阅读说明：本技术 一种小型化24GHz毫米波雷达传感器 (Miniaturized 24GHz millimeter wave radar sensor ) 是由 盛庆华 周超宇 陈志刚 李贺贺 李竹 于 2020-05-20 设计创作，主要内容包括：本发明公开了一种小型化24GHz毫米波雷达传感器,包括发射天线阵列、接收天线阵列、发射机、接收机、滤波器、放大器、分频器和温度传感器,其中,所述发射天线阵列与发射机相连接,所述发射机与分频器和接收机分别连接,所述接收机与接收天线阵列和滤波器分别连接,所述滤波器还与放大器相连接,所述发射机、接收机、分频器和温度传感器组成单片微波集成电路；所述发射天线阵列和接收天线阵列分布于单片微波集成电路的两侧,整体传感器形状呈长方形。本发明实现直接连接常见的RISC单片机无需任何外部电路,最高可以达到毫米级别的距离分辨能力,具有体积小、低功耗、低成本的优势。(The invention discloses a miniaturized 24GHz millimeter wave radar sensor which comprises a transmitting antenna array, a receiving antenna array, a transmitter, a receiver, a filter, an amplifier, a frequency divider and a temperature sensor, wherein the transmitting antenna array is connected with the transmitter, the transmitter is respectively connected with the frequency divider and the receiver, the receiver is respectively connected with the receiving antenna array and the filter, the filter is also connected with the amplifier, and the transmitter, the receiver, the frequency divider and the temperature sensor form a single-chip microwave integrated circuit; the transmitting antenna array and the receiving antenna array are distributed on two sides of the single-chip microwave integrated circuit, and the whole sensor is rectangular. The invention realizes the direct connection with the common RISC singlechip without any external circuit, can reach the distance resolution capability of millimeter level at most, and has the advantages of small volume, low power consumption and low cost.)

1. A miniaturized 24GHz millimeter wave radar sensor is characterized by comprising a transmitting antenna array, a receiving antenna array, a transmitter, a receiver, a filter, an amplifier, a frequency divider and a temperature sensor, wherein the transmitting antenna array is connected with the transmitter, the transmitter is respectively connected with the frequency divider and the receiver, the receiver is respectively connected with the receiving antenna array and the filter, the filter is also connected with the amplifier, and the transmitter, the receiver, the frequency divider and the temperature sensor form a single-chip microwave integrated circuit; the transmitting antenna array and the receiving antenna array are distributed on two sides of the single-chip microwave integrated circuit, and the whole sensor is rectangular.

2. The sensor of claim 1, further comprising a metal frame disposed at an outer edge of the whole, and further comprising two chamfers disposed at two ends of the metal frame on the same side as the long side.

3. The sensor of claim 1, further comprising a first pin and a second pin, each of which is centrally located on opposite sides of the long side of the sensor.

4. The sensor of claim 1, wherein the amplifier is located between the monolithic microwave integrated circuit and the second pin and between the transmit antenna array and the receive antenna array.

5. The sensor of claim 1, wherein the transmit antenna array and the receive antenna array each employ a four-element structure.

6. The sensor of claim 5, wherein the transmit antenna array comprises a first array element, a second array element, a third array element and a fourth array element, the first array element and the second array element connected in series are connected in parallel with the third array element and the fourth array element connected in series, the horizontal spacing between the first array element and the second array element is equal to the horizontal spacing between the third array element and the fourth array element, and the vertical spacing between the first array element and the third array element is equal to the vertical spacing between the second array element and the fourth array element.

7. The sensor of claim 6, wherein a transmitting port is disposed between the transmitting antenna array and the monolithic microwave integrated circuit, a receiving port is disposed between the receiving antenna array and the monolithic microwave integrated circuit, and both the transmitting port and the receiving port are of a CPWG coplanar waveguide structure.

8. The sensor of claim 7, further comprising a main branch and a first branch, wherein the transmission port is connected to the first array element and the second array element in series via the main branch and the first branch.

9. The sensor of claim 7, further comprising a main branch and a second branch, wherein the transmitting port is connected to a third array element and a fourth array element connected in series via the main branch and the second branch.

10. The sensor of claim 8, wherein a first impedance matching junction is disposed on the first branch.

Technical Field

The invention belongs to the field of microwave radar sensors, and relates to a miniaturized 24GHz millimeter wave radar sensor.

