阅读说明：本技术 电子设备、电子设备的控制方法以及电子设备的控制程序 (Electronic device, control method for electronic device, and control program for electronic device ) 是由 锦户正光 佐原彻 村上洋平 川路聪 本间拓也 佐东将行 于 2020-03-03 设计创作，主要内容包括：电子设备包括发送发送波的发送天线、接收发送波被反射的反射波的接收天线、以及控制部。控制部基于作为发送波发送的发送信号和作为反射波接收的接收信号,来检测反射发送波的物体。控制部将发送波的多个帧中的第二帧中的发送信号以与多个帧中的第一帧中的发送信号不同的方式构成。(The electronic device includes a transmission antenna that transmits a transmission wave, a reception antenna that receives a reflected wave in which the transmission wave is reflected, and a control unit. The control unit detects an object reflecting the transmission wave based on the transmission signal transmitted as the transmission wave and the reception signal received as the reflected wave. The control unit configures a transmission signal in a second frame of the plurality of frames of the transmission wave to be different from a transmission signal in a first frame of the plurality of frames.)

1. An electronic device, comprising:

a transmission antenna for transmitting a transmission wave;

a receiving antenna for receiving a reflected wave from which the transmission wave is reflected; and

a control unit that detects an object reflecting the transmission wave based on a transmission signal transmitted as the transmission wave and a reception signal received as the reflected wave,

the control unit is configured to configure a transmission signal in a second frame of a plurality of frames of the transmission wave to be different from a transmission signal in a first frame of the plurality of frames.

2. The electronic device of claim 1,

the control section configures the chirp signal in the second frame in a manner different from the chirp signal in the first frame.

3. The electronic device of claim 1 or 2,

the control unit makes timing of a transmission signal configured in the second frame different from timing of a transmission signal configured in the first frame.

4. The electronic device of any of claims 1-3,

the control unit causes the order of the transmission signals configured in the second frame to be different from the order of the transmission signals configured in the first frame.

5. The electronic device of any of claims 1-4,

the control unit makes a combination of the transmission signals configured in the second frame different from a combination of the transmission signals configured in the first frame.

6. The electronic device of any of claims 1-5,

the control unit performs calibration using a transmission signal included in at least one of a plurality of frames of the transmission wave.

7. A control method of an electronic device, comprising the steps of:

transmitting a transmission wave from a transmission antenna;

receiving a reflected wave in which the transmission wave is reflected from a reception antenna;

detecting an object reflecting the transmission wave based on a transmission signal transmitted as the transmission wave and a reception signal received as the reflected wave; and the number of the first and second groups,

the transmission signal in a second frame of the plurality of frames of the transmission wave is configured to be different from the transmission signal in a first frame of the plurality of frames.

8. A program, wherein a computer is caused to execute the steps of:

transmitting a transmission wave from a transmission antenna;

receiving a reflected wave in which the transmission wave is reflected from a reception antenna;

detecting an object reflecting the transmission wave based on a transmission signal transmitted as the transmission wave and a reception signal received as the reflected wave; and the number of the first and second groups,

the transmission signal in a second frame of the plurality of frames of the transmission wave is configured to be different from the transmission signal in a first frame of the plurality of frames.

Technical Field

The present disclosure relates to an electronic apparatus, a control method of the electronic apparatus, and a control program of the electronic apparatus.

Background

For example, in the field of industries related to automobiles, techniques for measuring a distance between a host vehicle and a predetermined object are attracting attention. In particular, various studies of RADAR (Radio detection and Ranging) technology that measures a distance to an object or the like by transmitting electric waves such as millimeter waves and receiving reflected waves reflected at the object such as an obstacle have been carried out in recent years. With the development of techniques for assisting the driver in driving and techniques associated with automatic driving in which a part or all of driving is automated, the importance of such techniques for measuring distances and the like is expected to increase in the future.

In addition, various proposals have been made for techniques for detecting the presence of a predetermined object by receiving a reflected wave of a transmitted radio wave reflected by the object. For example, patent document 1 discloses an FM-CW radar device that irradiates a transmission signal, which is linearly FM-modulated at a specific cycle, to a target object, detects a beat signal from a difference with a reception signal from the target object, and performs distance/velocity measurement based on frequency analysis of the signal. For example, patent document 2 discloses a technique that enables a transmitter using a high-frequency signal of about several tens GHz as a transmission wave to control the phase of the transmission wave to an arbitrary value with high accuracy.

Documents of the prior art

Patent document

Patent document 1: japanese laid-open patent publication No. 11-133144

Patent document 2: international publication No. WO2016/167253

Disclosure of Invention

An electronic device according to one embodiment includes a transmission antenna that transmits a transmission wave, a reception antenna that receives a reflected wave reflected by the transmission wave, and a control unit.

The control unit detects an object reflecting the transmission wave based on a transmission signal transmitted as the transmission wave and a reception signal received as the reflected wave.

The control unit sets any one of a plurality of ranges for detecting the object by the transmission signal and the reception signal for each frame of the transmission wave.

An electronic device according to one embodiment includes a transmission antenna that transmits a transmission wave, a reception antenna that receives a reflected wave reflected by the transmission wave, and a control unit.

The control unit detects an object reflecting the transmission wave based on a transmission signal transmitted as the transmission wave and a reception signal received as the reflected wave.

The control section sets any one of a plurality of ranges in which the object is detected by the transmission signal and the reception signal based on at least any one of a frame, a portion constituting the frame, and a chirp signal.

The control method of the electronic device of an embodiment includes the following steps.

(1) The transmission wave is transmitted from the transmission antenna.

(2) A reflected wave in which the transmission wave is reflected is received from a reception antenna.

(3) An object that reflects the transmission wave is detected based on a transmission signal transmitted as the transmission wave and a reception signal received as the reflected wave.

(4) Any one of a plurality of ranges in which the object is detected by the transmission signal and the reception signal is set for each frame of the transmission wave.

A control program of an electronic device according to an embodiment causes a computer to execute the steps (1) to (4).

Drawings

Fig. 1 is a diagram illustrating a usage mode of the electronic apparatus according to the first embodiment.

Fig. 2 is a functional block diagram schematically showing the configuration of the electronic apparatus according to the first embodiment.

Fig. 3 is a diagram illustrating a configuration of a transmission signal according to the first embodiment.

Fig. 4 is a diagram illustrating an operation of the electronic apparatus of the first embodiment.

Fig. 5 is a diagram showing an example of the configuration of the transmitting antenna and the receiving antenna in the electronic device of the first embodiment.

Fig. 6 is a diagram showing another example of the configuration of the transmitting antenna and the receiving antenna in the electronic device of the first embodiment.

Fig. 7 is a diagram illustrating an object detection distance of the electronic device according to the embodiment.

Fig. 8 is a diagram illustrating an example in which the object detection range is set for each frame in the first embodiment.

Fig. 9 is a diagram illustrating an example in which the object detection range is set for each part constituting a frame in the first embodiment.

Fig. 10 is a diagram illustrating an example in which an object detection range is set for each chirp signal constituting a frame in the first embodiment.

Fig. 11 is a flowchart illustrating the operation of the electronic apparatus of the first embodiment.

Fig. 12 is a diagram illustrating an example of setting an object detection range in a frame in the first embodiment.

Fig. 13 is a functional block diagram schematically showing the configuration of the electronic apparatus according to the second embodiment.

Fig. 14 is a diagram illustrating a configuration of a frame in the second embodiment.

Fig. 15 is a diagram illustrating a configuration of a frame in the third embodiment.

Fig. 16 is a diagram illustrating a configuration of a frame in the third embodiment.

Fig. 17 is a diagram illustrating a configuration of a frame in the third embodiment.

Fig. 18 is a diagram illustrating a configuration of a frame in the third embodiment.

Detailed Description

In a technique of detecting a predetermined object by receiving a reflected wave of a transmitted transmission wave reflected by the object, it is desired to improve convenience. An object of the present disclosure is to provide an electronic device, a control method of the electronic device, and a control program of the electronic device, which can improve convenience of object detection. According to one embodiment, an electronic device, a method for controlling an electronic device, and a program for controlling an electronic device, which can improve the convenience of object detection, can be provided. Hereinafter, some embodiments will be described in detail with reference to the accompanying drawings.

(first embodiment)

The electronic apparatus according to the first embodiment can be mounted on a vehicle (mobile body) such as an automobile, for example, to detect a predetermined object existing around the mobile body. Therefore, the electronic apparatus according to the first embodiment can transmit the transmission wave to the periphery of the mobile object from the transmission antenna provided in the mobile object. The electronic apparatus according to the first embodiment can receive a reflected wave in which the transmission wave is reflected from a receiving antenna provided in the mobile object. At least one of the transmission antenna and the reception antenna may be provided in, for example, a radar sensor or the like provided to the moving body.

Hereinafter, a description will be given of a configuration in which the electronic device according to the first embodiment is mounted on an automobile such as a car, as a typical example. However, the electronic device according to the first embodiment is not limited to being mounted on an automobile. The electronic device according to the first embodiment can be mounted on various types of mobile bodies such as a farm machine such as a bus, a truck, a motorcycle, a bicycle, a ship, an airplane, and a tractor, and an unmanned aerial vehicle. The electronic apparatus according to the first embodiment is not necessarily limited to being mounted on a mobile body that moves by its own power. For example, the electronic apparatus according to the first embodiment may be mounted on a mobile body such as a trailer pulled by a tractor. The electronic apparatus of the first embodiment is capable of measuring a distance or the like between the sensor and the predetermined object in a situation where at least one of the sensor and the object is movable. In addition, the electronic apparatus according to the first embodiment can also measure the distance between the sensor and the object, and the like, when both the sensor and the object are stationary.

First, an example of detecting an object by the electronic apparatus of the first embodiment is explained.

Fig. 1 is a diagram illustrating a usage mode of the electronic apparatus according to the first embodiment. Fig. 1 shows an example in which a sensor having a transmitting antenna and a receiving antenna according to a first embodiment is provided in a mobile body.

The mobile body 100 shown in fig. 1 is provided with the sensor 5 having the transmitting antenna and the receiving antenna of the first embodiment. The mobile object 100 shown in fig. 1 is equipped with (e.g., incorporates) the electronic apparatus 1 according to the first embodiment. The specific configuration of the electronic apparatus 1 will be described later. The sensor 5 may comprise, for example, at least one of a transmitting antenna and a receiving antenna. The sensor 5 may suitably include at least one of other functional units such as at least a part of the control unit 10 (fig. 2) included in the electronic device 1. The mobile body 100 shown in fig. 1 may be an automobile vehicle such as a car, but may be any type of mobile body. In fig. 1, the mobile body 100 may move (travel or creep) in the positive Y-axis direction (travel direction) shown in the figure, may move in another direction, or may be stationary without moving.

As shown in fig. 1, the mobile body 100 is provided with a sensor 5 having a transmitting antenna. In the example shown in fig. 1, only one sensor 5 having a transmitting antenna and a receiving antenna is disposed in front of the mobile body 100. Here, the position at which the sensor 5 is provided on the moving body 100 is not limited to the position shown in fig. 1, and may be other positions as appropriate. For example, the sensor 5 as shown in fig. 1 may be provided on the left side, right side, rear side, and/or the like of the moving body 100. In addition, the number of such sensors 5 may be any number of one or more according to various conditions (or requirements) such as a measurement range and/or accuracy in the mobile body 100. Further, the sensor 5 may be provided inside the mobile body 100. The interior may be, for example, a space within a bumper, a space within a headlamp, a space within a driving space, and the like.

The sensor 5 transmits an electromagnetic wave from the transmission antenna as a transmission wave. For example, when a predetermined object (for example, the object 200 shown in fig. 1) exists around the moving body 100, at least a part of the transmission wave transmitted from the sensor 5 is reflected by the object to become a reflected wave. By receiving such a reflected wave by a receiving antenna of the sensor 5, for example, the electronic apparatus 1 mounted on the mobile body 100 can detect the object.

The sensor 5 with the transmitting antenna may typically be a RADAR (Radio detection and Ranging) sensor that transmits and receives Radio waves. However, the sensor 5 is not limited to a radar sensor. The sensor 5 of the first embodiment may be, for example, a sensor based on LIDAR (Light Detection and Ranging: Light Detection and Ranging, Laser Imaging Detection and Ranging: Laser Imaging Detection and Ranging) technology using Light waves. Sensors such as these can be configured to include, for example, patch antennas and the like. Since technologies such as RADAR and LIDAR are known, detailed description thereof may be appropriately simplified or omitted.

