to a second operating mode containing radiation, in the second viewing area of the multi-mode RF sensor 100, a plurality of RF signals through one or more transmit antennas 132.2 with a second aperture, and receiving a second set of reflected RF signals through one or more receiving antennas 134.2 with a second aperture; (iii) obtaining a synthesized aperture covering both the first observation region and the second observation region of the multi-mode RF sensor 100, based on the first set of reflected RF signals to enable the mobile platform 200 to realize the first function, for example, a navigation function; and (iv) detecting objects in a second viewing area of the multi-mode RF sensor 100 based on the second plurality of reflected RF signals to enable the mobile platform 200 to realize a second function, such as an object detection function.

[0031] The following are details of operation (i). The first aperture mentioned is n times larger than the second aperture. Thus, a transmit antenna 132.1 with a first aperture is configured to emit a plurality of RF signals using a relatively narrower emission area 310, and a receive antenna 134.1 with a first aperture is configured to receive a corresponding first plurality of reflected RF signals. Since the antenna with the first aperture provides a narrower emission area 310, i.e. a radiation zone with a smaller aperture angle and a greater range in comparison with the aperture angle and the range of the radiation zone 305, the radiation in the radiation zone 310 is suitable for real-time navigation and / or construction of a navigation map of the space 20. Radiation with emission zone 310 is performed in the first observation region of the multi-mode RF sensor 100, which is preconfigured in that observation region which is not covered by the second observation region facing strictly forward in the direction of movement of the moving platform 200. As an example, if the angle of the second observation region is the horizontal plane is 60 °, the first observation region is pre-configured so that it covers the remaining 300 ° around the movable platform 200. The indicated angles of the first and second observation regions are given only as a specific example, and not limitation.

[0032] In the case of detecting an object in the first observation area based on the first set of reflected RF signals, the monitoring and processing device 140 is further configured to send a signal about the object for processing to the processor of the mobile platform 200 in order to take this object into account when implementing navigation and / or building a map of navigation through space 20 in real time or to analyze the first set of reflected RF signals for other purposes.

[0033] The following are details of operation (ii). The second aperture mentioned is n times smaller than the first aperture. Thus, a transmit antenna 132.2 with a second aperture is configured to emit a plurality of RF signals using a relatively wider radiation area 305, and a receive antenna 134.2 with a second aperture is configured to receive a corresponding second plurality of reflected RF signals. Since the antenna with the second aperture provides a wider radiation area 305, i.e. a radiation zone with a large aperture angle and a shorter range in comparison with the aperture angle and the range of the radiation zone 310, the radiation in the radiation zone 305 is suitable for detecting relatively close objects, potential obstacles in the movement path of the moving platform 200. The radiation with the radiation zone 305 is performed the second observation region of the multi-mode RF sensor 100, facing strictly forward in the direction of travel of the movable platform 200 (in the above example, the angle of the second observation region is 60 °).

[0034] The radiation in the radiation zone 305 in the second observation region can additionally be used to detect the heartbeat or respiration of living organisms when they are encountered in the path of the moving platform 200. In the case of detecting an object in the second observation region using radiation in the radiation zone 305 based on the second set of reflected RF signals, the control and processing device 140 is further configured to send a signal about the object for processing to the processor of the mobile platform 200 in order to adjust the path of the mobile platform 200 or to analyze the second set of reflected RF signals for the presence of a heartbeat, respiration, and etc. Route adjustment can be based on the coordinates of the detected object and, optionally, a navigation map, which is built in real time in the above-described first mode of operation of the RF radar 130 of the multi-mode RF sensor 100.

