Patent Description:
For navigation of robots, radiation-based guiding systems can be used.

Known guiding systems irradiate their environment with a radiation signal for guiding the robots along an increasing intensity of the radiation signal to the base station. Due to distortions (e.g. interferences) of the radiation signal, the robot may follow a wrong path and, in some cases, therefore, gets discharged or lost, i.e. out of the irradiated environment. Thus, the robots may need to be connected to the base station manually.

Document <CIT> refers to a robot cleaner system comprising an external recharging apparatus, a recharging apparatus recognition mark formed on the external recharging apparatus, and a robot cleaner having a recognition mark sensor that detects the recharging apparatus recognition mark.

Hence, there may be a demand for an improved concept for a guiding system for a robot.

This demand can be satisfied by the subject-matter of the appended independent and dependent claims.

Embodiments of the present disclosure relate to a guiding system for a robot. The guiding system comprises a millimeter-wave positioning system and a transmitter. The millimeter-wave positioning system is configured to determine a position of the robot relative to a base station for charging the robot. The transmitter is configured to emit a radar guiding signal for guiding the robot to the base station and to steer the radar guiding signal towards the position of the robot.

The robot, for example, is a lawnmower robot, a vacuum cleaner robot, a household robot, or another at least partially automatically controlled/steered mobile device (e.g. an at least partially automatically steered vehicle).

The millimeter-wave positioning system, for example, is a radar-based positioning system using a millimeter-wave signal for locating the robot, i.e. the position of the robot relative to the base station. The position can be indicative of coordinates in a predefined reference coordinate system of the base station.

The radar guiding signal can be a millimeter-wave signal having a frequency between <NUM> and <NUM> (i.e. a wavelength between <NUM> and <NUM>). Since the radar guiding signal is steered to the robot's position, it can be understood as a directional signal towards the robot/the robot's position.

This allows the radar guiding signal to be emitted in a smaller field of view than in applications using an "undirected" signal, which is not purposefully directed to the robot, for guiding the robot. Therefore, a probability or number of distortions of the (directional) radar guiding signal can be less than for undirected signals. Further, this may reduce a probability to guide the robot along a wrong path or of the robot to get lost and possibly discharged somewhere away from the base station.

In general, the guiding system can be installed in or separate from the base station of the robot.

It is to be noted that the guiding system generally can be configured to guide multiple robots, for example, using multiple (directional) radar guiding signals directed/steered to the robots.

Some embodiments relate to a base station for a robot. The base station comprises the aforementioned guiding system.

The base station can be understood as a stationary device to which the robot can dock for charging, maintaining, and/or cleaning the robot. The guiding system, for example, is installed adjacent or next to a docking port for guiding the robot to or at least close to the docking port.

Some embodiments relate to a method for guiding a robot. The method comprises determining a position of the robot relative to a base station for charging the robot and emitting a radar guiding signal for guiding the robot to the base station and steering the radar guiding signal towards the position of the robot.

The aforementioned guiding system, for example, is able to execute this method. Therefore, the features and aspects of the guiding system described herein can be mutatis mutandis applied to the method.

<FIG> illustrates a known concept for guiding a robot <NUM> to its base station <NUM>. For example, this enables the robot <NUM> to find and dock to the base station <NUM> automatically, e.g. for charging or maintenance purposes.

The robot <NUM>, for example, is a vacuum cleaner robot which moves automatically within a predefined outdoor or indoor movement area (e.g. in a living space).

To guide the robot <NUM> to the base station <NUM>, the base station <NUM> exhibits an antenna <NUM> emitting a radiation signal within a predefined field of view (FoV) <NUM>. The robot <NUM> can orient itself by the radiation signal and follow an intensity distribution or power distribution of the radiation signal over the FoV <NUM> to find the base station <NUM>.

The robot <NUM>, for example, follows a path <NUM> along an increasing intensity of the intensity distribution or an increasing average power level of the power distribution within the FoV <NUM> to find the base station <NUM>. For this purpose, the robot <NUM> can be equipped with a sensor (not shown) for sensing the intensity of the radiation or average power level of the radiation in time intervals and a navigation unit (not shown) for navigating the robot <NUM> in direction to maximum values of the sensed intensity or average power level.