The electronic apparatus 1 mounted on the mobile body 100 shown in fig. 1 receives, from the receiving antenna, a reflected wave of the transmission wave transmitted from the transmitting antenna of the sensor 5. In this way, the electronic apparatus 1 can detect the predetermined object 200 existing within the predetermined distance from the moving body 100. For example, as shown in fig. 1, the electronic apparatus 1 is capable of measuring a distance L between a moving body 100 as a host vehicle and a predetermined object 200. In addition, the electronic apparatus 1 is also capable of measuring the relative speed between the moving body 100 as the own vehicle and the predetermined object 200. Further, the electronic apparatus 1 may also measure the direction (arrival angle θ) in which the reflected wave from the predetermined object 200 reaches the moving body 100 as the own vehicle

Here, the object 200 may be at least one of an oncoming vehicle traveling on a lane adjacent to the mobile body 100, an automobile running in parallel with the mobile body 100, a front-rear automobile traveling on the same lane as the mobile body 100, and the like, for example. In addition, the object 200 may be any object existing around the moving body 100, such as a motorcycle, a bicycle, a baby carriage, a pedestrian, a guardrail, a center barrier, a road sign, a sidewalk step, a wall, an obstacle, and the like. Also, the object 200 may be moving or may be stopped. For example, the object 200 may be a car or the like that is parked or stopped around the mobile body 100.

In fig. 1, the ratio between the size of the sensor 5 and the size of the mobile body 100 does not necessarily represent an actual ratio. Fig. 1 shows a state in which the sensor 5 is provided outside the mobile body 100. However, in the first embodiment, the sensor 5 may be provided at various positions of the mobile body 100. For example, in the first embodiment, the sensor 5 may be disposed inside a bumper of the mobile body 100 so as not to appear in the external appearance of the mobile body 100.

Hereinafter, as a typical example, a case where the transmission antenna of the sensor 5 transmits an electric wave of a frequency band such as a millimeter wave (30GHz or more) or a quasi millimeter wave (for example, around 20GHz to 30 GHz) will be described. For example, the transmission antenna of the sensor 5 may transmit an electric wave having a bandwidth of 4GHz such as 77GHz to 81 GHz.

Fig. 2 is a functional block diagram schematically showing an example of the configuration of the electronic apparatus 1 of the first embodiment. An example of the configuration of the electronic device 1 according to the first embodiment will be described below.

When measuring a distance or the like by a millimeter Wave radar, a Frequency Modulated Continuous Wave radar (hereinafter referred to as FMCW radar) is often used. The FMCW radar scans the frequency of the transmitted radio wave to generate a transmission signal. Therefore, in the FMCW radar of the millimeter wave system using radio waves of, for example, 79GHz band, the frequency of the radio waves used has, for example, a 4GHz bandwidth of 77GHz to 81 GHz. The 79GHz band radar has a feature of a wider usable bandwidth than other millimeter wave/quasi millimeter wave radars, for example, 24GHz, 60GHz, 76GHz bands, and the like. Hereinafter, such an embodiment will be described.

As shown in fig. 2, the Electronic device 1 of the first embodiment is composed of a sensor 5 and an ECU (Electronic Control Unit) 50. The ECU50 controls various operations of the mobile body 100. The ECU50 may be constituted by at least one or more ECUs. The electronic apparatus 1 of the first embodiment includes a control unit 10. In addition, the electronic apparatus 1 of the first embodiment may suitably include other functional sections such as at least any one of the transmission section 20, the reception sections 30A to 30D, and the storage section 40. As shown in fig. 2, the electronic apparatus 1 may include a plurality of receiving sections such as the receiving sections 30A to 30D. Hereinafter, the receiver 30A, the receiver 30B, the receiver 30C, and the receiver 30D will be simply referred to as "receiver 30" without distinguishing them.

The control section 10 may include a distance FFT processing section 11, a velocity FFT processing section 12, an arrival angle estimating section 13, an object detecting section 14, a detection range determining section 15, and a parameter setting section 16. These functional units included in the control unit 10 will be described later.

As shown in fig. 2, the transmission section 20 may include a signal generation section 21, a synthesizer 22, phase control sections 23A and 23B, amplifiers 24A and 24B, and transmission antennas 25A and 25B. Hereinafter, the phase control unit 23A and the phase control unit 23B are simply referred to as "phase control unit 23" when they are not distinguished from each other. Hereinafter, the amplifier 24A and the amplifier 24B will be simply referred to as "amplifier 24" without distinguishing them. Hereinafter, the transmission antenna 25A and the transmission antenna 25B are simply referred to as "transmission antenna 25" without distinguishing them.

As shown in fig. 2, the receiving section 30 may include corresponding receiving antennas 31A to 31D, respectively. Hereinafter, the receiving antenna 31A, the receiving antenna 31B, the receiving antenna 31C, and the receiving antenna 31D will be simply referred to as "receiving antenna 31" without distinguishing them. In addition, as shown in fig. 2, the plurality of receiving sections 30 may include LNAs 32, mixers 33, IF sections 34, and AD conversion sections 35, respectively. The receiving units 30A to 30D may have the same configuration. Fig. 2 schematically shows only the configuration of the receiving unit 30A as a typical example.

The sensor 5 may comprise, for example, a transmitting antenna 25 and a receiving antenna 31. The sensor 5 may include at least one of other functional units such as the control unit 10.

The control unit 10 included in the electronic apparatus 1 according to the first embodiment can control each of the functional units constituting the electronic apparatus 1, thereby performing the operation of the entire electronic apparatus 1. The control section 10 may include at least one processor such as a CPU (Central Processing Unit) to provide control and Processing capabilities for performing various functions. The control section 10 may be implemented by one processor as a whole, by several processors, or by separate processors, respectively. The processor may be implemented as a single integrated circuit. Integrated circuits are also known as ics (integrated circuits). The processor may be implemented as a plurality of communicatively coupled integrated circuits and discrete circuits. The processor may be implemented based on various other known technologies. In the first embodiment, the control section 10 may be configured as, for example, a CPU and a program executed by the CPU. The control section 10 may suitably include a memory required for the operation of the control section 10.

The storage unit 40 may store a program executed in the control unit 10, a result of processing executed in the control unit 10, and the like. The storage unit 40 may function as a work memory of the control unit 10. The storage unit 40 may be formed of, for example, a semiconductor memory, a magnetic disk, or the like, but is not limited thereto and may be any storage device. In addition, the storage section 40 may be a storage medium such as a memory card inserted into the electronic device 1 of the present embodiment, for example. In addition, as described above, the storage section 40 may be an internal memory serving as a CPU of the control section 10.

In the first embodiment, the storage unit 40 may store various parameters for setting a range in which an object is detected by the transmission wave T transmitted from the transmission antenna 25 and the reflected wave R received from the reception antenna 31. Such parameters will be further described later.

In the electronic device 1 of the first embodiment, the control unit 10 can control at least one of the transmission unit 20 and the reception unit 30. In this case, the control section 10 may control at least one of the transmission section 20 and the reception section 30 based on various information stored in the storage section 40. In the electronic device 1 according to the first embodiment, the control unit 10 may instruct the signal generation unit 21 to generate a signal or may control the signal generation unit 21 to generate a signal.

Under the control of the control unit 10, the signal generation unit 21 generates a signal (transmission signal) to be transmitted as a transmission wave T from the transmission antenna 25. When generating the transmission signal, the signal generation unit 21 may allocate the frequency of the transmission signal based on the control of the control unit 10, for example. Specifically, the signal generator 21 may allocate the frequency of the transmission signal according to the parameter set by the parameter setting unit 16. For example, the signal generator 21 receives the frequency information from the controller 10 (parameter setting unit 16) and generates a signal having a predetermined frequency, for example, a 77 to 81GHz band. The signal generation section 21 may be configured to include a functional section such as a Voltage Controlled Oscillator (VCO).

The signal generating unit 21 may be configured as hardware having the function, may be configured by a microcomputer or the like, or may be configured as a processor such as a CPU, a program executed by the processor, or the like. Each functional unit described below may be configured as hardware having the function, and may be configured by, for example, a microcomputer or the like, or may be configured as a processor such as a CPU, a program executed by the processor, or the like, where possible.

In the electronic device 1 of the first embodiment, the signal generation section 21 may generate a transmission signal (transmission chirp signal) such as a chirp signal. In particular, the signal generation section 21 may generate a signal (linear chirp signal) whose frequency linearly changes periodically. For example, the signal generating section 21 may generate a chirp signal whose frequency periodically increases linearly from 77GHz to 81GHz over time. In addition, for example, the signal generating section 21 may generate a signal in which the frequency periodically repeats linear increase (up-chirp) and decrease (down-chirp) from 77GHz to 81GHz with the passage of time. The signal generated by the signal generating unit 21 may be preset in the control unit 10, for example. The signal generated by the signal generating unit 21 may be stored in the storage unit 40 or the like in advance, for example. Since chirp signals used in the technical field such as radar are known, a more detailed explanation is appropriately simplified or omitted. The signal generated by the signal generation unit 21 is supplied to the synthesizer 22.

Fig. 3 is a diagram illustrating an example of the chirp signal generated by the signal generation section 21.

In fig. 3, the horizontal axis represents elapsed time, and the vertical axis represents frequency. In the example shown in fig. 3, the signal generation section 21 generates a linear chirp signal whose frequency varies linearly periodically. In fig. 3, the respective chirp signals are represented as c1, c2, …, c8, for example. As shown in fig. 3, in each chirp signal, the frequency increases linearly with the passage of time.

In the example shown in fig. 3, eight chirp signals such as c1, c2, …, c8 are contained in one subframe. That is, the sub-frames 1 and 2, etc. shown in fig. 3 are configured to include eight chirp signals such as c1, c2, …, c8, respectively. In addition, in the example shown in fig. 3, sixteen subframes such as subframe 1 to subframe 16 are included in one frame. That is, frame 1 and frame 2, etc. shown in fig. 3 are configured to include sixteen subframes, respectively. In addition, as shown in fig. 3, a frame interval of a predetermined length may be included between frames. One frame shown in fig. 3 may have a length of, for example, about 30 milliseconds to 50 milliseconds. A frame refers to a group of at least more than one chirp signal. At least more than one chirp signal may be included in a frame. The chirp signals in a frame may include chirp signals of the same amplitude and/or the same frequency, or may include chirp signals of different amplitudes and/or different frequencies.

In fig. 3, the same configuration may be applied after frame 2. In fig. 3, the same configuration may be applied after frame 3. In the electronic device 1 of the first embodiment, the signal generating section 21 may generate the transmission signal as an arbitrary number of frames. In addition, in fig. 3, a part of the chirp signal is omitted. As described above, the relationship between the time and the frequency of the transmission signal generated by the signal generation unit 21 can be stored in the storage unit 40 or the like, for example.

As described above, the electronic apparatus 1 of the first embodiment can transmit the transmission signal composed of the sub-frame including the plurality of chirp signals. In addition, the electronic device 1 of the first embodiment may transmit a transmission signal composed of a frame including a predetermined number of subframes.

The following describes the transmission of a transmission signal having a frame structure as shown in fig. 3 by the electronic device 1. However, the frame structure as shown in fig. 3 is an example, and for example, the chirp signals contained in one sub-frame are not limited to eight. In the first embodiment, the signal generating section 21 may generate a sub-frame including an arbitrary number (for example, an arbitrary plurality) of chirp signals. In addition, the subframe structure as shown in fig. 3 is also an example, and for example, subframes included in one frame are not limited to sixteen. In the first embodiment, the signal generating section 21 may generate a frame including an arbitrary number (for example, an arbitrary plurality) of subframes.

Returning to fig. 2, the synthesizer 22 raises the frequency of the signal generated by the signal generating section 21 to the frequency of a predetermined frequency band. The synthesizer 22 may raise the frequency of the signal generated by the signal generating section 21 to a frequency selected as the frequency of the transmission wave T transmitted from the transmission antenna 25. The frequency selected as the frequency of the transmission wave T transmitted from the transmission antenna 25 can be set by the control unit 10, for example. For example, the frequency selected as the frequency of the transmission wave T transmitted from the transmission antenna 25 may be the frequency selected by the parameter setting unit 16. The frequency selected as the frequency of the transmission wave T transmitted from the transmission antenna 25 may be stored in the storage unit 40, for example. The signal whose frequency is raised by the synthesizer 22 is supplied to the phase control section 23 and the mixer 33. In the case where there are a plurality of phase control sections 23, the signal whose frequency is raised by the synthesizer 22 may be supplied to each of the plurality of phase control sections 23. In addition, in the case where there are a plurality of receiving sections 30, the signal whose frequency is raised by the synthesizer 22 may be supplied to each mixer 33 in the plurality of receiving sections 30.

The phase control unit 23 controls the phase of the transmission signal supplied from the synthesizer 22. Specifically, the phase control section 23 may appropriately advance or delay the phase of the signal supplied from the synthesizer 22 based on the control of the control section 10, for example, thereby adjusting the phase of the transmission signal. In this case, the phase control section 23 may adjust the phase of each transmission signal based on the path difference between each transmission wave T transmitted from the plurality of transmission antennas 25. The transmission waves T transmitted from the plurality of transmission antennas 25 are emphasized in a predetermined direction and formed into a beam (beam forming) by appropriately adjusting the phase of each transmission signal by the phase control section 23. In this case, the correlation between the direction of beam forming and the phase amount to be controlled of the transmission signal transmitted by each of the plurality of transmission antennas 25 may be stored in the storage unit 40, for example. The transmission signal phase-controlled by the phase control unit 23 is supplied to the amplifier 24.

