Automotive technology
Mwrf 8153 20b Thinkstockphotos 653513498 Promo 0
Mwrf 8153 20b Thinkstockphotos 653513498 Promo 0
Mwrf 8153 20b Thinkstockphotos 653513498 Promo 0
Mwrf 8153 20b Thinkstockphotos 653513498 Promo 0
Mwrf 8153 20b Thinkstockphotos 653513498 Promo 0

Count on Design Software for Millimeter-Wave Automotive Radar and Antenna System Development, Part 2

Feb. 2, 2018
No question, automotive radar technology is reaching new heights. This article, part 2 of a two-part series, explains how the latest software can facilitate antenna design for the radar systems needed for next-generation cars and trucks.

Download this article as a .PDF

Ongoing developments in advanced driver assistance systems (ADAS) are expanding the capabilities and affordability of vehicles that can alert and assist drivers using radar technology mostly focused over the 76-to-81 GHz spectrum. Part 1 provided an overview of ADAS systems and discussed various radar systems and architectures. Part 2 discusses multi-beam and multi-range design and examines antenna design for multiple-input, multiple-output (MIMO), and beam-steering technologies for 5G that will be useful for automotive safety in the future.

Multi-Beam/Multi-Range Design

A typical adaptive-cruise-control (ACC) stop-and-go system requires multiple short- and long-range radar sensors to detect nearby vehicles. The shorter-range radar typically covers up to 60 m with an angle coverage up to ±45°, allowing the detection of the vehicle’s adjacent lanes that may cut into the current travel lane. The longer-range radar provides coverage up to 250 m and an angle of ±5° to ±10° to detect vehicles in the same lane, further ahead.

To support multiple ranges and scan angles, module manufacturers such as Bosch, DENSO, and Delphi have developed and integrated multi-range, multi-detection functionality into increasingly capable and cost-sensitive sensors using multi-channel transmitter (TX)/receiver (RX) architectures (Fig. 1). These different ranges can be addressed with multi-beam/multi-range radar by employing radar technology such as frequency-modulated-continuous-wave (FMCW) and digital beamforming with antenna-array design.

1. This mid-range radar sensor from Bosch features three transmitters and four receivers. It supports horizontal field-of-views of 160m (±6°), 100m (±9°), and 60m (±10°) for the main antenna, as well as 36 m (±25°) and 12 m (±42°) for the elevation antenna. Photo Courtesy of System Plus Consulting. 

Antenna Design

A multi-modal radar for an ACC system1 based on an FMCW radar driving multiple antenna arrays is shown in Fig. 2. This multi-beam, multi-range radar with digital beamforming operates at both 24 and 77 GHz, utilizing two switching-array antennas to enable long-range, narrow-angle coverage (150 m, ±10°) and short-range, wide-angle coverage (60 m, ±30°). This example illustrates the use of multiple antenna-array systems, including multiple (5 × 12 element) series-fed patch arrays (SFPAs) for long-range, narrow-angle detection (77 GHz); a single SFPA (1 × 12 elements designed for 24 GHz) for short-range, wide-angle detection; and four (1 × 12) SFPAs for the receiver that was required for this type of system.

2. Shown is a multi-band, multi-range FMCW digital beam-forming ACC radar that utilizes six individual SFPAs.

Radar performance is greatly influenced by the antenna technology, which must consider electrical performance such as gain, beam width, range, and physical size for the particular application. The multiple, fixed TX/RX antenna arrays in the example radar were optimized for range, angle, and side-lobe suppression. A patch antenna is relatively easy to design and manufacture and will perform quite well when configured into an array, which results in an increase of overall gain and directivity.

The performance of a rectangular patch antenna design is controlled by the length, width, dielectric height, and permittivity of the antenna. The length of the single patch controls the resonant frequency, whereas the width controls the input impedance and the radiation pattern. By increasing the width, the impedance can be reduced. However, decreasing the input impedance to 50 Ω often requires a very wide patch antenna, which takes up a lot of valuable space. Larger widths can also increase the bandwidth, as does the height of the substrate.

The permittivity of the substrate controls the fringing fields with lower values, resulting in wider fringes and therefore better radiation. Decreasing the permittivity also increases the antenna’s bandwidth. The efficiency is also increased with a lower value for the permittivity.

Designing a single-patch antenna or array is made possible through the use of design software that utilizes electromagnetic (EM) analysis to accurately simulate and optimize performance. NI AWR Design Environment includes AXIEM 3D planar and Analyst 3D finite-element method simulators. In addition to simulating antenna performance such as near- and far-field radiation patterns, input impedance, and surface currents, these co-simulate directly with Visual System Simulator (VSS)—automatically incorporating the antenna simulation results into the overall radar system analysis without the need to manually export/import data between EM simulator and system design tools.

Both AXIEM and Analyst take the user-defined physical attributes of the antenna such as patch width and length, as well as the dielectric properties such as material and substrate height, to produce the electrical response. AXIEM is ideal for patch-antenna analysis, whereas Analyst is best suited for 3D structures such as modeling of a coaxial feed structure or finite dielectric (when proximity to the edge of a printed-circuit-board [PCB] would impact antenna performance; see Fig. 3).

3. This figure illustrates an example of an edge-coupled single-patch antenna optimized in AXIEM for center return loss and broadside gain to design frequency.

Figure 4 shows a patch-antenna array with corporate feed and 167 k unknowns solved in less than 6.5 minutes with a quad core.

4. Shown is an 8 × 16 patch-antenna array (128-element) with corporate feed (single-feed port) and 167 k unknowns (1.88 GHz) solved in approximately 6.5 minutes with quad core.