A directivity of the field of view <NUM> is represented by an opening angle α, e.g. indicating a half-power beamwidth of the radiation signal. The opening angle α can be set such that the field of view covers most of the robot's movement area to guide the robot to the base station <NUM> from most of the positions in the movement area. In typical applications of such known guiding systems, the radiation signal has a half-power beamwidth/opening angle α between <NUM>° and <NUM>°.

Distortions (e.g. interferences) of the radiation signal and its intensity distribution may cause the robot <NUM> to follow a wrong path. Such distortions, for example, are caused by objects within the field of view <NUM>. As can be seen in <FIG>, the robot <NUM> can end up outside of the field of view <NUM> resulting from following a wrong path and may not be able to find its way (back) to the base station <NUM>. Consequently, the robot <NUM> may be discharged completely before reaching the base station <NUM> and may need to be coupled to the base station <NUM> manually.

Hence, there may be a demand for an improved concept for a guiding system. A concept for satisfying this demand is described below with reference to <FIG>.

<FIG> shows a flowchart schematically illustrating a method <NUM> for guiding a robot. Method <NUM> comprises determining <NUM> a position of the robot relative to a base station for charging the robot. Further, method <NUM> comprises emitting <NUM> a radar guiding signal for guiding the robot to the base station and steering the radar guiding signal towards the position of the robot.

In context of the present disclosure, the robot, particularly, is to be understood as an at least partially automatically controlled/steered mobile device. In some applications, the robot is a lawnmower robot, a vacuum cleaner robot, a household robot, or another type of robot. In other applications, an at least partially automatically steered vehicle embodies the robot. The vehicle, for example, is an autonomously steered vehicle (e.g. an autonomously driving car or an autonomously flying aerial vehicle).

The base station can be a stationary (installed) device. The radar guiding signal, for example, enables the robot to find the base station automatically by following a radiation pattern (e.g. intensity pattern) of the radar guiding signal and to dock to the base station, e.g. for charging and maintenance/service purposes.

The radar guiding signal can be (specifically or purposely) directed to the robot based on the sensed position of the robot. This allows to use a smaller field of view irradiated with the radar guiding signal for less distortions of the radar guiding signal than in applications using an arbitrary, undirected signal, which is not purposefully directed to the robot, for guiding the robot. The field of view irradiated with the radar guiding signal, for example, is smaller than in the example of <FIG>. In particular, this can reduce a probability of the robot to follow a wrong path and/or "get lost" while trying to find the base station.

The smaller field of view may also lead to a shorter route which the robot travels on its way to the base station and, thus, to a lower energy consumption.

More details and aspects are mentioned in connection with the embodiments described below with reference to further figures.

Method <NUM>, for example, can be executed by guiding system <NUM> illustrated in <FIG>.

The guiding system <NUM> comprises a millimeter-wave positioning system <NUM> for determining <NUM> a position of a robot <NUM> relative to a base station (not shown) for charging the robot <NUM> and a transmitter <NUM> for emitting a radar guiding signal <NUM> for guiding the robot <NUM> to the base station and steering the radar guiding signal <NUM> towards the position of the robot <NUM>.

In some applications, the robot <NUM> is a vacuum cleaner robot, a lawnmower robot, or a household robot. The guiding system <NUM>, for example, is installed in the base station.

The millimeter-wave positioning system <NUM>, for example, is a radar positioning system using reflections or a so-called "echo" of a radar positioning signal from the robot <NUM> for determining <NUM> the position of the robot <NUM>.

The transmitter <NUM>, for example, uses beam steering to control the radar guiding signal <NUM> and direct/steer the radar guiding signal <NUM> (purposefully) based on the sensed position towards the robot. As stated in more detail later, the transmitter <NUM> can comprise multiple transmit elements for beam steering.

The robot <NUM> can be equipped with a sensor (not shown) for sensing the intensity of the radar guiding signal and a navigation unit (not shown) for navigating the robot <NUM> based on the sensed intensity.