The amplifier 24 amplifies the power (electric power) of the transmission signal supplied from the phase control unit 23, for example, based on the control of the control unit 10. In the case where the sensor 5 has a plurality of transmitting antennas 25, the plurality of amplifiers 24 may amplify the power (electric power) of the transmission signal supplied from each corresponding phase control unit 23 of the plurality of phase control units 23, respectively, based on the control of the control unit 10, for example. Since a technique of amplifying the power of a transmission signal is known per se, a more detailed description is omitted. The amplifier 24 is connected to a transmission antenna 25.

The transmission antenna 25 outputs (transmits) the transmission signal amplified by the amplifier 24 as a transmission wave T. In the case where the sensor 5 has a plurality of transmission antennas 25, the plurality of transmission antennas 25 may output (transmit) the transmission signal amplified by each corresponding amplifier 24 of the plurality of amplifiers 24 as the transmission wave T, respectively. Since the transmitting antenna 25 can be configured in the same manner as a transmitting antenna used in a known radar technique, a more detailed description is omitted.

In this way, the electronic apparatus 1 of the first embodiment can include the transmission antenna 25, and transmit a transmission signal (for example, a transmission chirp signal) as the transmission wave T from the transmission antenna 25. Here, at least one of the respective functional sections constituting the electronic apparatus 1 may be accommodated in one case. In addition, in this case, the one housing may be a structure that is not easily opened. For example, the transmitting antenna 25, the receiving antenna 31, and the amplifier 24 are accommodated in one housing, and the housing may be a structure that is not easily opened. Also, here, when the sensor 5 is provided to the mobile body 100 such as an automobile, the transmitting antenna 25 may transmit the transmission wave T to the outside of the mobile body 100 via a cover member such as a radome. In this case, the radar cover may be made of a material that allows electromagnetic waves to pass therethrough, such as synthetic resin or rubber. The radar cover may be, for example, a housing of the sensor 5. By covering the transmission antenna 25 with a cover member such as a radome, the risk of the transmission antenna 25 being damaged or malfunctioning due to contact with the outside can be reduced. In addition, the radome and the housing are also referred to as a radome.

The electronic device 1 shown in fig. 2 shows an example with two transmitting antennas 25. However, in the first embodiment, the electronic device 1 may include any number of transmission antennas 25. On the other hand, in the first embodiment, in the case where the transmission wave T transmitted from the transmission antenna 25 is formed into a beam in a predetermined direction, the electronic apparatus 1 may have a plurality of transmission antennas 25. In the first embodiment, the electronic device 1 may have any number of transmission antennas 25. In this case, the electronic apparatus 1 may further include a plurality of phase control sections 23 and amplifiers 24 corresponding to the plurality of transmission antennas 25, respectively. The plurality of phase control units 23 may control the phases of the plurality of transmission waves supplied from the synthesizer 22 and transmitted from the plurality of transmission antennas 25, respectively. Further, the plurality of amplifiers 24 may amplify the power of the plurality of transmission signals transmitted from the plurality of transmission antennas 25, respectively. In addition, in this case, the sensor 5 may be configured to include a plurality of transmission antennas. As described above, in the case of having a plurality of transmission antennas 25, the electronic apparatus 1 shown in fig. 2 may be configured to further include a plurality of functional sections necessary for transmitting the transmission waves T from the plurality of transmission antennas 25.

The receiving antenna 31 receives the reflected wave R. The reflected wave R is a wave in which the transmitted wave T is reflected by the predetermined object 200. The reception antenna 31 may be configured to include a plurality of antennas such as the reception antennas 31A to 31D. Since the receiving antenna 31 can be configured in the same manner as a receiving antenna used in a known radar technology, a more detailed description is omitted. The receive antenna 31 is connected to the LNA 32. The reception signal based on the reflected wave R received by the reception antenna 31 is supplied to the LNA 32.

The electronic apparatus 1 of the first embodiment is capable of receiving, from the plurality of receiving antennas 31, reflected waves R reflected by the predetermined object 200 of the transmitted wave T transmitted as a transmitted signal (transmitted chirp signal) such as a chirp signal. As described above, in the case of transmitting the transmission chirp signal as the transmission wave T, the reception signal based on the received reflected wave R is referred to as a reception chirp signal. That is, the electronic apparatus 1 receives a reception signal (for example, a reception chirp signal) as the reflected wave R from the reception antenna 31. Here, when the sensor 5 is provided to the mobile body 100 such as an automobile, the receiving antenna 31 may receive the reflected wave R from the outside of the mobile body 100 via a cover member such as a radome. In this case, the radar cover may be made of a material that allows passage of electromagnetic waves, such as synthetic resin or rubber. The radar cover may be, for example, a housing of the sensor 5. By covering the receiving antenna 31 with a member such as a radome, the risk of the receiving antenna 31 being damaged or malfunctioning due to contact with the outside can be reduced. In addition, the radome and the housing are also referred to as a radome.

In addition, in the case where the receiving antenna 31 is disposed in the vicinity of the transmitting antenna 25, these antennas may be collectively included in one sensor 5. That is, one sensor 5 may include, for example, at least one transmitting antenna 25 and at least one receiving antenna 31. For example, one sensor 5 may include a plurality of transmitting antennas 25 and a plurality of receiving antennas 31. In this case, a radar sensor may be covered by a cover member such as a radome.

The LNA32 amplifies a reception signal based on the reflected wave R received by the reception antenna 31 with low noise. The LNA32 may be a Low Noise Amplifier (Low Noise Amplifier) that amplifies a reception signal provided from the reception antenna 31 with Low Noise. The received signal amplified by the LNA32 is supplied to the mixer 33.

The mixer 33 generates a beat signal by mixing (multiplying) the reception signal of the RF frequency supplied from the LNA32 with the transmission signal supplied from the synthesizer 22. The beat signal mixed by the mixer 33 is supplied to the IF section 34.

The IF unit 34 reduces the frequency of the beat signal supplied from the mixer 33 to an Intermediate Frequency (IF) by performing frequency conversion on the beat signal. The beat signal whose frequency is reduced by the IF section 34 is supplied to the AD conversion section 35.

The AD conversion unit 35 digitizes the analog beat signal supplied from the IF unit 34. The AD Converter 35 may be configured by an arbitrary Analog-to-Digital Converter (ADC). The beat signal digitized by the AD conversion section 35 is supplied to the distance FFT processing section 11 of the control section 10. In the case where there are a plurality of the receiving sections 30, each beat signal digitized by the plurality of AD conversion sections 35 may be supplied to the distance FFT processing section 11.

The distance FFT processor 11 estimates the distance between the moving object 100 mounted with the electronic apparatus 1 and the object 200 based on the beat signal supplied from the AD converter 35. The distance FFT processing unit 11 may include, for example, a processing unit that performs fast fourier transform. In this case, the distance FFT processing unit 11 may be configured by an arbitrary circuit, a chip, or the like that performs Fast Fourier Transform (FFT) processing.

The distance FFT processing unit 11 performs FFT processing (hereinafter, referred to as "distance FFT processing" as appropriate) on the beat signal digitized by the AD conversion unit 35. For example, the distance FFT processing section 11 may perform FFT processing on the complex signal supplied from the AD conversion section 35. The beat signal digitized by the AD conversion section 35 can be expressed as a temporal change in signal intensity (power). The distance FFT processing section 11 can express signal strengths (powers) corresponding to the respective frequencies by performing FFT processing on such a beat signal. The distance FFT processing section 11 may determine that the predetermined object 200 is located at a distance corresponding to the peak value if the peak value is above a predetermined threshold value in the result obtained by the distance FFT processing. For example, for a constant error probability (CFAR (constant false alarm rate)) detection process, a determination method is known that determines that an object (reflected object) that reflects a transmission wave is present when a peak value equal to or larger than a threshold value is detected from an average power or amplitude of an interference signal.

As described above, the electronic apparatus 1 of the first embodiment can detect the object 200 reflecting the transmission wave T based on the transmission signal transmitted as the transmission wave T and the reception signal received as the reflected wave R.

The distance FFT processing section 11 can estimate the distance to the predetermined object based on one chirp signal (e.g., c1 shown in fig. 3). That is, the electronic apparatus 1 can measure (estimate) the distance L shown in fig. 1 by performing the distance FFT processing. Since a technique of measuring (estimating) a distance to a predetermined object by performing FFT processing on a beat signal is known per se, a more detailed description will be appropriately simplified or omitted. The result of the distance FFT processing by the distance FFT processing section 11 (for example, distance information) may be supplied to the velocity FFT processing section 12. In addition, the result of the distance FFT processing by the distance FFT processing section 11 may also be supplied to the object detection section 14.

The velocity FFT processor 12 estimates the relative velocity between the moving object 100 mounted with the electronic apparatus 1 and the object 200 based on the beat signal subjected to the distance FFT process by the distance FFT processor 11. The velocity FFT processing unit 12 may include, for example, a processing unit that performs fast fourier transform. In this case, the velocity FFT processing section 12 may be constituted by an arbitrary circuit, a chip, or the like that performs a Fast Fourier Transform (FFT) process.

The velocity FFT processing section 12 also performs FFT processing (hereinafter, appropriately referred to as "velocity FFT processing") on the beat signal subjected to the distance FFT processing by the distance FFT processing section 11. For example, the velocity FFT processing section 12 may perform FFT processing on the complex signal supplied from the distance FFT processing section 11. The velocity FFT processing section 12 can estimate the relative velocity with respect to the predetermined object based on the sub-frame (e.g., sub-frame 1 shown in fig. 3) of the chirp signal. As described above, if the range FFT processing is performed on the beat signal, a plurality of vectors can be generated. By obtaining the phase of the peak in the result of the velocity FFT processing performed on these plural vectors, the relative velocity with respect to the predetermined object can be estimated. That is, the electronic apparatus 1 can measure (estimate) the relative velocity between the moving body 100 and the predetermined object 200 shown in fig. 1 by performing velocity FFT processing. Since a technique of measuring (estimating) a relative velocity between a predetermined object by performing velocity FFT processing on a result of performing distance FFT processing is known per se, a more detailed description will be appropriately simplified or omitted. The result of the velocity FFT processing by the velocity FFT processing section 12 (for example, velocity information) may be supplied to the arrival angle estimating section 13. In addition, the result of the velocity FFT processing by the velocity FFT processing section 12 may also be supplied to the object detection section 14.

The arrival angle estimating unit 13 estimates the direction in which the reflected wave R arrives from the predetermined object 200, based on the result of the velocity FFT processing performed by the velocity FFT processing unit 12. The electronic apparatus 1 can estimate the direction in which the reflected wave R arrives by receiving the reflected wave R from the plurality of receiving antennas 31. For example, the plurality of receiving antennas 31 are arranged at predetermined intervals. In this case, the transmission wave T transmitted from the transmission antenna 25 is reflected by the predetermined object 200 to become a reflected wave R, and the reflected wave R is received by each of the plurality of reception antennas 31 arranged at predetermined intervals. Also, the arrival angle estimating section 13 can estimate the direction in which the reflected wave R reaches the receiving antenna 31 based on the phase of the reflected wave R received by the plurality of receiving antennas 31, respectively, and the path difference between each of the reflected waves R. That is, the electronic apparatus 1 can measure (estimate) the arrival angle θ shown in fig. 1 based on the result of performing the velocity FFT processing.

Various techniques have been proposed to estimate the direction in which the reflected wave R arrives based on the result of performing velocity FFT processing. For example, MUSIC (MUltiple Signal Classification: MUltiple Signal Classification) and ESPRIT (Estimation of Signal Parameters Via Rotational Invariance Technique: Signal parameter Estimation based on Rotational Invariance Technique) are known as known algorithms for estimating the direction of arrival. Therefore, a more detailed description of the known technology will be appropriately simplified or omitted. The information (angle information) of the arrival angle θ estimated by the arrival angle estimating section 13 may be supplied to the object detecting section 14.

The object detection unit 14 detects an object existing in a range in which the transmission wave T is transmitted, based on information supplied from at least any one of the distance FFT processing unit 11, the velocity FFT processing unit 12, and the arrival angle estimation unit 13. The object detection section 14 may perform, for example, clustering processing based on the supplied distance information, speed information, and angle information, thereby performing object detection. As an algorithm used for clustering data, for example, there is known a Density-based clustering method with noise (DBSCAN). In the clustering process, for example, the average power of the points constituting the object to be detected can be calculated. The distance information, speed information, angle information, and power information of the object detected in the object detection section 14 may be supplied to the detection range determination section 15. In addition, distance information, speed information, angle information, and power information of the object detected in the object detection portion 14 may be supplied to the ECU 50. In this case, when the mobile body 100 is an automobile, communication CAN be performed using a communication interface such as a CAN (Controller Area Network)

The detection range determining unit 15 determines a range of an object (hereinafter, also referred to as an "object detection range") in which the reflected transmission wave T is detected, from the transmission signal and the reception signal. Here, the detection range specifying unit 15 may specify the plurality of object detection ranges, for example, based on an operation by a driver or the like of the moving object 100 mounted with the electronic apparatus 1. For example, the detection range determination unit 15 may determine a plurality of object detection ranges suitable for parking assistance when a parking assistance button is operated by a driver or the like of the mobile body 100. In addition, the detection range determination portion 15 may determine a plurality of object detection ranges, for example, based on an instruction from the ECU 50. For example, when the ECU50 determines that the mobile unit 100 desires to reverse, the detection range determination section 15 may determine a plurality of suitable object detection ranges when the mobile unit 100 reverses based on an instruction from the ECU 50. The detection range determination unit 15 may determine a plurality of object detection ranges based on, for example, a change in the operation state of the mobile body 100 such as steering, accelerator, or shift position. Further, the detection range determining section 15 may determine a plurality of object detection ranges based on the result of the object detected by the object detecting section 14.