[0035] The following are details of operation (iii). Since in the second observation area (covering 60 ° in the above example, strictly in front of the moving platform 200, the RF radar 130 operates in the second mode of operation, i.e., using the radiation zone 305, which is used not to implement navigation, but to detect objects directly on the way the movement of the platform, to take into account this second observation area for realizing navigation and / or constructing a navigation map of the space 20 in real time, the control and processing device 140 is configured to produce a synthesized aperture covering both the first observation area and this second observation area The RF radar 130 of the multi-mode RF sensor 100 based on the first plurality of reflected RF signals received in the first observation area to enable the mobile platform 200 to realize a navigation function taking into account the entire 360-degree viewing area around the mobile platform 200. Thus, the first observation area and second the observation area of the RF radar 130 of the multi-mode RF sensor 100 together encompasses a 360-degree observation area around the movable platform 200.

[0036] In a preferred embodiment of the present invention, the monitoring and processing device 140 is configured to produce a synthesized aperture encompassing both the first viewing area and the second viewing area of the RF radar 130 of the multi-mode RF sensor 100 based on the first set of reflected RF signals. Aperture siting is a signal processing technique that can significantly increase the resolution and consists in receiving the reflected signals sequentially in time at different positions of the antenna phase center and then summing the reflected signal data multiplied by the phase shift of the antenna phase center. In a preferred embodiment of the present invention, a synthesized aperture can be obtained by applying Fast Fourier Transform (FFT) to the first set of reflected RF signals. For this, N reflected RF signals of the first set of reflected RF signals or part thereof (it is assumed that N + M measurements were taken at N + M points in total, where N are measurements in the first observation area of the RF radar 130, M are measurements in the second region observations of the RF radar 130) are summarized by the formula:

,

,

– комплекскное представление отраженного сигнала с информацией о фазе и амплитуде, принятого в определенный момент времени, R – расстояние от фазового центра антенн до центра вращения вращающейся части 120 относительно неподвижного основания 110,

– угол образованный фазовым центром антенн в момент приема отраженного сигнала, центром вращения вращающейся части 120 и некоторым фиксированным заранее определенным «нулевым» направлением, например одна из границ перехода между первой и второй областью наблюдения,

– длина волны несущей отраженных сигналов,

– угол образованный направлением наблюдения в первой или второй областях наблюдения и заранее определенным «нулевым» направлением. Для осуществления кругового обзора значение

выбирается из диапазона от 0 до 360 градусов с шагом, который необходим для получения однозначной картины. В предпочтительном варианте осуществления этот шаг равен 1/4 разрешения системы, которое пропорционально

.

позволяет получить информацию об отраженном сигнале в направлении

как в первой, так и во второй области наблюдения (т.е. синтезировать отраженный сигнал для той области наблюдения, в которой непосредственного измерения не проводилось).Where

- a comprehensive representation of the reflected signal with information about the phase and amplitude received at a certain point in time, R is the distance from the phase center of the antennas to the center of rotation of the rotating part 120 relative to the fixed base 110,

- the angle formed by the phase center of the antennas at the time of receiving the reflected signal, the rotation center of the rotating part 120 and some fixed predetermined "zero" direction, for example, one of the transition boundaries between the first and second observation area,

- wavelength of the carrier of the reflected signals,

- the angle formed by the direction of observation in the first or second areas of observation and a predetermined "zero" direction. For a round-robin view, the value

is selected from a range from 0 to 360 degrees in increments that are necessary to obtain a unique picture. In a preferred embodiment, this step is 1/4 of the resolution of the system, which is proportional

.

allows you to get information about the reflected signal in the direction

both in the first and in the second observation region (i.e., to synthesize the reflected signal for that observation region in which direct measurement was not performed).