Background

Radar is an object detection system that utilizes radio waves to determine the range, angle or velocity of a moving object. The radar system captures the reflected wave of any measured target in the path of the transmitted signal by the electromagnetic wave generated by the transmitter through the transmitting antenna and the receiving antenna (which are independent or the previous one), and the receiving, the analysis and the processing of the signal are completed by the receiver and the processor.

FMCW (frequency Modulated Continuous wave) frequency Modulated Continuous wave. The transmitted wave is a high-frequency continuous wave, and the frequency of the high-frequency continuous wave changes along with the time according to the triangular wave rule. The change law of the frequency of the echo received by the radar is the same as that of the transmitted frequency, and the change law is a triangular wave law with a time difference. After FFT processing is carried out on the intermediate frequency signal by using an FPGA or a DSP, the distance of a measured target can be accurately obtained through the frequency of the difference frequency signal on the power spectrum, and all objects reflecting electromagnetic waves can be reflected on the power spectrum. By tracking the change of each frequency value, the motion speed and the motion state of the object can be judged.

FSK (Frequency-shift keying) Frequency shift keying. The transmitted signal changes under two or more frequencies, the receiving and transmitting frequencies are still synchronous, so that the radar can still be regarded as a fixed-frequency radar within a short time, the frequency received by the radar is Doppler frequency shift generated due to relative motion between the object to be measured and the radar module, and the motion speed of the object to be measured can be accurately obtained from the frequency after the intermediate-frequency signal is subjected to FFT. But the transmitted signal frequency is constantly changing over a longer period of time, which may suppress bursty interference at the operating frequency, or continuous interfering signals of small bandwidth.

In recent years, with the rapid development of radio frequency and microwave technologies, radar systems are gradually miniaturized, and civil radars are gradually popularized, wherein a 24GHz frequency band is commonly used for medium-distance and short-distance applications. The application scenes of the civil radar mainly focus on severe rain and fog environments, places with privacy emphasis, dark environments or non-contact speed and distance measurement, such as automobiles, unmanned aerial vehicles, flow meters and the like.

Disclosure of Invention

To solve the above problems, the present invention is directed to provide a short-range radar sensor for measuring distance and speed information of a moving object in a space, which further improves the integration of the millimeter wave radar sensor, and at the same time reduces the use threshold of the 24GHz millimeter wave radar sensor, so that a user can perform various debugging modes, such as CW, FMCW, FSK, etc., on the sensor to determine the priority of distance and speed in actual measurement through different modulation modes without additional hardware cost increase.

The 24GHz millimeter wave radar sensor provided by the invention uses an ISM frequency band near 24GHz, can be used in the global range, has no radio supervision obstacle, can provide at least 2 times of sensitivity improvement and 1.5 times of detection range improvement compared with similar competitive products, and has lower power consumption and smaller sensor size.

The technical scheme of the invention is as follows: a miniaturized 24GHz millimeter wave radar sensor comprises a transmitting antenna array, a receiving antenna array, a transmitter, a receiver, a filter, an amplifier, a frequency divider and a temperature sensor, wherein the transmitting antenna array is connected with the transmitter, the transmitter is respectively connected with the frequency divider and the receiver, the receiver is respectively connected with the receiving antenna array and the filter, the filter is also connected with the amplifier, and the transmitter, the receiver, the frequency divider and the temperature sensor form a single-chip microwave integrated circuit; the transmitting antenna array and the receiving antenna array are distributed on two sides of the single-chip microwave integrated circuit, and the whole sensor is rectangular.

Preferably, still include the metal frame, set up at holistic outward flange, still include two chamfers, set up the long limit homonymy both ends at the metal frame.

Preferably, the sensor further comprises a first pin and a second pin which are respectively positioned at the center positions of the opposite sides of the long edge of the sensor.

Preferably, the amplifier is located between the monolithic microwave integrated circuit and the second pin, and between the transmit antenna array and the receive antenna array.

Preferably, the transmitting antenna array and the receiving antenna array both adopt a four-array element structure.

Preferably, the transmit antenna array includes a first array element, a second array element, a third array element and a fourth array element, the first array element and the second array element connected in series are connected in parallel with the third array element and the fourth array element connected in series, a horizontal distance between the first array element and the second array element is equal to a horizontal distance between the third array element and the fourth array element, and a vertical distance between the first array element and the third array element is equal to a vertical distance between the second array element and the fourth array element.