The millimeter-wave positioning system <NUM> and the transmitter <NUM> can be separate devices, e.g. using separate antennas for emitting the radar positioning and the radar guiding signal <NUM>.

Alternatively, the millimeter-wave positioning system <NUM> and the transmitter <NUM> can mutually use (i.e. share) the transmit elements for emitting the radar positioning and radar guiding signal <NUM>, as stated in more detail later with reference to <FIG>.

The millimeter-wave positioning system <NUM> and the transmitter <NUM> also can use a common data processing circuitry or separate respective data processing circuitries to control the separate or mutually used transmit elements emitting the radar positioning and radar guiding signal <NUM>, respectively.

<FIG> illustrates an exemplary application of the guiding system <NUM> in a base station <NUM> of the robot <NUM>. The base station <NUM> can be stationary placed next to and facing a movement area of the robot <NUM>. The movement area, for example, comprises a living space or a garden of a user if the robot is a vacuum cleaner or lawnmower robot, respectively.

The guiding system <NUM> comprises a plurality of radar transmit elements with different sub-fields of view <NUM>, <NUM>,. , n covering an overall field of view <NUM>. The radar transmit elements, for example, comprise differently oriented radar antennas. The transmit elements, e.g., comprise one or more horn antennas and/or patch antennas.

As outlined below, both the millimeter-wave positioning system <NUM> and the transmitter <NUM> can use the radar transmit elements. The millimeter-wave positioning system <NUM> can use the radar transmit elements for emitting a radar positioning signal <NUM> and determining <NUM> the position of the robot <NUM>. The transmitter <NUM> can use the radar transmit elements for emitting <NUM> the radar guiding signal <NUM> for guiding the robot <NUM>.

To capture the robot <NUM> in most of the robot's movement area with the radar positioning signal <NUM>, the overall field of view <NUM>, for example, has an opening angle α or half-power beamwidth of <NUM>°. In alternative embodiments, a different, e.g. a larger or smaller overall field of view may be used. As can be seen in <FIG>, the overall field of view <NUM> (theoretically) can be evenly divided into the sub-fields of view <NUM>, <NUM>,. Accordingly, the sub-fields of view <NUM>, <NUM>,. , n have an opening angle or half-power beamwidth of <MAT>. In practice, the radar transmit elements may not have adjacent but overlapping sub-fields of view <NUM>, <NUM>,. , n having an opening angle or a half-power beamwidth of
<MAT>
and β < α.

In a first step, the radar transmit elements are used to emit the radar positioning signal <NUM> in the overall field of view <NUM> to determine the robot's position using reflections of the radar positioning signal <NUM>. The millimeter-wave positioning system <NUM>, for example, further comprises one, two, or more receive antennas (not shown) to receive the reflections and a data processing unit (not shown) to determine the position using the reflections.

The skilled person having benefit from the present disclosure will appreciate that the reflections or a sequence of reflections are indicative of a velocity, a material, a shape and/or a position of objects within the field of view <NUM>. To identify the robot <NUM> among multiple detected objects, the data processing circuitry can compare velocities of the sensed objects with a predefined velocity of the robot <NUM>. Reflections related to the robot <NUM> can be used to determine the robot's position.

Alternatively, the data processing circuitry can identify and locate the robot <NUM> from the reflections by its shape or material (radar signature).

As can be seen from <FIG>, the millimeter-wave positioning system <NUM>, for example, detects the robot <NUM> in sub-field of view <NUM>.

In a next step, the respective radar transmit element with sub-field of view <NUM> is selected and used to emit and steer the radar guiding signal <NUM> to the robot <NUM>.

In other scenarios where the robot <NUM> is detected in sub-field of view <NUM> or n, the respective radar transmit element with sub-field of view <NUM> or n is used to emit the radar guiding signal <NUM>.

The radar guiding signal <NUM> can be a continuous, a modulated (e.g. a frequency-modulated continuous wave (FMCW)), or pulsed signal which is transmitted until the robot arrives at, e.g. docks to, the base station <NUM>.