[0037] The following are details of operation (iv). The monitoring and processing device 140 is further configured to detect objects in a second observation area of the multi-mode RF sensor 100 based on the second plurality of reflected RF signals to enable the mobile platform 200 to realize a second function, for example, an object detection function. Object detection in this case can be performed as follows: When the monitoring and processing device 140 determines that the RF radar 130 of the multi-mode RF sensor 100 is in the second observation area, the monitoring and processing device 140 causes the transmitting antenna 132.2 with a second aperture to emit an RF signal in the area 310 radiation. In this example, one RF signal is used to simplify the description, in the actual implementation, many RF signals are emitted at different positions (provided by the gradual movement of the RF radar 130 on the rotating part 120) within the observation area in order to cover all of the above (first, second or other pre-configured observation area). In the presence of an object, a potential obstacle, in the second observation area, the radiated RF signal is reflected and received by the receiving antenna 134.2 with the second aperture and, accordingly, the receiving channel of the multi-mode RF sensor 100. In the case of M measurements, the monitoring and processing device 140 forms a second set reflected RF signals in the order they are received. Then, this second plurality of reflected RF signals can be digitized so that each digitized signal from said second plurality is a sequence of samples. The signal level in each sample is compared with a certain, predetermined or software-defined threshold value. If as a result of the comparison in the second set of reflected RF signals there is at least one signal the level of which exceeds the threshold value, the monitoring and processing device 140 provides an obstacle signal that can be used to adjust the travel route of the moving platform 200 or to stop. The object detection algorithm can be further applied in a similar way to detect vehicles and / or pedestrians and / or road obstacles when implementing the function of detecting vehicles and / or pedestrians and / or road obstacles when the movable platform 200 is a vehicle.

[0038] The construction of a navigation map can be carried out as follows: The RF radar 130 makes one revolution around the axis of rotation, collecting N + M reflected signals and transmitting them to the monitoring and processing device 140. During the time that the RF radar 130 makes the next revolution, the control and processing device 140 synthesizes the aperture as described in paragraph [036] of this application and generates synthesized digitized signals in each direction in the first and second observation areas with a predetermined step. The synthesized digitized signals are a sequence of samples in each direction of observation. The signal level in each sample is compared with a certain, predetermined or software-defined threshold value. If, as a result of comparison, the set of synthesized digitized signals contains a signal the level of which exceeds the threshold value, the monitoring and processing device 140 gives a signal that there is an obstacle in this direction, while the number in the sampling sequence corresponds to the distance of the location of the obstacle, which can be used to correct the route movement of the movable platform 200 or stop. The device 140 control and processing determines the presence of obstacles and the distance to them in each of the directions of observation and passes them to the processor. The processor (the processor of the mobile platform 200 or any other processor integrated with the multi-mode RF sensor 100) can be configured to map the location of the obstacle relative to the mobile platform 200. Then this operation can be repeated after the next turn of the RF radar 130 around its axis.

[0039] The RF radar 130 may further be configured to detect heartbeat and / or breathing. Since the respiration and heartbeat frequency ranges from 0.2 to 2 Hz, the radar should rotate at a speed of about 10 revolutions per second (in the preferred embodiment, the more often the better) and take at least 5 measurements (in the preferred embodiment - the more, the better) in the second observation area. In this case, in 1 second the RF radar 130 will receive about 50 measurements. Since 50 >> 2, it is possible to make the Fourier transform and select the carrier frequency corresponding to the respiratory rate of a person or his heartbeat.

[0040] The RF radar 130 may further be configured to detect the movements of living organisms by detecting a micro-Doppler frequency shift in the reflected signals by averaging the measurements obtained in accordance with the above description in paragraph [0039].

во избежание возникновения ложных целей. В предпочтительном варианте осуществления настоящего изобретения выбирается частота равная одному замеру на градус поворота вращающейся части 120.[0041] In addition, one skilled in the art will understand that the rotational speed of the rotating part 120 is selected so that the distance that the movable platform 200 moves is comparable to the distance that the movable platform 200 travels from the moment the control signal is issued by moving, for example, a stop command signal to the stop itself. For example, if a robot vacuum cleaner needs 5 cm to stop at a speed of 30 cm / sec, then the rotation speed should be more than 6 revolutions per second, but usually not more than 30 revolutions per second. The frequency of measurements of N RF radar 130 during one period should be more than 6πR /

to avoid false targets. In a preferred embodiment of the present invention, a frequency equal to one measurement per degree of rotation of the rotating part 120 is selected.