Preferably, a transmitting port is arranged between the transmitting antenna array and the monolithic microwave integrated circuit, a receiving port is arranged between the receiving antenna array and the monolithic microwave integrated circuit, and both the transmitting port and the receiving port are of a CPWG coplanar waveguide structure.

Preferably, the antenna further comprises a main branch and a first branch, and the transmitting port is connected with the first array element and the second array element which are connected in series through the main branch and the first branch.

Preferably, the antenna further comprises a main branch and a second branch, and the transmitting port is connected with a third array element and a fourth array element which are connected in series through the main branch and the second branch.

Preferably, a first impedance matching section is arranged on the first branch.

Compared with the prior art, the invention has the following beneficial effects: firstly, the 24GHz millimeter wave radar sensor provided by the invention is a complete set of 24GHz millimeter wave front end, and integrates a transmitting antenna, a receiving antenna, a transmitter, a receiver, an amplifier, a filter, a frequency divider and a temperature sensor, in the structure, the transmitter, the receiver, the frequency divider and the temperature sensor are Integrated in an MMIC (Monolithic Microwave Integrated Circuit), the amplifier and the filter are positioned around the MMIC, the whole structure is adapted to the current mainstream RISC single chip microcomputer, and a user directly integrates the sensor in the existing product without any external auxiliary Circuit.

Secondly, the 24GHz millimeter wave radar sensor is integrally designed on the basis of RO4350B hydrocarbon ceramics with the thickness of 0.508mm, the required mechanical strength is guaranteed, meanwhile, the cost is effectively reduced, a metal frame for shielding is arranged at the edge of the sensor, and metallized through holes are distributed on the metal frame, so that the lateral interference is effectively reduced, and the formation of an array antenna directional diagram is facilitated;

and the two contact pins are positioned at the edges of the two long edges of the sensor, so that the mounting height and the parallelism of the sensor can be stably maintained, and the consistency of mass production is better ensured on the structure.

Finally, the transmitting antenna array and the receiving antenna array are of a four-array-element mixed feed structure, wherein four radiating array elements are fed uniformly in equal amplitude and in the same phase, the feed point of each array element has a certain insertion depth to match transmission line impedance, and the horizontal spacing and the vertical spacing of the four array elements are optimized reasonably, so that side lobes are combined with a main lobe, and compared with the prior art, the influence of the side lobes is eliminated.

Drawings

FIG. 1 is a block diagram of a miniaturized 24GHz millimeter wave radar sensor in accordance with an embodiment of the present invention;

FIG. 2 is a circuit layout diagram of a miniaturized 24GHz millimeter wave radar sensor in accordance with an embodiment of the present invention;

fig. 3 is a layout diagram of a transmitting end circuit of a miniaturized 24GHz millimeter wave radar sensor according to an embodiment of the present invention.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention more apparent, the present invention is described in further detail below with reference to the accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are merely illustrative of the invention and are not intended to limit the invention.

On the contrary, the invention is intended to cover alternatives, modifications, equivalents and alternatives which may be included within the spirit and scope of the invention as defined by the appended claims. Furthermore, in the following detailed description of the present invention, certain specific details are set forth in order to provide a better understanding of the present invention. It will be apparent to one skilled in the art that the present invention may be practiced without these specific details.

Referring to fig. 1-3, the miniaturized 24GHz millimeter wave radar sensor of the present invention includes a transmitting antenna array 1, a receiving antenna array 2, a transmitter 3, a receiver 4, a filter 5, an amplifier 6, a frequency divider 7, and a temperature sensor 8, wherein the transmitting antenna array 1 is connected to the transmitter 3, the transmitter 3 is connected to the frequency divider 7 and the receiver 4, the receiver 4 is connected to the receiving antenna array 2 and the filter 5, the filter 5 is further connected to the amplifier 6, and the transmitter 3, the receiver 4, the frequency divider 7, and the temperature sensor 8 constitute a monolithic microwave integrated circuit 14; the transmitting antenna array 1 and the receiving antenna array 2 are distributed on two sides of the monolithic microwave integrated circuit 14, and the whole sensor is rectangular.

The antenna also comprises a metal frame 15 which is arranged on the outer edge of the whole body, and metallized through holes are distributed on the metal frame 15, so that the lateral interference is effectively reduced, and the formation of an array antenna directional pattern is facilitated; the metal frame edge further includes two chamfers 1616 disposed at the same side of the metal frame 15.