The parameter setting unit 16 sets various parameters that define a transmission signal and a reception signal for detecting an object that reflects the transmission wave T as the reflected wave R. That is, the parameter setting unit 16 sets various parameters for transmitting the transmission wave T from the transmission antenna 25 and various parameters for receiving the reflected wave R from the reception antenna 31.

In particular, in the first embodiment, the parameter setting unit 16 may set various parameters relating to transmission of the transmission wave T and reception of the reflected wave R so as to detect the object in the object detection range. For example, the parameter setting unit 16 may specify a range in which the reflected wave R is expected to be received, so as to receive the reflected wave R and detect the object in the object detection range. For example, the parameter setting unit 16 may define a range in which the beam direction of the transmission wave T is desired, and the like, so as to transmit the transmission wave T from the plurality of transmission antennas 25 and detect the object in the object detection range. The parameter setting unit 16 may set various parameters for transmitting the transmission wave T and receiving the reflected wave R.

Various parameters set by the parameter setting section 16 may be supplied to the signal generating section 21. Thus, the signal generator 21 can generate a transmission signal to be transmitted as the transmission wave T based on the various parameters set by the parameter setting unit 16. Various parameters set by the parameter setting section 16 may be supplied to the object detection section 14. Thus, the object detection unit 14 can perform the process of detecting the object within the object detection range specified based on the various parameters set by the parameter setting unit 16.

The ECU50 included in the electronic apparatus 1 of the first embodiment is capable of controlling the operation of the entire mobile object 100, including controlling the respective functional sections constituting the mobile object 100. To provide control and Processing capabilities for performing various functions, the ECU50 may include at least one processor, such as a CPU (Central Processing Unit). The ECU50 may be realized by a single processor in a collective manner, by several processors in a collective manner, or by separate processors. The processor may be implemented as a single integrated circuit. Integrated circuits are also known as ics (integrated circuits). The processor may be implemented as a plurality of communicatively coupled integrated circuits and discrete circuits. The processor may be implemented based on various other known technologies. In the first embodiment, the ECU50 may be configured as, for example, a CPU and a program executed by the CPU. ECU50 may suitably include memory required for operation of ECU 50. At least a part of the functions of the controller 10 may be the function of the ECU50, and at least a part of the functions of the ECU50 may be the function of the controller 10.

The electronic device 1 shown in fig. 2 has two transmitting antennas 25 and four receiving antennas 31. However, the electronic device 1 of the first embodiment may have any number of transmitting antennas 25 and any number of receiving antennas 31. For example, by having two transmitting antennas 25 and four receiving antennas 31, the electronic device 1 can be assumed to have a virtual antenna array consisting of eight antennas. In this way, the electronic apparatus 1 can receive the reflected waves R of the sixteen sub-frames shown in fig. 3 by supposing that eight antennas are used, for example.

Next, the operation of the electronic apparatus 1 of the first embodiment will be described.

In recent years, sensors capable of detecting obstacles and the like existing in the periphery of a vehicle such as an automobile include various sensors such as a millimeter wave radar, a LiDAR (Light Detection and Ranging) or an ultrasonic sensor. In these sensors, millimeter-wave radar is often used in terms of accuracy, reliability, cost, and the like for detecting an obstacle.

Examples of techniques for detecting obstacles around a vehicle using millimeter-wave radar include Blind Spot Detection (BSD), Cross Traffic Alert (CTA) during reverse or outbound, and Free Space Detection (FSD). In such detection, it is general to set in advance a radio wave emission range relating to the physical shape of the antenna of the millimeter wave radar to determine an object detection range. That is, in each of the respective radars, generally, the physical shape of the antenna of the millimeter wave radar is predetermined in accordance with the respective use, function, or the like, and the object detection range is also predetermined. Thus, to implement a plurality of different radar functions, a plurality of different radar sensors is required.

However, it is disadvantageous from the viewpoint of cost to prepare a plurality of radar sensors separately according to the use or function. In addition, for example, if the physical shape of the antenna is determined in advance and the transmission range is determined, it is difficult to change the use and function of the antenna. In addition, for example, when the physical shape and the emission range of the antenna are determined and all the objects within the emission range are detected, the amount of information to be processed increases. In this case, since an unnecessary object may be erroneously detected as an object, the reliability of detection is lowered. In addition, for example, if the physical shape and the transmission range of the antenna are determined and the number of sensors to be mounted is increased, fuel efficiency may be reduced due to an increase in the weight of the vehicle (mainly, a wire harness), or fuel efficiency may be reduced due to an increase in power consumption. Further, when a plurality of radar sensors are used for detection, since delay may occur between the sensors, it may take time to process when performing automatic driving, driving assistance, or the like based on such detection. This is because the processing speed of CAN is slower than the update rate of radar and also time is required in feedback. In addition, when a plurality of sensors having different object detection ranges are used for detection, control may become complicated.

Therefore, the electronic apparatus 1 of the first embodiment can use one radar sensor as a plurality of functions or purposes. In addition, the electronic apparatus 1 of the first embodiment can realize such an operation that a plurality of functions or usages are simultaneously realized by one radar sensor.

Fig. 4 is a diagram illustrating an operation of the electronic apparatus 1 of the first embodiment.

A moving object 100 shown in fig. 4 is mounted with the electronic apparatus 1 of the first embodiment. As shown in fig. 4, at least one sensor 5 is provided on the left side of the rear portion of the mobile body 100. As shown in fig. 4, sensor 5 is connected to ECU50 mounted on mobile body 100. A sensor 5 that operates in the same manner as the sensor 5 provided on the rear left side may also be provided at a position other than the rear left side of the moving body 100 shown in fig. 4. In the following description, only one sensor 5 provided on the rear left side will be described, and the description of the other sensors will be omitted. In the following description, each functional unit constituting the electronic apparatus 1 can be controlled by at least one of the control unit 10, the phase control unit 23, and the ECU 50.

As shown in fig. 4, the electronic apparatus 1 according to the first embodiment can select any one of a plurality of detection ranges to detect an object. In addition, the electronic apparatus 1 according to the first embodiment can switch to any one of the plurality of detection ranges to detect the object. In fig. 4, a range in which an object is detected by a transmission signal transmitted by the electronic apparatus 1 (particularly, the sensor 5) and a reception signal received by the electronic apparatus 1 (particularly, the sensor 5) of the first embodiment is shown.

For example, when the electronic apparatus 1 of the first embodiment is used for a purpose or a function such as a Parking Assist (Parking Assist), object detection can be performed with the range (1) shown in fig. 4 as an object detection range. The object detection range (1) shown in fig. 4 may be the same as or similar to that of, for example, a radar designed specifically for Parking assistance (park assist). In addition, for example, when the electronic device 1 according to the first embodiment is used for applications or functions such as passable region Detection (FSD), object Detection can be performed using the range (2) shown in fig. 4 as the object Detection range. The object detection range (2) shown in fig. 4 may be the same or similar range as that of, for example, a radar designed specifically for passable area detection (FSD).

In addition, for example, when the electronic apparatus 1 according to the first embodiment is used for, for example, a purpose or function of collision detection (CTA: Cross Traffic Alert) at the time of shipment, object detection can be performed with the range (3) shown in fig. 4 as the object detection range. The object detection range (3) shown in fig. 4 may be the same as or similar to that of a radar designed specifically for collision detection (CTA) at the time of shipment, for example. In addition, for example, when the electronic apparatus 1 according to the first embodiment is used for a purpose or a function such as Blind Spot Detection (BSD), object Detection can be performed with the range (4) shown in fig. 4 as the object Detection range. The object detection range (4) shown in fig. 4 may be the same or similar range as that of, for example, a radar designed specifically for Blind Spot Detection (BSD).

The electronic apparatus 1 according to the first embodiment can detect an object by arbitrarily switching a plurality of object detection ranges (1) to (4) shown in fig. 4, for example. As described above, the plurality of ranges to be switched in this case may be determined based on, for example, the operation of the driver or the like of the mobile body 100, or may be determined based on an instruction of the control portion 10, the ECU50, or the like.

As described above, in the electronic device 1 of the first embodiment, when object detection is performed in accordance with any of the object detection ranges (1) to (4), the detection range determination section 15 may determine any of a plurality of object detection ranges based on any information. When the detection range determining unit 15 determines a plurality of object detection ranges, the parameter setting unit 16 sets various parameters for transmitting a transmission signal and receiving a reception signal in the determined plurality of object detection ranges. The various parameters set by the parameter setting unit 16 may be stored in the storage unit 40 in advance, for example.

Such parameters may be determined prior to object detection by the electronic device 1, based on e.g. actual measurements in the test environment, etc. In addition, when such a parameter is not stored in the storage section 40, it may be a parameter that the parameter setting section 16 estimates as appropriate based on predetermined data such as past measurement data. In addition, when such parameters are not stored in the storage section 40, the parameter setting section 16 can acquire appropriate parameters by networking with an external network, for example.

As described above, in the first embodiment, the control unit 10 detects an object reflecting the transmission wave T based on the transmission signal transmitted as the transmission wave T and the reception signal received as the reflection wave R. In the first embodiment, the control unit 10 varies a plurality of object detection ranges (for example, object detection ranges (1) to (4) in fig. 4) based on the transmission signal and the reception signal.

In the first embodiment, the control unit 10 may switch the plurality of object detection ranges. For example, when object detection is being performed in the object detection range (3), the control unit 10 may switch the range in which object detection is performed from the object detection range (3) to the object detection range (2). In addition, in the first embodiment, the control portion 10 may vary the plurality of object detection ranges according to at least one of the use and the function of detecting an object (e.g., Parking Assist (PA), Blind Spot Detection (BSD), and the like). In addition, in the first embodiment, as will be described later, the control portion 10 may make the plurality of object detection ranges variable with a minute lapse of time. This control will be further explained later.

In addition, in the first embodiment, the control section 10 may determine a plurality of object detection ranges based on the detection result of the object. For example, when a predetermined object has been detected by object detection, the control section 10 may determine a plurality of object detection ranges according to the position of the object it detects. In addition, in the first embodiment, the control section 10 may process only the transmission signal and the reception signal in any one of the plurality of object detection ranges.

As described above, the electronic apparatus 1 of the first embodiment is capable of performing detection range clipping (setting and/or switching) in object detection by a millimeter wave radar or the like, for example. Thus, according to the electronic apparatus 1 of the first embodiment, it is possible to flexibly cope with a situation in which it is desired to detect an object in a plurality of object detection ranges. In addition, the electronic apparatus 1 according to the first embodiment can set the detection range of the object to be wide in advance, and cut out only information of a range necessary for detection based on information such as a distance and an angle detected by the electronic apparatus 1. Thus, according to the electronic apparatus 1 of the first embodiment, information of the detection range necessary for processing can be processed without increasing the processing load. Therefore, according to the electronic apparatus 1 of the first embodiment, the convenience of object detection can be improved.

As shown in fig. 4, the electronic apparatus 1 of the first embodiment varies the object detection range from the transmission signal and the reception signal, but may also direct the beam of the transmission wave T toward the object detection range. This enables the object in the desired cutting range to be detected with high accuracy.

For example, as described above, the electronic apparatus 1 according to the first embodiment can select the object detection range (4) from the plurality of detection ranges shown in fig. 4 as the use or function of the Blind Spot Detection (BSD) to perform the object detection. The electronic apparatus 1 of the first embodiment may also form a beam of the transmission waves T transmitted from the plurality of transmission antennas 25 toward the direction of the object detection range (4) (beamforming). For example, when the object detection is performed at a distance, the beam forming is performed in the direction using the beams of the transmission waves transmitted from the plurality of transmission antennas 25, and thus the object detection range can be covered with high accuracy.

Fig. 5 and 6 are diagrams showing examples of the configurations of the transmitting antenna and the receiving antenna in the electronic device of the first embodiment.

As shown in fig. 5, the sensor 5 of the electronic device 1 of the first embodiment may include, for example, two transmitting antennas 25A and 25A'. In addition, as shown in fig. 5, the sensor 5 of the electronic apparatus 1 of the first embodiment may include four receiving antennas 31A, 31B, 31C, and 31D.

The wavelength of the transmission wave T is λ, and the four receiving antennas 31A, 31B, 31C, and 31D are arranged at intervals of λ/2 in the horizontal direction (X-axis direction), respectively. As described above, by arranging the plurality of receiving antennas 31 in parallel in the horizontal direction and receiving the transmission wave T by the plurality of receiving antennas 31, the electronic apparatus 1 can estimate the direction in which the reflected wave R reaches. Here, when the frequency band of the transmission wave T is, for example, 77GHz to 81GHz, the wavelength λ of the transmission wave T may be the wavelength of the transmission wave T whose center frequency is 79 GHz.