[0042] As used herein, the terms “first” and “second” are not intended to indicate a preferred sequence of actions defined by such terms, nor are they intended to indicate any priority between the elements that they define. It is assumed that the terms "first" and "second" are used only to distinguish between the actions or elements they define in order to simplify the description. A similar remark is relevant for the reference signs used in the materials of this application.

[0043] In a preferred embodiment of the present invention, the monitoring and processing device 140 is further configured to determine the position of the rotating part 120 relative to the stationary base 110 and to determine the operating times of the RF radar 130 through antennas 132.1, 134.1 with the first aperture and the operating times of the RF radar 130 through antennas 132.2, 134.2 with a second aperture. In other words, the monitoring and processing device 140 is configured to determine whether the multi-mode RF sensor 100 rotating on the rotating part 120 of the RF radar 130 is in the first observation region or the second observation region.

[0044] In one embodiment of said position determination by means of the monitoring and processing device 140, the multi-mode RF sensor 100 further comprises a photodiode 150 mounted on the rotating part 120 in a predetermined position. The photodiode 150 is mounted so as to face the surface of the stationary base 110 or the surface of the movable platform 200, on which the structure is applied (an example of the applied structure for many different viewing areas is illustrated in figure 3), indicating the first viewing area and the second viewing area of the multi-mode RF sensor 100 The mentioned structure may be a circular region in which, for example, a matte surface of one color corresponds to a first observation region and a glossy surface of another color corresponds to a second observation region. Thus, when the rotating part 120 rotates, the photodiode 150 is configured to detect a feature (glossy or matte, for example) of a structure indicating that the RF radar 130 of the multimode RF sensor 100 is in one of the regions or the transition of the RF radar 130 of the multimode RF sensor 100 from one region to another. Thus, the photodiode 150 is configured to provide a signal based on the detection result, which indicates in which area of observation the RF radar 130 of the multi-mode RF sensor 100 is currently located, and can be used to determine the mentioned timing of switching the operating modes of the RF radar 130 multimode RF sensor 100.

[0045] In another embodiment of said position determination by the monitoring and processing apparatus 140, the multi-mode RF sensor 100 further comprises a stepper motor 160 coupled to the rotating part 120 and calibrated based on a predetermined first viewing area and a second viewing area of the RF radar 130 of the multi-mode RF sensor 100. In this case, the stepping motor 160 is configured to detect the transition of the RF radar 130 of the multi-mode RF sensor 100 from one of the above-mentioned areas to another, or to locate the RF radar 130 of the multi-mode RF sensor 100 in a certain one observation area, and outputting a signal based on the detection result that is used to determine the mentioned points in time or current observation area.

[0046] In a preferred embodiment of the present invention, the multi-mode RF sensor monitoring and processing device 140 integrates with the RF radar 130 as a chip-on-chip (SoC) system, a case-by-case (CRS) system, programmable logic integrated circuit (FPGA), special purpose integrated circuit (ASIC). This feature of the present invention is not illustrated in the figures.

[0047] An RF key may be used to switch the operating mode of the RF radar 130 of the multi-mode RF sensor 100. In an embodiment of the present invention, the RF radar 130 comprises at least one RF key 132.3 of at least one transmit channel 132 and at least one RF key 134.3 of at least one receive channel 134. Said at least one RF key 132.3 of at least one transmitting channel 132 is configured to switch between one or more transmitting antennas 132.1 with a first aperture and one or more transmitting antennas 132.2 with a second aperture based on a specific timing of the switching of the operation of the RF radar 130 or a specific position of the RF radar 130, i.e. whether the RF radar 130 is currently in the first observation region or the second observation region. Said at least one RF key 134.3 of at least one receiving channel 134 is configured to switch between one or more receiving antennas 134.1 with a first aperture and one or more receiving antennas 134.2 with a second aperture based on a specific timing of switching the operating mode of the RF radar 130 or a specific position of the RF radar 130, i.e. whether the RF radar 130 is currently in the first observation region or the second observation region.