The sensor also comprises a first pin 11 and a second pin 12 which are respectively positioned at the center positions of the opposite sides of the long edge of the sensor, so that the mounting height and the parallelism of the sensor can be stably maintained.

The amplifier 6 is located between the monolithic microwave integrated circuit 14 and the second pin 12, and between the transmit antenna array 1 and the receive antenna array 2.

The transmitting antenna array 1 and the receiving antenna array 2 both adopt a four-array element structure, the transmitting antenna array 1 comprises a first array element 26, a second array element 27, a third array element 28 and a fourth array element 29, the first array element 26 and the second array element 27 which are connected in series are connected in parallel with the third array element 28 and the fourth array element 29 which are connected in series, the horizontal distance between the first array element 26 and the second array element 27 is equal to the horizontal distance between the third array element 28 and the fourth array element 29, and the vertical distance between the first array element 26 and the third array element 28 is equal to the vertical distance between the second array element 27 and the fourth array element 29.

A transmitting port 18 is arranged between the transmitting antenna array 1 and the monolithic microwave integrated circuit 14, a receiving port is arranged between the receiving antenna array 2 and the monolithic microwave integrated circuit 14, and the transmitting port 18 and the receiving port are both in a CPWG coplanar waveguide structure.

The antenna further comprises a main branch 19 and a first branch 20, and the transmitting port 18 is connected with a first array element 26 and a second array element 27 which are connected in series through the main branch 19 and the first branch 20; and further comprises a main branch 19 and a second branch 21, and the transmitting port 18 is connected with a third array element 28 and a fourth array element 29 which are connected in series through the main branch 19 and the second branch 21. The main branch 19 has a characteristic impedance of 50 ohms and the first branch 20 and the second branch 21 have a characteristic impedance of 100 ohms.

A first impedance matching section 22 is arranged on the first branch 20, a second impedance matching section 23 is arranged on the second branch 21, and both are Taper matching sections, and a first snake-shaped phase shifter 24 is arranged on the first branch 20 and between the first array element 26 and the second array element 27; a second snake-shaped phase shifter 25 is arranged on the second branch 21 and between the third array element 28 and the fourth array element 29; so that the radiation phases of the two elements at the end of each branch, i.e. the second element 27 and the fourth element 29, are the same as the radiation phases of the two elements in the first section, i.e. the first element 26 and the third element 28, of each branch.

The receiving end on one side of the receiving antenna array has the same structure and principle as the transmitting end, and is not described in detail.

With the above arrangement, a serpentine phase shifter is respectively arranged between the first array element 26 and the second array element 27 and between the third array element 28 and the fourth array element 29 for adjusting the radiation phases of the second array element 27 and the fourth array element 29 to be respectively the same as the radiation phases of the first array element 26 and the third array element 28. Two array elements in the horizontal direction are fed in series, the impedance is matched by a first impedance matching node 22 and a second impedance matching node 23, a parallel feed structure formed by a first branch 20 and a second branch 21 is connected to a main branch 19, and a transmitting port 18 structure is transformed into a CPWG coplanar waveguide at the connection position of the main branch 19 and the monolithic microwave integrated circuit 14, so that the continuity of the impedance and the matching of the monolithic microwave integrated circuit 14 are ensured, and meanwhile, higher isolation is realized.

The 24GHz millimeter wave radar sensor generates a single-frequency signal with a frequency in a certain range near 24GHz through the voltage-controlled oscillator, the frequency of the single-frequency signal can be controlled by the modulation voltage of a user, and the user can detect the output of the frequency divider to know the frequency. A part of energy of a high-frequency signal generated by a voltage-controlled oscillator is radiated into space through a power amplifier and a transmitting antenna, the other part of energy is provided for a receiver as a local oscillation signal, electromagnetic waves are reflected by a small part if meeting a target in the process of air propagation, a reflected echo signal is intercepted by a receiving antenna to form an electric signal, the receiver always outputs the difference frequency and the difference phase between the local oscillation signal and the echo signal as a beat signal, the beat signal is processed by a user after passing through a filter and an amplifier, and the information such as the position, the speed and the like of the target in the space can be obtained by analyzing the frequency and the phase of the beat signal.

The above description is only for the purpose of illustrating the preferred embodiments of the present invention and is not to be construed as limiting the invention, and any modifications, equivalents and improvements made within the spirit and principle of the present invention are intended to be included within the scope of the present invention.