The transmission wave T has a wavelength λ, and the two transmission antennas 25A and 25A' are arranged at an interval λ/2 in the vertical direction (Z-axis direction). As described above, by arranging the plurality of transmission antennas 25 in parallel in the vertical direction and transmitting the transmission wave T by the plurality of transmission antennas 25, the electronic apparatus 1 can change the beam direction of the transmission wave T to the vertical direction.

As shown in fig. 6, the sensor 5 of the electronic device 1 according to the first embodiment may include, for example, four transmission antennas 25A, 25A ', 25B, and 25B'.

Here, as shown in fig. 6, the wavelength of the transmission wave T is λ, and the two transmission antennas 25A and 25B are arranged at an interval of λ/2 in the horizontal direction (X-axis direction). As shown in fig. 6, the wavelength of the transmission wave T is λ, and the two transmission antennas 25A 'and 25B' are also arranged at an interval of λ/2 in the horizontal direction (X-axis direction). As described above, by arranging the plurality of transmission antennas 25 in parallel in the horizontal direction and transmitting the transmission wave T by the plurality of transmission antennas 25, the electronic apparatus 1 can also change the beam direction of the transmission wave T to the horizontal direction.

On the other hand, as shown in fig. 6, the wavelength of the transmission wave T is λ, and the two transmission antennas 25A and 25A' are arranged at an interval of λ/2 in the vertical direction (Z-axis direction). As shown in fig. 6, the wavelength of the transmission wave T is λ, and the two transmission antennas 25B and 25B' are also arranged at an interval of λ/2 in the vertical direction (Z-axis direction). As described above, in the configuration shown in fig. 6, by arranging the plurality of transmission antennas 25 side by side in the vertical direction, the transmission wave T is transmitted by the plurality of transmission antennas 25, and the electronic apparatus 1 can change the direction of the beam of the transmission wave T to the vertical direction.

In the electronic device 1 according to the first embodiment, when beamforming of the transmission waves T transmitted from the plurality of transmission antennas 25 is performed, the phases of the transmission waves T may be aligned in a predetermined direction on the basis of the path difference when the plurality of transmission waves T are transmitted. In the electronic apparatus 1 of the first embodiment, in order to align the phase of each transmission wave T in a predetermined direction, for example, the phase control section 23 may control the phase of at least one of the transmission waves transmitted from the plurality of transmission antennas 25.

The amount of phase controlled in order to align the phases of the plurality of transmission waves T in a predetermined direction may be stored in the storage section 40 in correspondence with the predetermined direction. That is, the relationship between the direction of the beam and the amount of phase at the time of beamforming may be stored in the storage unit 40.

Such a relation may be determined based on, for example, actual measurements in the test environment, etc., prior to object detection by the electronic device 1. In addition, when such a relationship is not stored in the storage section 40, an appropriately estimated relationship may be set by the phase control section 23 based on predetermined data such as past measurement data. In addition, when such a relationship is not stored in the storage section 40, the phase control section 23 may acquire an appropriate relationship by, for example, networking with an external network.

In the electronic device 1 of the first embodiment, control for performing beamforming of the transmission waves T transmitted from the plurality of transmission antennas 25 may be performed by at least one of the control unit 10 and the phase control unit 23. In the electronic device 1 according to the first embodiment, a functional unit including at least the phase control unit 23 is referred to as a transmission control unit.

As described above, in the electronic device 1 of the first embodiment, the transmission antenna 25 may include a plurality of transmission antennas. In the electronic device 1 according to the first embodiment, the receiving antenna 31 may include a plurality of receiving antennas. In addition, in the electronic device 1 of the first embodiment, the transmission control section (for example, the phase control section 23) may control the transmission waves T transmitted from the plurality of transmission antennas 25 to form a beam in a predetermined direction (beam forming). In addition, in the electronic apparatus 1 of the first embodiment, the transmission control section (for example, the phase control section 23) may form a beam in the direction of the range in which the object is detected.

In addition, in the electronic device 1 of the first embodiment, as described above, the transmission antenna 25 may include a plurality of transmission antennas 25 configured to include the vertical direction component. In this case, in the electronic apparatus 1 of the first embodiment, the phase control section 23 (transmission control section) may change the direction of the beam to include a vertical direction component in the direction of the object detection range.

Also, in the electronic device 1 of the first embodiment, as described above, the transmission antenna 25 may include a plurality of transmission antennas 25 configured to include a horizontal direction component. In this case, in the electronic apparatus 1 of the first embodiment, the phase control section 23 (transmission control section) may change the direction of the beam to include a horizontal direction component in the direction of the object detection range.

In addition, in the electronic apparatus 1 of the first embodiment, the transmission control section (for example, the phase control section 23) may form a beam in a direction covering at least a part of the range of the detection object. In addition, in the electronic apparatus 1 of the first embodiment, the transmission control section (for example, the phase control section 23) may control the phase of at least one of the plurality of transmission waves so that the phase of each of the transmission waves T transmitted from the plurality of transmission antennas 25 is aligned in a predetermined direction.

According to the electronic apparatus 1 of the first embodiment, it is possible to calculate a compensation value of a phase based on frequency information of a wide-frequency band signal (for example, FMCW signal) output from the plurality of transmission antennas 25 and to perform phase compensation with respect to the frequency for each of the plurality of transmission antennas. This makes it possible to perform high-precision beamforming for a specific direction in the entire frequency band in which a transmission signal can be obtained.

According to such beam forming, the distance of a detectable object can be enlarged in a specific direction in which the object needs to be detected. In addition, according to the beam forming as described above, a reflected signal from an unnecessary direction can be reduced. Therefore, the accuracy of detecting the distance/angle can be improved.

Fig. 7 is a diagram illustrating the type of detection distance of the radar realized by the electronic device 1 of the first embodiment.

As described above, the electronic apparatus 1 of the first embodiment can perform shearing of the object detection range and/or beamforming of the transmission wave. By using at least one of the shear of the object detection range and the beam forming of the transmission wave, a range in which the distance to the object can be detected can be defined from the transmission signal and the reception signal.

As shown in fig. 7, the electronic apparatus 1 of the first embodiment can perform object detection in the range of r1, for example. The range r1 shown in fig. 7 may be a range in which object detection can be performed by Ultra Short Range Radar (USRR), for example. As shown in fig. 7, the electronic apparatus 1 according to the first embodiment can perform object detection in the range of r2, for example. The range r2 shown in fig. 7 may be a range in which object detection can be performed by Short Range Radar (SRR), for example. As shown in fig. 7, the electronic apparatus 1 according to the first embodiment can detect an object in the range of r3, for example. The range r3 shown in fig. 7 may be a range in which object detection can be performed by a Mid Range Radar (MRR), for example. As described above, the electronic apparatus 1 of the first embodiment can appropriately switch any one of the range r1, the range r2, and the range r3, for example, to perform object detection. Such radars having different detection distances tend to have lower measurement accuracy as the detection distance becomes longer.

As described above, in the electronic apparatus 1 of the first embodiment, the control section 10 may set a range in which the distance of the object is detected by the transmission signal and the reception signal, in accordance with any one of the plurality of object detection ranges.

Next, in the electronic apparatus 1 according to the first embodiment, a description will be given of a mode in which any one of a plurality of object detection ranges is set for each frame of the transmission wave T or the like.

The electronic device 1 according to the first embodiment may store, for example, parameters defining various settings for clipping the object detection range in the storage unit 40. The electronic device 1 according to the first embodiment may also store, for example, parameters defining various settings for performing beamforming toward the object detection range in the storage unit 40. The electronic device 1 according to the first embodiment may store, for example, parameters defining various settings for realizing the type of the detected distance by the radar as shown in fig. 7 in the storage unit 40.

The electronic apparatus 1 of the first embodiment can set (allocate) an operation for realizing a function of a plurality of types of radars for each minute time interval such as a frame of the transmission wave T. For example, the following describes operations for setting three types of radars for realizing different radar functions for each minute time interval, for example, a frame of the transmission wave T.

Hereinafter, the three types of radars are referred to as "radar 1", "radar 2", and "radar 3", respectively, for convenience. These "radar 1", "radar 2" and "radar 3" are distinguished by specifying parameters for achieving operation as different radar functions. That is, "radar 1", "radar 2", and "radar 3" may be radars different in object detection range, respectively. These different types of radar may be specified by different parameters, for example. The "radar 1", "radar 2", and "radar 3" may be radars that are different in the presence or absence of beamforming and the direction in which beamforming is performed. These different types of radar may also be specified by different parameters, for example. Also, "radar 1", "radar 2", and "radar 3" may be different types of radars each according to the detection distance of the radar as shown in fig. 7. These different types of radar may also be specified by different parameters, for example.

Fig. 8 to 10 are diagrams showing a case where functions of different types of radars are set (allocated) for each frame of the transmission wave T and the like.

Fig. 8 is a diagram showing a frame of a transmission wave T, as in fig. 3. In the example shown in fig. 8, frames 1 to 6 of the transmission wave T are shown, but there may be subsequent frames thereafter. In addition, each frame shown in fig. 8 may include sixteen subframes, for example, as in frame 1 shown in fig. 3. In addition, in this case, each of the sub-frames may include, for example, eight chirp signals, as in the respective sub-frames shown in fig. 3.

For example, as shown in fig. 8, the electronic device 1 according to the first embodiment may set (assign) a different radar function for each frame of the transmission wave T. For example, the electronic apparatus 1 according to the first embodiment may set any one of a plurality of object detection ranges for each frame of the transmission wave T, for example. As described above, in the electronic apparatus 1 of the first embodiment, the control unit 10 can set any one of a plurality of object detection ranges for each frame of the transmission wave T. In the electronic apparatus 1 according to the first embodiment, the control unit 10 may switch any one of the plurality of object detection ranges for each frame of the transmission wave T to transmit the transmission signal and receive the reception signal. In the example shown in fig. 8, the function of radar 1 is set in frame 1 of transmission wave T, the function of radar 2 is set in frame 2 of transmission wave T, the function of radar 3 is set in frame 3 of transmission wave T, and the same function is repeatedly set thereafter. In the first embodiment, the frames of the transmission wave T may be ordered in, for example, tens of microseconds or the like. Therefore, the electronic device 1 according to the first embodiment functions as a different radar for each very short time. Therefore, the electronic apparatus 1 of the first embodiment operates in such a manner that a plurality of functions or uses are simultaneously realized by one radar sensor.

Fig. 9 is a diagram showing subframes included in a frame of a transmission wave T, as in fig. 3. In the example shown in fig. 9, subframes 1 to 6 of the transmission wave T are shown, but there may be subsequent subframes thereafter. Sub-frames 1 to 6 shown in fig. 9 may form a part of sixteen sub-frames included in frame 1 shown in fig. 3. In addition, each of the respective sub-frames shown in fig. 9 may include, for example, eight chirp signals, respectively, as in the respective sub-frames shown in fig. 3.

For example, as shown in fig. 9, the electronic device 1 of the first embodiment may set (assign) a different radar function for each subframe of the transmission wave T. For example, the electronic device 1 according to the first embodiment may set any one of a plurality of object detection ranges for each subframe of the transmission wave T, for example. As described above, in the electronic apparatus 1 of the first embodiment, the control section 10 may set any one of a plurality of object detection ranges according to the transmission signal and the reception signal for each part (for example, subframe) of the frame constituting the transmission wave T. In the example shown in fig. 9, the function of radar 1 is set in subframe 1 of transmission wave T, the function of radar 2 is set in subframe 2 of transmission wave T, the function of radar 3 is set in subframe 3 of transmission wave T, and the same functions are repeatedly set thereafter. In the first embodiment, each subframe of the transmission wave T may be shorter than the time of one frame, for example. Therefore, the electronic device 1 according to the first embodiment functions as a different radar for each short time. Therefore, the electronic apparatus 1 of the first embodiment operates in such a manner that a plurality of functions or uses are simultaneously realized by one radar sensor.

Fig. 10 is a diagram showing chirp signals included in a sub-frame of a transmitted wave T, as in fig. 3. In the example shown in fig. 10, the middle of the transmission wave T from the subframe 1 to the subframe 2 is shown, but the subframes after the subframe 1 may also continue in the same manner as the subframe 1. In addition, the subframe 1 shown in fig. 10 may include eight chirp signals, like the subframe 1 shown in fig. 3. In addition, each of the respective chirp signals shown in fig. 10 may be the same as each of the eight chirp signals included in the respective sub-frames shown in fig. 3.