[0048] In alternative embodiments of the present invention using synthesized aperture principles, a larger number of detection areas can be defined and, accordingly, switching between a large number of operating modes of the RF radar 130 of the multi-mode RF sensor 100. In addition, it should be understood that based on of the present disclosure, a method for controlling a mobile platform using the disclosed multi-mode RF sensor or the method of operation of a multi-mode RF sensor may also be provided. In such embodiments, the operations performed by the various claimed hardware components may be implemented as the respective steps of said methods. In another embodiment, a computer-readable medium may be provided storing computer-executable instructions for implementing the above steps by computing means, for example, a processor.

[0049] After reading this description, the specialist will understand other embodiments of the present invention, modifications, equivalent features and features. It is assumed that all such other embodiments of the present invention, modifications, equivalent features and features are covered by the following claims.

[0050] the List of reference positions

100 - Multimode Radio Frequency (RF) Sensor

200 - Mobile platform

110 - Fixed base

120 - Rotating part

130 - RF radar

140 - Control and processing device

305 - Wider radiation area

310 - Narrower emission area

132 - Transmit Channel

132.1 - Transmitting antenna with a first aperture

132.2 - Transmitting antenna with a second aperture

132.3 - RF key transmit channel

134 - Receive channel

134.1 - Receiving antenna with a first aperture

134.2 - Receiving antenna with a second aperture

134.3 - RF key receiving channel

160 - Stepper motor

150 - Photodiode

Claims (30)