It is noted that, alternatively, multiple transmit antennas (e.g. having adjacent fields of view) can be used to emit the radar guiding signal <NUM>.

The skilled person having benefit from the present disclosure will appreciate that the transmit elements (e.g. multiple patch antennas) can optionally be operated in a phased array (or electronically scanned array) configuration for the to determine the position of the robot.

The robot <NUM> optionally (indicated by dashed lines) is equipped with a reflector <NUM> for the radar positioning signal <NUM>. This may lead to stronger reflections of the radar positioning signal from the robot <NUM> and a more precise and/or reliable location of the robot <NUM>. It is noted that the robot can be also equipped with multiple reflectors which, e.g., are mounted around the robot to reflect the radar positioning signal at various orientations of the robot.

The base station <NUM> is powered by a power supply <NUM>.

<FIG> illustrates another exemplary application of the guiding system <NUM> suitable for phase-modulation-based communication with the robot.

The guiding system <NUM> includes a communication system (not shown) for phase-modulation-based communication, i.e. communication using phase-modulated signals, with the robot.

The communication system, for example, comprises a communication antenna and a modulator for controlling the communication antenna to emit a phase-modulated (communication) signal. To save costs for a separate communication antenna, one or multiple of the radar transmit elements can be used as communication antennas.

Preferably, the radar guiding signal <NUM> includes the phase-modulated signal to communicate while guiding the robot <NUM>. For example, the radar guiding signal <NUM> is phase-modulated.

In turn, the robot <NUM> comprises a receiver for receiving and processing the phase-modulated signal.

In this way, the communication system can communicate with the robot. In some applications, the communication system can communicate the robot's position or navigation messages which include instructions for movement of the robot <NUM>, through the phase-modulated signal. The communication can reduce a probability of the robot <NUM> to get lost.

The communication, for example, is based on (binary) phase-shift keying. The modulator can use (binary) phase-shift keying to generate the phase-modulated signal indicative of the robot's position, navigation messages, and/or other information. Optionally, one or more of predefined frequency bands can be used for the communication. In some embodiments, one or more frequency bands reserved for industrial, scientific, and medical (ISM), so-called ISM (radio) bands, are used for the communication, e.g. to avoid predefined (legal) restrictions related to signals, e.g. related to a modulation scheme of such signals, for the communication outside the ISM bands.

In some applications, the robot <NUM> and the communication system each comprise a transceiver for a two-way communication over a peer-to-peer connection using phase-modulated signals.

<FIG> illustrates another exemplary application of the guiding system <NUM> comprising a radio-based communication system. The radio-based communication system comprises an interface <NUM> for wireless communication, e.g., via a wireless local area network (WLAN), WiGig (e.g. WiGig at <NUM>), Bluetooth (BT), long range (LoRa) technology, mobile radio, or the like. The interface, e.g., comprises a WLAN interface, a BT interface, and/or a RadCom system (e.g. including a orthogonal frequency division multiplexing (OFDM) radar for detection and communication). In some applications, the robot <NUM> is equipped with a WLAN, BT, WiGig, and/or a mobile radio communication module <NUM> to communicate with the radio-based communication system via WLAN, BT, WiGig, and/or mobile radio, respectively. In some applications, the robot <NUM> is (already) equipped with such a communication module <NUM>, e.g. for communication with a user.

Claim 1:
A guiding system (<NUM>) for a robot (<NUM>), the guiding system (<NUM>) comprising:
a millimeter-wave positioning system (<NUM>) configured to
emit a radar positioning signal (<NUM>);
receive a reflection of the radar positioning signal (<NUM>) from the robot (<NUM>); and
determine, using the reflection, a position of the robot (<NUM>) relative to a base station (<NUM>) for charging the robot (<NUM>); and
a transmitter (<NUM>) configured to emit a radar guiding signal (<NUM>) for guiding the robot (<NUM>) to the base station (<NUM>) by following a radiation pattern of the radar guiding signal (<NUM>) and to steer the radar guiding signal (<NUM>) towards the position of the robot (<NUM>) based on the determined position.