For example, as shown in fig. 10, the electronic apparatus 1 of the first embodiment may set (assign) a different radar function for each of the chirp signals included in the sub-frame of the transmitted wave T. For example, the electronic apparatus 1 of the first embodiment may set any one of a plurality of object detection ranges for each chirp signal of the transmitted wave T, for example. As described above, in the electronic apparatus 1 of the first embodiment, the control section 10 may set any one of a plurality of object detection ranges according to the transmission signal and the reception signal for each chirp signal constituting a frame of the transmission wave T. In the example shown in fig. 10, the function of radar 1 is set in the chirp signal c1 of the transmitted wave T, the function of radar 2 is set in the chirp signal c2 of the transmitted wave T, the function of radar 3 is set in the chirp signal c3 of the transmitted wave T, and the same functions are also repeatedly set thereafter. In the first embodiment, each chirp signal of the transmitted wave T may be shorter than the time of 1 subframe, for example. Therefore, the electronic device 1 according to the first embodiment functions as a radar different for each short time. Therefore, the electronic apparatus 1 in the first embodiment operates in such a manner that a plurality of functions or uses are simultaneously realized by one radar sensor.

As described above, according to the electronic apparatus 1 of the first embodiment, it is possible to perform the clipping of the detection range and the beamforming toward the direction of the clipped detection range according to various uses or functions. In addition, the electronic apparatus 1 according to the first embodiment can arbitrarily switch between the clipping of the detection range and the beamforming in the direction of the clipped detection range. Therefore, for example, one radar sensor can be dynamically switched to a plurality of applications or functions for use. Therefore, according to the electronic apparatus 1 of the first embodiment, the convenience of object detection can be improved. In addition, according to the electronic apparatus 1 of the first embodiment, not only the object detection with high accuracy can be realized, but also it is extremely advantageous in view of cost.

In addition, according to the electronic apparatus 1 of the first embodiment, the use and function of one sensor can be changed by appropriately changing the direction of the beam of the transmission wave transmitted from the plurality of transmission antennas or switching the object detection range. In addition, according to the electronic apparatus 1 of the first embodiment, since only a specific portion within the range of the transmission wave T can be detected, an increase in the amount of information to be processed is suppressed. In addition, according to the electronic apparatus 1 of the first embodiment, since the possibility of erroneously detecting an unnecessary object as well as an object is also reduced, the reliability of detection can be improved.

In addition, according to the electronic apparatus 1 of the first embodiment, it is possible to detect an object as if it were a plurality of sensors with one sensor 5. Therefore, according to the electronic apparatus 1 of the first embodiment, the weight of the vehicle (particularly, the wire harness) is not increased. Therefore, according to the electronic apparatus 1 of the first embodiment, it is also possible to avoid a decrease in fuel efficiency due to the addition of the sensor 5 or a decrease in fuel efficiency due to an increase in power consumption.

In addition, according to the electronic apparatus 1 of the first embodiment, the functions of a plurality of radar sensors can be integrated. Thus, delays such as may occur between multiple sensors may also be avoided. This can avoid a problem that the processing may take time in the automatic driving, the driving assistance, or the like. Furthermore, according to the electronic apparatus 1 of the first embodiment, it is also possible to avoid such a situation that control may become cumbersome, such as when detecting using a plurality of sensors different in object detection range.

Conventionally, when object detection is performed in a plurality of object detection ranges, detection can be performed by using a plurality of sensors each having a unique object detection range. However, in the past, it was difficult to accurately perform object detection in, for example, a short distance using one sensor, and also detect an object located at a far distance.

In this regard, the electronic apparatus 1 according to the first embodiment can perform object detection in a plurality of object detection ranges by one sensor. In addition, according to the electronic apparatus 1 of the first embodiment, it is possible to operate in such a manner that object detection is simultaneously performed in a plurality of object detection ranges.

Fig. 11 is a flowchart illustrating the operation of the electronic apparatus of the first embodiment. The following describes a flow of operations of the electronic device according to the first embodiment.

The operation shown in fig. 11 may be started, for example, when an object existing around the mobile body 100 is detected by the electronic apparatus 1 mounted on the mobile body 100.

When the operation shown in fig. 11 is started, the detection range determination section 15 of the control section 10 determines a plurality of object detection ranges to be switched for use (step S1). For example, in step S1, the detection range specifying unit 15 may specify, as the object detection range, a plurality of ranges from among the object detection ranges (1) to (4) shown in fig. 4. In step S1, the detection range determination portion 15 may determine the plurality of object detection ranges based on, for example, an operation by the driver or the like of the mobile body 100, or may determine the plurality of object detection ranges based on, for example, an instruction by the control portion 10 or the ECU50 or the like.

In addition, the operation shown in step S1 is not initially started after the operation shown in fig. 11 has been previously performed, but may be an operation performed again after the operation shown in fig. 11 is started. When there is a result that the object has been detected by the object detection section 14 at the point in time of step S1 performed again, the detection range determination section 15 may determine a plurality of object detection ranges based on the positions of the detected objects.

When a plurality of object detection ranges are determined in step S1, the parameter setting part 16 sets various parameters in the electronic device 1 for each of the individual frames or the like of the transmission wave T (step S2) so as to detect objects in the determined plurality of object detection ranges. For example, in step S2, the parameter setting unit 16 sets various parameters so that a plurality of ranges are cut out as object detection ranges in the object detection ranges (1) to (4) shown in fig. 4 for each frame of the transmission wave T and object detection is performed. In step S2, as shown in fig. 8 to 9, various parameters may be set for each frame of the transmitted wave T, may be set for each part (e.g., sub-frame) constituting the frame, or may be set for each chirp signal. Various parameters set for cutting out detection ranges such as the respective object detection ranges and performing object detection can be stored in the storage section 40, for example. In this case, in step S2, the parameter setting unit 16 may read and set various parameters from the storage unit 40. In step S2, the parameter setting unit 16 may set various parameters for the object detection unit 14, for example.

In step S2, the parameter setting unit 16 may set various parameters so that the beam of the transmission wave is formed in the direction of each of the determined object detection ranges for each frame of the transmission wave T and the like. For example, in step S2, the parameter setting unit 16 sets various parameters so that the beam of the transmission wave is directed toward the object detection range determined in step S1 for each frame of the transmission wave T and the like. Various parameters set for directing the beam of the transmission wave toward the detection range such as the respective object detection ranges can be stored in the storage section 40, for example. In this case, in step S2, the parameter setting unit 16 may read and set various parameters from the storage unit 40. In step S2, the parameter setting unit 16 may set various parameters for the phase control unit 23 (transmission control unit) or the transmission unit 20, for example, for each frame of the transmission wave T.

As described above, in the electronic apparatus 1 according to the first embodiment, the parameter setting unit 16 of the control unit 10 can set a parameter that defines any one of a plurality of object detection ranges from the transmission signal and the reception signal for each frame of the transmission wave T or the like. In addition, the parameter setting unit 16 may switch the radar type for each frame or each processing unit in the frame among the radar types having different detection ranges, and notify the signal generation unit 21 of the switched radar type.

After setting the parameters in step S2, the control unit 10 controls the transmission of the transmission wave T from the transmission antenna 25 in accordance with the order of the frames of the transmission wave T and the like (step S3). For example, in step S3, the signal generator 21 may generate transmission signals that function as various types of radars in accordance with the order of the frames of the transmission wave T and the like based on the parameters set by the parameter setting unit 16. When beamforming of the transmission wave T is performed, in step S3, the phase control unit 23 (transmission control unit) controls each of the transmission waves T transmitted from the plurality of transmission antennas 25 to form a beam in a predetermined direction in accordance with the order of the frames of the transmission waves T and the like. In this case, the phase control section 23 (transmission control section) may control the phase of each transmission wave T. The phase control unit 23 (transmission control unit) may perform control such that the beam of the transmission wave T is directed toward the object detection range determined in step S1, for example, so as to cover at least a part of the object detection range, in accordance with the order of the frames of the transmission wave T and the like.

After transmitting the transmission wave T in step S3, the control unit 10 controls to receive the reflected wave R from the reception antenna 31 (step S4).

After receiving the reflected wave R in step S4, the control unit 10 detects an object existing around the mobile object 100 (step S5). In step S5, the object detection unit 14 of the control unit 10 may perform object detection (clipping of the object detection range) in the object detection range determined in step S1. In step S5, the object detection portion 14 of the control portion 10 may detect the presence of an object based on the estimation result of at least any one of the distance FFT processing portion 11, the velocity FFT processing portion 12, and the arrival angle estimation portion 13.

In the electronic device 1 according to the first embodiment, the object detection unit 14 of the control unit 10 may perform object detection (e.g., clustering) processing based on angle, speed, and distance information obtained for each of a plurality of different types of radars, for example, and calculate the average power of points constituting the object. In addition, in the electronic apparatus 1 of the first embodiment, the object detection portion 14 may notify the upper control CPU such as the ECU50 of the object detection information or the point cloud information obtained for each of the plurality of different types of radars.

Since the detection of the object in step S5 can be performed based on various algorithms and the like using a technique using a known millimeter wave radar, a more detailed description is omitted. After step S5 shown in fig. 11, the controller 10 may restart the process of step S1. In this case, the object detection range may be determined in step S1 based on the result of detecting the object in step S5. As described above, in the electronic apparatus 1 of the first embodiment, the control unit 10 can detect the object reflecting the transmission wave T based on the transmission signal transmitted as the transmission wave T and the reception signal received as the reflected wave R.

In the first embodiment described above, any one of a plurality of ranges in which an object is detected by transmitting and receiving a signal is set for each frame, each subframe, or each chirp signal, for example. On the other hand, in the first embodiment, at least any one of a plurality of ranges in which an object is detected by transmitting and receiving a signal can be set more flexibly in a frame or a subframe, for example. Hereinafter, such an embodiment will be described.

In the first embodiment shown in fig. 10, a different radar function is set (allocated) for each chirp signal included in a subframe of a transmitted wave T. In fig. 10, the function of the radar 1 is set in the chirp signal c1, the function of the radar 2 is set in the chirp signal c2, the function of the radar 3 is set in the chirp signal c3, and the same function is repeatedly set thereafter. In addition, in the example shown in fig. 10, the respective chirp signals respectively have the same time length. In addition, in the example shown in fig. 10, the maximum frequencies of the respective chirp signals are all the same. Therefore, the frequency gradient is the same in each chirp signal. Also, in the example shown in fig. 10, the respective chirp signals are configured without a gap, i.e., without a time interval, in a subframe or frame. However, in the first embodiment, when a different radar function is assigned for each chirp signal, it is not necessarily the configuration of the chirp signal of the example shown in fig. 10.

Fig. 12 is a diagram illustrating an example in which the electronic apparatus 1 of the second embodiment sets the object detection range in a frame. As shown in fig. 12, the control section 10 of the electronic apparatus according to the first embodiment may arrange different chirp signals in a frame, for example. In fig. 12, the function of the radar 1 is set in the chirp signal c1, the function of the radar 2 is set in the chirp signal c2, and the function of the radar 3 is set in the chirp signal c3, as in fig. 10. On the other hand, in fig. 12, the respective chirp signals may be arranged with an interval therebetween, that is, with a time interval. In particular, in fig. 12, the chirp signal c1 does not start from the beginning of frame 1. In addition, in the example shown in fig. 12, the respective chirp signals do not have the same time length, respectively. In addition, in the example shown in fig. 12, the maximum frequencies of the respective chirp signals are not all the same. Therefore, the frequency gradients are not all the same in the respective chirp signals. Each chirp signal shown in fig. 12 is an example. The electronic apparatus 1 of the first embodiment can appropriately configure a chirp signal having an arbitrary length and an arbitrary frequency band in each frame.

Also, in the example shown in fig. 12, the same configuration of the chirp signal as that of frame 1 may also be repeated after frame 2, or a chirp signal different from that of frame 1 may be configured after frame 2. In addition, in the example shown in fig. 12, the frame 2 may be followed by different configurations of chirp signals, respectively.

In the chirp signals in frame 1 shown in fig. 12, the maximum frequency of the chirp signal c1 is the largest, and the maximum frequency of the chirp signal c2 is the smallest. In addition, in the chirp signals in the frame 1 shown in fig. 12, the time of the chirp signal c1 is relatively short, and the times of the chirp signal c2 and the chirp signal c3 are relatively long. When the time of the chirp signal is long, since the power thereof is large, the accuracy in object detection can be improved. In addition, when the frequency band of the chirp signal is wide, the accuracy in object detection can be improved as well.

As described above, the control unit 10 of the electronic device 1 according to the first embodiment can set at least any one of a plurality of ranges in which an object is detected by the transmission signal and the reception signal in the frame of the transmission wave. As described above, in the first embodiment, at least any one of a plurality of ranges in which an object is detected can be set more flexibly in a frame or a subframe, for example. Fig. 12 shows an example in which at least any one of a plurality of ranges of the detection object is flexibly set in each frame. On the other hand, the control unit 10 of the electronic device 1 according to the first embodiment can flexibly set at least any one of a plurality of ranges in which an object is detected in each subframe.

(second embodiment)

Next, an electronic device according to a second embodiment will be described. The electronic device according to the second embodiment performs calibration of the transmission wave based on the transmission signal and the reception signal.

Fig. 13 is a functional block diagram schematically showing an example of the configuration of the electronic apparatus of the second embodiment. An example of the configuration of the electronic device according to the second embodiment will be described below.