1. A multi-mode radio frequency (RF) sensor (100) mounted on a movable platform (200) for implementing the mobile platform (200) simultaneously at least two functions in space (20), and the multi-mode RF sensor (100) contains: a fixed base (110), which is mounted on a movable platform (200), capable of moving in space (20); a rotating part (120), which is mounted on a fixed base (110) and configured to rotate relative to the fixed base (110) in a horizontal plane, and on the rotating part (120) installed RF radar (130), which contains: at least one transmitting channel (132) including one or more transmitting antennas (132.1) with a first aperture and one or more transmitting antennas (132.2) with a second aperture; at least one receiving channel (134) including one or more receiving antennas (134.1) with a first aperture and one or more receiving antennas (134.2) with a second aperture; a control and processing device (140) configured to control the operating modes of the multi-mode RF sensor (100), the control comprising causing the multi-mode RF sensor (100) to operate the RF radar (130) at specific times through antennas (132.1, 134.1) with the first aperture, and at other certain points in time through antennas (132.2, 134.2) with the second aperture; wherein the monitoring and processing device (140) is further configured to send data received by the RF radar (130) to the processor of the mobile platform in order to be able to control the mobile platform (200) based on the data with the implementation of the mobile platform (200) at least simultaneously two functions in space (20). 2. The multi-mode RF sensor (100) according to claim 1, wherein said control of the operating modes of the multi-mode RF sensor (100) comprises: switching the operating mode of the RF radar (130) to the first operating mode containing radiation in the first observation area of the multi-mode RF sensor (100), a plurality of RF signals through one or more transmitting antennas (132.1) with a first aperture and receiving the first set of reflected RF signals by one or more receiving antennas (134.1) with a first aperture; switching the operating mode of the RF radar (130) to a second operating mode containing radiation in the second observation area of the multi-mode RF sensor (100), a plurality of RF signals via one or more transmitting antennas (132.2) with a second aperture, and receiving a second set of reflected RF signals by one or more receiving antennas (134.2) with a second aperture; obtaining a synthesized aperture covering both the first observation region and the second observation region of the multi-mode RF sensor (100), based on the first set of reflected RF signals to enable the mobile platform (200) to realize the first function; and object detection in the second observation region of the multi-mode RF sensor (100) based on the second set of reflected RF signals to enable the mobile platform (200) to realize the second function. 3. The multi-mode RF sensor (100) according to claim 1 or 2, wherein the first aperture is larger than the second aperture and the first observation area is larger than the second viewing area. 4. The multimode RF sensor (100) according to claim 1 or 2, wherein the first observation region and the second observation region of the multimode RF sensor (100) together cover a 360-degree observation region around the moving platform (200). 5. The multi-mode RF sensor (100) according to claim 1 or 2, in which the control and processing device (140) is further configured to determine the position of the rotating part (120) relative to the fixed base (110) and determine the operating times of the RF radar (130) ) through antennas (132.1, 134.1) with the first aperture and the operating times of the RF radar (130) through antennas (132.2, 134.2) with the second aperture. 6. The multi-mode RF sensor (100) according to claim 5, further comprising a photodiode (150) mounted on the rotating part (120) in a predetermined position and facing the fixed base (110), on which is applied a structure indicating the first observation area and the second the observation area of the multi-mode RF sensor (100), and the photodiode (150) is configured to: detecting during rotation of the rotating part (120) a structural feature indicative of the transition of the multi-mode RF sensor (100) from one region to another; and issuing a signal based on the detection result, which is used to determine the points in time. 7. A multi-mode RF sensor (100) according to claim 5, further comprising a stepper motor (160) connected to the rotating part (120) and calibrated based on a predetermined first observation region and a second observation region of the multi-mode RF sensor (200), a stepper motor (160) is configured to detect the transition of a multi-mode RF sensor (100) from one of the mentioned area to another; and issuing a signal based on the detection result, which is used to determine the points in time. 8. The multi-mode RF sensor (100) according to claim 1, wherein the monitoring and processing device (140) is integrated with the RF radar (130) as a system on a chip (SoC), a system in a case (SVK), a programmable logic integrated circuit (FPGA ), a special purpose integrated circuit (ASIC). 9. The multi-mode RF sensor (100) according to claim 2, wherein obtaining a synthesized aperture covering both the first observation area and the second observation region of the multi-mode RF sensor (100), based on the first set of reflected RF signals, comprises processing the first set of reflected RF Signals using Fast Fourier Transform (FFT). 10. A multi-mode RF sensor (100) according to claim 6 or 7, wherein the RF radar (130) comprises at least one RF key (132.3) of at least one transmitting channel (132) and at least one RF key (134.3 ) at least one receiving channel (134), while at least one RF key (132.3) of at least one transmit channel (132) is configured to switch between one or more transmit antennas (132.1) with a first aperture and one or more transmit antennas (132.2) with a second aperture based on a specific moment switching time of the RF radar operation mode (130); and at least one RF key (134.3) of at least one receiving channel (134) is configured to switch between one or more receiving antennas (134.1) with a first aperture and one or more receiving antennas (134.2) with a second aperture based on a specific moment the time of switching the operating mode of the RF radar (130). 11. The multi-mode RF sensor (100) according to claim 1, wherein the movable platform (200) is one of a robot vacuum cleaner, multicopter, a vehicle in which the multi-mode RF sensor is part of the driver assistance system (ADAS) that cleans / moisturizes the air robot, life control robot. 12. A multi-mode RF sensor (100) according to claim 1 or 2, in which the operating times of the RF radar (130) through the antennas (132.1, 134.1) with the first aperture correspond to the first observation area, and the operating times of the RF radar (130) are antennas (132.2, 134.2) with a second aperture correspond to the second observation area. 13. A multi-mode RF sensor (100) according to claim 1 or 2, wherein said at least two functions are selected from the group consisting of a navigation function and an obstacle detection function, a function for constructing a navigation map of the space (20) in which the moving platform is located (200) with a multi-mode RF sensor installed on it (100), the functions of detecting vehicles and / or pedestrians and / or road obstacles, the functions of monitoring the heartbeat or respiration of living organisms, the function of detecting and / or recognizing the movements of living organisms.

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