As shown in fig. 13, the electronic apparatus 2 of the second embodiment may have the same configuration as the electronic apparatus 1 of the first embodiment shown in fig. 2 except for a part. That is, as shown in fig. 13, the electronic device 2 according to the second embodiment is the electronic device 1 shown in fig. 2, to which the calibration processing unit 17 is added. Therefore, hereinafter, the same or similar explanation as that explained in fig. 2 will be appropriately simplified or omitted

The calibration processing section 17 performs calibration processing based on the beat signal digitized by the AD conversion section 35. That is, the calibration processing unit 17 calibrates the transmission wave based on the transmission signal and the reception signal. The signal subjected to the calibration process by the calibration processing section 17 may be supplied to the distance FFT processing section 11

Fig. 14 is a diagram illustrating a configuration of a frame in the second embodiment.

Fig. 14 is a diagram illustrating an example in which the electronic device 2 of the second embodiment sets the object detection range and the chirp signal for calibration in a frame. As shown in fig. 14, the control section 10 of the electronic device 2 according to the second embodiment may arrange different chirp signals in a frame, for example. In fig. 14, the chirp signal c1 sets the function of the radar 1, and the chirp signal c2 sets the function of the radar 2. In addition, in fig. 14, the chirp signal c3 is allocated as a chirp signal for calibration. Each chirp signal shown in fig. 14 is an example. The electronic apparatus 1 of the second embodiment can appropriately configure a chirp signal having an arbitrary length and an arbitrary frequency band in each frame.

For example, in fig. 14, the chirp signal c3 used for calibration may be arranged at an arbitrary position in the frame. In addition, the chirp signal c3 used for calibration may have an arbitrary length. In addition, the chirp signal c3 used for calibration may have an arbitrary maximum frequency. Therefore, the chirp signal c3 used for calibration may have an arbitrary frequency gradient.

In the example shown in fig. 14, there is only one chirp signal c3 used for calibration. However, there may be any number of chirp signals c3 used for calibration in each frame. For example, in the example shown in fig. 14, more than two chirp signals for calibration may be configured in frame 1. In addition, in the example shown in fig. 14, the chirp signal for calibration may be configured after frame 2 instead of in frame 1.

When the sensor 5 is required to have a higher measurement accuracy, a relatively large number of chirp signals for calibration may be included. On the other hand, when the sensor 5 is not required to have such high measurement accuracy, a relatively small chirp signal for calibration may be included. For example, the chirp signal for calibration may be configured every 1 frame. The chirp signal for calibration may be arranged at an arbitrary frame interval, for example, every 5 frames or 10 frames. In addition, instead of regularly arranging chirp signals for calibration every predetermined 5 frames, chirp signals for calibration may be arranged at random frame intervals.

Also, in the example shown in fig. 14, the same configuration of the chirp signal as that of frame 1 may also be repeated after frame 2, or a chirp signal different from that of frame 1 may be configured after frame 2. In addition, in the example shown in fig. 14, the frame 2 may be followed by different configurations of chirp signals, respectively.

As described above, the control unit 10 of the electronic device 2 according to the second embodiment includes the chirp signal for performing the calibration process in a frame or a sub-frame. That is, the control section 10 of the electronic device 2 configures (allocates) a chirp signal (signal for calibration) for performing calibration processing in a frame or a subframe. The control unit 10 of the electronic device 2 performs calibration using signals included in a frame or a subframe.

As described above, a general radar sensor has a function of calculating at least one of a distance, a relative speed, and an angle to an object to be detected. On the other hand, a general radar sensor has the following factors that may cause errors. For example, regarding the distance, an error may occur due to a position where the radar sensor is mounted (an installation depth with respect to a vehicle surface) and/or a deviation of a clock frequency inside the radar sensor. In addition, regarding the relative speed, an error may occur due to an error of a speedometer of the vehicle and/or a deviation of a clock frequency inside the radar sensor. Further, regarding the angle, there is a possibility that an error may occur due to a deviation of the angle at which the radar sensor is mounted and/or a deviation of the shape and the interval at the time of manufacturing the antenna.

Hereinafter, as an example, the error of the angle is further described. The angle detected by the radar sensor is calculated based on the angle at which the radar sensor is mounted on the vehicle. For example, assuming that the radar sensor is mounted at an angle of 5 degrees with respect to the reference angle of the vehicle, the result of estimating the angle by the radar sensor is that the reference angle with respect to the vehicle is 10 degrees. In this case, the radar sensor recognizes that the angle of the detected object is in the direction of 15 degrees with respect to the vehicle. However, for example, assuming that the radar sensor is mounted at an angle of 7 degrees with respect to the vehicle reference angle, the result of estimating the angle by the radar sensor is 10 degrees with respect to the vehicle reference angle. In this case, the radar sensor recognizes that the angle of the detected object is in the direction of 17 degrees with respect to the vehicle. Such deviations in the mounting angle are difficult to eliminate completely and are essentially accompanied by initial and/or aged deviations.

Therefore, in order to reduce the influence of the variation, the electronic device 2 according to the second embodiment performs the calibration process, for example, during operation. The calibration process performed by the calibration processing section 17 may be, for example, a calibration function for accurately maintaining the object detection function of the electronic apparatus 2. Here, the above-described calibration process will be described.

The radar such as the sensor 5 is mainly intended to detect an object that may have a risk of collision when a moving body such as a vehicle on which the radar is mounted travels. However, the radar of the sensor 5 can also detect an object having a relatively low risk of collision when the moving body is traveling, such as a guardrail, a utility pole, and the like. When such an object is detected by radar, it is considered to be an object that is located in the moving direction of the moving body and moves in the direction opposite to the moving direction.

Therefore, the electronic apparatus 2 according to the second embodiment is calibrated using, for example, the chirp signal c3 shown in fig. 14. Specifically, the electronic apparatus 2 transmits a transmission wave such as the chirp signal c3 shown in fig. 14 from the transmission antenna 25, and receives a reflected wave reflected by the guard rail, for example, from the reception antenna 31. The calibration processing unit 17 may compare the beat signal digitized by the AD conversion unit 35 with the information of the known object (guard rail) stored in the storage unit 40. Here, the calibration processing unit 17 may compare the trajectory (known data) of the object to be detected with the trajectory of the object to be detected in the first place, taking into consideration the installation angle of the transmitting antenna 25 (and the receiving antenna 31) in the sensor 5. Based on the result of the comparison, the calibration processing unit 17 can correct various parameters used for various processes.

The electronic device 2 according to the second embodiment may be provided with a predetermined reflector or the like in a radome or a housing of the sensor 5, for example. Here, the predetermined reflector may be stored in the storage unit 40 in advance with at least one of information such as an installation position and/or an angle thereof, and a reflectance of a material constituting the reflector. In this case, the electronic apparatus 2 of the second embodiment transmits a transmission wave, such as the chirp signal c3 shown in fig. 14, from the transmission antenna 25, and receives a reflected wave reflected by the predetermined reflector from the reception antenna 31. The calibration processing unit 17 may compare the beat signal digitized by the AD conversion unit 35 with information of a known object (predetermined reflector) stored in the storage unit 40. Here, the calibration processing unit 17 may compare the trajectory (known data) of the object to be detected with the trajectory of the object to be detected in the first place, taking into consideration the installation angle of the transmitting antenna 25 (and the receiving antenna 31) in the sensor 5. Based on the result of the comparison, the calibration processing unit 17 can correct various parameters used for various processes.

In this way, the electronic device 2 of the second embodiment can perform the calibration process within a time of 1 frame, for example. In addition, the electronic device 2 of the second embodiment may perform the calibration process for each frame or each sub-frame in each time, for example. As described above, when the calibration process is repeatedly performed, various statistical processes such as averaging for each process result can be performed. According to such statistical processing, it can be expected that the detection accuracy by the radar function of the electronic device 2 is gradually improved by repeating the calibration processing. In addition, in performing such statistical processing, a detection result that can be regarded as noise can be excluded.

As described above, in the electronic device 2 according to the second embodiment, the control unit 10 sets at least one of a plurality of ranges in which the object is detected by the transmission signal and the reception signal in the frame of the transmission wave. In the electronic device 2 according to the second embodiment, the control unit 10 may include a signal for calibration in the frame. In the electronic device 2 according to the second embodiment, the control unit 10 may perform calibration using the signal included in the frame.

According to the electronic apparatus 2 of the second embodiment, for example, even if the mounting angle of the sensor 5 to the mobile body varies, detection by radar can be performed and calibration can be performed. Therefore, according to the electronic device 2 of the second embodiment, the error due to the deviation can be corrected. In addition, according to the electronic device 2 of the second embodiment, even if a variation with aged deterioration or the like occurs in the sensor 5, for example, detection by radar can be performed and calibration can be performed. Therefore, according to the electronic device 2 of the second embodiment, the error due to the deviation can be corrected.

In the second embodiment described above, a case is assumed and described where the arrival angle θ on a plane (for example, in the XY plane shown in fig. 1) is calibrated by the calibration processing performed by the electronic apparatus 2. That is, the electronic device 2 can calibrate the installation angle of the transmission antenna 25 (and the reception antenna 31) in the sensor 5 based on the detected arrival angle θ. However, in the second embodiment, the electronic device 2 may perform other calibrations. For example, in the second embodiment, the electronic apparatus 2 may calibrate the installation angle of the transmission antenna 25 (and the reception antenna 31) in the sensor 5 in the vertical direction (for example, in the Z-axis direction shown in fig. 1). In addition, the electronic device 2 of the second embodiment may perform calibration, for example, based on the position of the detected object and/or the relative speed with the detected object, where possible. In addition, for example, in the second embodiment, the electronic device 2 may calibrate the power of the transmission wave transmitted from the transmission antenna 25.

(third embodiment)

Next, an electronic device according to a third embodiment will be described.

The electronic apparatus according to the third embodiment may have the same configuration as the electronic apparatus 1 according to the first embodiment shown in fig. 2 or the electronic apparatus 1 according to the second embodiment shown in fig. 13. Therefore, hereinafter, the same or similar explanation as that explained in fig. 2 or fig. 13 is appropriately simplified or omitted.

In the first and second embodiments described above, it is assumed that the units are sequentially repeated in units of one or more frames (or subframes, etc.). For example, in the example shown in fig. 8, the first 3 frames may be sequentially repeated after the first 3 frames in units of 3 frames (from frame 1 to frame 3). In the example shown in fig. 9, the first 3 subframes may be sequentially repeated after the first 3 subframes in units of 3 subframes (from subframe 1 to subframe 3). In addition, in the example shown in fig. 10, the first three chirp signals may be sequentially repeated thereafter in units of three chirp signals (from chirp signal c1 to chirp signal c 3). In addition, in the example shown in fig. 12 and 14, the first frame may be sequentially repeated after the first frame in units of one frame including three chirp signals (from the chirp signal c1 to the chirp signal c 3).

In contrast, the electronic device of the third embodiment can configure the transmission signal in different ways in different frames. That is, the control unit 10 configures the transmission signal in the second frame of the plurality of frames of the transmission wave transmitted by the transmission antenna 25 to be different from the transmission signal in the first frame of the plurality of frames. Specifically, the transmission signal may be a chirp signal, for example. That is, the control section 10 may configure the chirp signal in the second frame in a manner different from the chirp signal in the first frame. Here, the first frame may be the first frame of a plurality of frames, or may be any frame of a plurality of frames. Here, the first frame and the second frame may be consecutive frames such as frame 1 and frame 2, for example. The first frame and the second frame may be discontinuous frames such as the frame 1 and the frame 10, for example. Here, the first frame is a frame before the second frame, and the second frame is a frame after the first frame. However, these orders may be reversed.

Hereinafter, a mode in which the control unit 10 of the electronic device according to the third embodiment configures a frame of a transmission wave will be described.

Fig. 15 is a diagram showing an example of a frame configuration in the third embodiment. That is, fig. 15 is a diagram illustrating an example in which the electronic device 1 of the third embodiment sets the object detection range in a frame. As shown in fig. 15, the control unit 10 of the electronic device according to the third embodiment may arrange the chirp signals in different manners in each frame, for example. In fig. 15, the function of the radar 1 is set in the chirp signal c 1. In fig. 15, the chirp signals c1 are arranged with a gap therebetween, that is, with a time interval therebetween. On the other hand, as shown in fig. 15, the transmission start timing of each chirp signal c1 differs in each frame. Therefore, the transmission end timing of each chirp signal c1 is also different in each frame. That is, the timings of the transmission signals (the frequency modulation signal c1) formed in frames 1 to 3 are different from each other.

In fig. 15, frame 3 may also be followed by a repeat from frame 1 to frame 3. In fig. 15, frame 3 may be followed by a frame constituting a chirp signal having a timing different from that of frame 1 to frame 3. In fig. 15, the frame 3 may be followed by a frame constituting a chirp signal having the same timing as any of the frames 1 to 3.

As described above, the control unit 10 of the electronic device according to the third embodiment may set the timing of the transmission signal configured in the second frame to be different from the timing of the transmission signal configured in the first frame.

According to the electronic apparatus of the third embodiment, when transmitting a transmission wave in a plurality of frames, it is avoided that a transmission signal of the same frequency is continuously transmitted at the same timing. In addition, the control unit 10 of the electronic device according to the third embodiment can make the timings of processing the signals different from each other by making the timings of the signals transmitted between the frames different from each other. Therefore, for example, even in a situation where a plurality of mobile bodies each carry the electronic apparatus according to the third embodiment and each travel at the closest distance, it is possible to reduce interference caused by transmission waves transmitted from each of the electronic apparatuses. In the future, it is considered that there are more and more moving objects of automobiles equipped with radars. Even in such a case, according to the electronic apparatus of the third embodiment, interference with another radar can be reduced. Therefore, according to the electronic apparatus of the third embodiment, it is possible to reduce deterioration of characteristics due to the influence of interference with other radars.

Fig. 16 is a diagram showing another example of the frame configuration in the third embodiment. As shown in fig. 16, the control unit 10 of the electronic device according to the third embodiment may arrange chirp signals in different orders in each frame, for example. In fig. 16, the function of the radar 1 is set in the chirp signal c1, the function of the radar 2 is set in the chirp signal c2, and the function of the radar 3 is set in the chirp signal c 3. In fig. 16, the chirp signals c1, c2, and c3 are arranged with a gap, that is, with a time interval. Such an interval may be set appropriately, or may not be set. On the other hand, as shown in fig. 16, the transmission order of the chirp signals c1, c2, and c3 differs in each frame. That is, the order of the transmission signals (chirp signals c1, c2, and c3) formed in frames 1 to 3 is different, respectively.

In the third embodiment, as shown in fig. 16, the chirp signal arranged in each frame may be not only an up-chirp like the chirp signals c1 and c2 but also a down-chirp like the chirp signal c 3. This may be the same in the first and second embodiments described above.

In fig. 16, frame 3 may also be followed by a repeat from frame 1 to frame 3. In fig. 16, frame 3 may be followed by a frame in which chirp signals having a different order from frame 1 to frame 3 are formed. In fig. 16, the frame 3 may be followed by a frame in which chirp signals having the same sequence as that of any of the frames 1 to 3 are formed.

As described above, the control unit 10 of the electronic device according to the third embodiment may set the order of the transmission signals formed in the second frame to be different from the order of the transmission signals formed in the first frame.

Even in this case, according to the electronic apparatus of the third embodiment, when transmitting the transmission waves in a plurality of frames, it is avoided that the transmission signals of the same frequency are continuously transmitted at the same timing. In addition, the control unit 10 of the electronic device according to the third embodiment can change the processing order of the signals by changing the order of the signals transmitted between frames. Therefore, according to the electronic apparatus of the third embodiment, interference with other radars can be reduced. Therefore, according to the electronic apparatus of the third embodiment, it is possible to reduce deterioration of characteristics due to the influence of interference with other radars.

Fig. 17 is a diagram showing another example of the configuration of a frame in the third embodiment. As shown in fig. 17, the control section 10 of the electronic apparatus according to the third embodiment may arrange chirp signals in different combinations in each frame, for example. In fig. 17, the function of the radar 1 is set in the chirp signal c1, the function of the radar 2 is set in the chirp signal c2, the function of the radar 3 is set in the chirp signal c3, and the function of the radar 4 is set in the chirp signal c 4. In fig. 17, the chirp signals c1, c2, c3, and/or c4 are arranged with a gap, that is, a time interval, therebetween. Such an interval may be set appropriately, or may not be set. On the other hand, as shown in fig. 17, the transmission combinations of the chirp signals c1, c2, c3, and/or c4 are made different in each frame. That is, combinations of the transmission signals (chirp signals c1, c2, c3, and/or c4) configured in frames 1 to 3 are respectively different.

In fig. 17, frame 3 may be followed by a repeat from frame 1 to frame 3. In fig. 17, frame 3 may be followed by a frame in which a chirp signal having a different combination from that of frame 1 to frame 3 is formed. In fig. 17, the frame 3 may be followed by a frame in which a chirp signal having the same combination as that of any one of the frames 1 to 3 is formed.

As described above, the control unit 10 of the electronic device according to the third embodiment may make the combination of the transmission signals configured in the second frame different from the combination of the transmission signals configured in the first frame.

Even in this case, according to the electronic apparatus of the third embodiment, when transmitting the transmission waves in a plurality of frames, it is avoided that the transmission signals of the same frequency are continuously transmitted at the same timing. In addition, the control unit 10 of the electronic apparatus according to the third embodiment can make the processing combination of the signals different by making the combination of the signals transmitted between the frames different. Therefore, according to the electronic apparatus of the third embodiment, interference with other radars can be reduced. Therefore, according to the electronic apparatus of the third embodiment, it is possible to reduce deterioration of characteristics due to the influence of interference with other radars.

Fig. 18 is a diagram showing another example of the frame configuration in the third embodiment. As shown in fig. 18, the control section 10 of the electronic apparatus according to the third embodiment may configure the chirp signal at different timings, in different orders, and/or in different combinations, for example, in each frame. In fig. 18, the function of the radar 1 is set in the chirp signal c1, the function of the radar 2 is set in the chirp signal c2, and the function of the radar 3 is set in the chirp signal c 3. As shown in fig. 18, the control unit 10 of the electronic device according to the third embodiment can appropriately arrange a chirp signal (signal for calibration) for performing calibration processing in each frame, as in the electronic device 2 according to the second embodiment.

In fig. 18, the chirp signal used for the calibration process (signal used for calibration) is shown as a calibration-use chirp signal cc. In fig. 18, one chirp signal cc for calibration is arranged in all frames from frame 1 to frame 3. However, the number of the chirp signals cc for calibration may be arbitrary in each frame. For example, in the example shown in fig. 18, two or more calibration chirp signals cc may be arranged in the frame 1. In the example shown in fig. 18, the chirp signal cc for calibration may be arranged not in the frame 1 but in the frame 2 and thereafter.

In fig. 18, the chirp signal cc for calibration is arranged in all frames from frame 1 to frame 3. However, the chirp signal cc for calibration may be arranged every 1 frame, for example. The chirp signal cc for calibration may be arranged at an arbitrary frame interval, for example, every 5 frames or every 10 frames. The calibration chirp signals cc may be arranged at random frame intervals, instead of being arranged regularly at every predetermined 5 frames.

In fig. 18, the chirp signals c1, c2, c3 and/or the calibration chirp signal cc are arranged with a gap, that is, a time interval, therebetween. Such an interval may be set appropriately, or may not be set. On the other hand, as shown in fig. 18, the chirp signals c1, c2, c3 and/or the calibration chirp signal cc are transmitted in different combinations in each frame. That is, combinations of the transmission signals (chirp signals c1, c2, c3, and/or calibration chirp signals cc) formed in frames 1 to 3 are different from each other.

As shown in fig. 18, in frame 1, the chirp signals c1, c2 and the chirp-for-alignment signal cc are densely arranged in a temporally early region of the frame. In frame 2, the chirp signal c2 is located in an earlier region in the frame, and the chirp signal c3 and the chirp signal cc for calibration are densely located in a later region in the frame. In frame 3, the chirp signal cc for calibration, and the chirp signals c1 and c3 are arranged at substantially equal time intervals in the frame.

In fig. 18, frame 3 may also be followed by a repeat from frame 1 to frame 3. In fig. 18, frame 3 may be followed by a frame in which chirp signals having a different combination from frame 1 to frame 3 are formed. In fig. 18, the frame 3 may be followed by a frame in which a chirp signal having the same combination as that of any one of the frames 1 to 3 is formed.

As described above, the control unit 10 of the electronic device according to the third embodiment may make the configuration of the transmission signal configured in the second frame different from the configuration of the transmission signal configured in the first frame. The control unit 10 of the electronic device according to the third embodiment may perform calibration using a transmission signal included in at least one of a plurality of frames of a transmission wave.

Even in this case, according to the electronic apparatus of the third embodiment, when transmitting the transmission waves in a plurality of frames, it is avoided that the transmission signals of the same frequency are continuously transmitted at the same timing. Therefore, according to the electronic apparatus of the third embodiment, interference with other radars can be reduced. Therefore, according to the electronic apparatus of the third embodiment, it is possible to reduce deterioration of characteristics due to the influence of interference with other radars. The control unit 10 of the electronic device according to the third embodiment can perform calibration using a transmission signal included in at least one of a plurality of frames of a transmission wave. Therefore, the control unit 10 of the electronic apparatus according to the third embodiment can correct errors due to the initial variation, the aged variation, and the like, as in the electronic apparatus 2 according to the second embodiment.

The electronic device of the third embodiment configures the transmission signal differently for each frame. In this case, the electronic device according to the third embodiment may have a configuration in which the transmission signal is configured differently for each of a plurality of predetermined frames, and then the electronic device returns to the first frame to repeat the transmission of the signal. On the other hand, the electronic device of the third embodiment may also constitute the transmission signal in a different manner for each of a predetermined number of frames. In this case, the electronic apparatus according to the third embodiment forms a transmission signal differently for each of a predetermined number of frames among a predetermined plurality of frames, and then returns to the first frame to repeat the formation of the transmission signal. The electronic device according to the third embodiment may be configured to insert a transmission signal having a scheme different from that of only 1 frame for each of a predetermined number of frames having the same configuration. In addition, the electronic apparatus of the third embodiment can avoid a configuration in which all frames of the predetermined plurality of frames are the same. In short, the electronic device according to the third embodiment can avoid a configuration in which all frames are identical for a relatively long period.

Although the present disclosure has been described based on the drawings and the embodiments, it should be noted that various changes or modifications based on the present disclosure are easy to be made by those skilled in the art. Therefore, it should be noted that these variations or modifications are included in the scope of the present disclosure. For example, functions and the like included in the respective functional sections can be reconfigured in a logically non-contradictory manner. A plurality of functional sections and the like may be combined into one or divided. The embodiments of the present disclosure described above are not limited to being implemented as faithful to the embodiments described above, and may be implemented by appropriately combining the respective features or omitting a part thereof. That is, various changes and modifications of the present disclosure may be made by those skilled in the art based on the present disclosure. Accordingly, such variations and modifications are intended to be included within the scope of the present disclosure. For example, in each embodiment, each functional unit, each step, and the like may be added to or replaced with each functional unit, each step, and the like of the other embodiments without being logically contradicted. In each embodiment, a plurality of functional units, steps, and the like may be combined into one or divided. The embodiments of the present disclosure are not limited to the embodiments described above, and may be implemented by appropriately combining the features or omitting some of them.

For example, in the above embodiment, a description has been given of a mode in which the object detection range is dynamically switched by one sensor 5. However, in an embodiment, object detection may be performed in the determined object detection range by a plurality of sensors 5. In addition, in one embodiment, the beamforming may be performed by a plurality of sensors 5 toward the determined object detection range.

The above embodiments are not limited to the implementation as the electronic device 1. For example, the above embodiments may also be implemented as a control method of an apparatus such as the electronic apparatus 1. Further, for example, the above-described embodiments may also be implemented as a control program of an apparatus such as the electronic apparatus 1.

The electronic device 1 according to an embodiment may include, for example, at least a part of only one of the sensor 5 and the control unit 10 as a minimum configuration. On the other hand, the electronic apparatus 1 of an embodiment may be configured to appropriately include at least any one of the signal generating section 21, the synthesizer 22, the phase control section 23, the amplifier 24, and the transmission antenna 25 shown in fig. 2 in addition to the control section 10. In addition, the electronic apparatus 1 of an embodiment may be configured to include at least any one of the reception antenna 31, the LNA32, the mixer 33, the IF section 34, and the AD conversion section 35 in place of or together with the above-described functional section as appropriate. Further, the electronic apparatus 1 of an embodiment may be configured to include the storage section 40. As described above, the electronic apparatus 1 according to an embodiment can adopt various configurations. In addition, when the electronic apparatus 1 according to one embodiment is mounted on the mobile body 100, at least one of the above-described functional units may be provided at an appropriate position such as inside the mobile body 100. On the other hand, in one embodiment, for example, at least one of the transmission antenna 25 and the reception antenna 31 may be provided outside the mobile body 100

In the above-described embodiment, the case where different types of radar functions are set (allocated) for each frame of the transmission wave T or the like is described with reference to fig. 8 to 10, but the present disclosure is not limited to this case. For example, the control section 10 may set any one of a plurality of ranges in which an object is detected by transmitting and receiving a signal, based on a frame, a portion (e.g., a sub-frame) constituting the frame, and a chirp signal, or any combination thereof.

Description of reference numerals

1: electronic device

5: sensor with a sensor element

10: control unit

11: distance FFT processing unit

12: speed FFT processing unit

13: arrival angle estimating unit

14: object detection unit

15: detection range determining section

16: parameter setting unit

20: transmitting part

21: signal generation unit

22: synthesizer

23: phase control unit

24: amplifier with a high-frequency amplifier

25: transmitting antenna

30: receiving part

31: receiving antenna

32：LNA

33: frequency mixer

34: IF section

35: AD converter

40: storage unit

50：ECU

100: moving body

200: object