To determine the physical attributes that will yield the desired electrical response, antenna designers can use NI AWR software’s AntSyn antenna synthesis and optimization tool (Fig. 5). AntSyn enables users to specify the electrical requirements and physical size constraints of the antenna. The software explores a set of design configurations and determines the optimum structure based on proprietary genetic optimization and EM analysis. The resulting antenna geometry can then be imported in a dedicated planar or 3D EM solver, such as AXIEM or Analyst, for verification or further analysis/optimization.

5. This figure illustrates the AntSyn antenna synthesis specification interface and library of antenna types (a) and simulated results based on user-specified antenna requirements (b).

Planar elements can easily form array structures by combining very simple elements such as microstrip patches. Patches can be configured in a series such as the 1 × 8 patch array in Fig. 6, where each element is connected serially by a “tunable” section of transmission line. In this AXIEM project, the lengths and widths of each array element and the connecting transmission lines were defined with variables to allow optimization of the overall array performance.

6. The software allows for the optimization of a series-feed 1 × 8 patch array with parameterized modifiers.

The 1 × 8 array can be further expanded into an 8 × 8 array for a high-gain fixed-beam design (Fig. 7). This replicates the 8 × 8 element array reported in Ref. 2.

7. This is 77-GHz 8 × 8 antenna array. Parameters are N*λ/2 feeding with λ/2 < spacing < λ.

Within NI AWR Design Environment, arrays can be represented in VSS as a system behavioral block using the proprietary phased-array model that enables designers to specify the array configuration (number of elements, element spacing, antenna radiation pattern, impaired elements, gain tapering, and more) for a high-level understanding of array requirements for desired performance such as gain and side lobes. This approach is best for large-scale arrays (thousands of elements) and system designers developing basic requirements for the antenna array team.

8. Shown is a 4 × 4 patch-antenna array with individual ports for each element, enabling the feed structure (lower left) to be defined and co-simulated at the circuit/system level to monitor the changing antenna input impedance per element and control beam steering through the RF feed network.

The array could also be modeled in AXIEM or Analyst with the detailed physical array, specifying individual port feeds (Fig. 8) or a single feed if the feed network is also implemented in AXIEM/Analyst (Fig. 9).

9. This figure shows the simulation1 of published 8 × 8 patch array on RO4003C PCB, approximately 2.3 × 2.5 cm. Tree-structure corporate feeding paths guarantee that the overall radiation is constructive, resulting in an array with greater than 20 dBi gain over a 1-GHz bandwidth.

This approach enables the design team to investigate the interaction between the beam angle and the input impedance of each individual element, allowing RF front-end component designers to account for impedance loading effects on transceiver performance. This capability highlights the importance of having RF circuit, system, and EM co-simulation to accurately investigate circuit/antenna behavior before fabricating these complex systems.

MIMO and Beam-Steering Antenna Technologies

For road vehicles, a radar will receive unwanted backscatter off the ground and any large stationary objects in the environment, such as the sides of buildings and guardrails. In addition to direct-path reflections, there are also multipath reflections between scatterers, which can be used to mitigate the impact of clutter through the use of MIMO antennas.

A MIMO radar system uses a system of multiple antennas, with each transmit antenna radiating an arbitrary waveform independently of the other transmitting antennas. Each receiving antenna can receive these signals. Due to the different waveforms, the echo signals can be re-assigned to the single transmitter. An antenna field of N transmitters and a field of K receivers mathematically results in a virtual field of K·N elements, resulting in an enlarged virtual aperture that allows the designer to reduce the number of necessary array elements. MIMO radar systems thereby improve spatial resolution and provide a substantially improved immunity to interference. By improving the signal-to-noise ratio, the probability of detection of the targets is also increased.

VSS is able to implement user-specified MIMO algorithms and evaluate the overall performance as it relates to the channel model (Fig. 10). Users can simulate a highly-customizable multipath fading channel that includes channel path loss, the relative velocity between the transmitter and receiver, and the maximum Doppler spread. Supporting independent or continuous block-to-block operation, the channel can contain multiple paths (LOS, Rayleigh, Ricean, frequency shift) that can be individually configured in terms of their fading types, delays, relative gains, and other applicable features. This module can also simulate a receiver antenna array with user-defined geometry, enabling simulation of single-input, multiple-output (SIMO) systems.

10. VSS can implement user-specified MIMO SIMO algorithms.

Conclusion

Aside from becoming more sophisticated and reliable, ADAS systems will become more prevalent on most (if not all) vehicles in the not-too-distant future. Thanks to the similar advances in antenna-array and millimeter-wave technology that are occurring in 5G communications, most cars and trucks will be considerably safer than they are today. Advances in simulation technology—particularly in RF-aware circuit design, array modeling, and system-level co-simulation—will enable antenna designers and system integrators to optimize these systems for challenging size, cost, and reliability targets.

References

  1. Rohling, Hermann; Meinecke, Marc-Michael, “Waveform Design Principles for Automotive Radar Systems,” Technical University of Hamburg-Harburg/ Germany, Conference: Radar, 2001 CIE International Conference on, Proceedings /react-text.
  2. -H. Jeong, H.-Y. Yu, J.-E. Lee, et. al., “A Multi-beam and Multi-range Radar with FMCW and Digital Beam-forming for Automotive Applications,” Progress in Electromagnetics Research, Vol. 124, 285{299, 2012}.
  3. Jri Lee, Yi-An Li, Meng-Hsiung Hung, and Shih-Jou Huang, “A Fully-Integrated 77-GHz FMCW Radar Transceiver in 65-nm CMOS Technology,” IEEE Journal of Solid-State Circuits, Vol. 45, No. 12, December 2010.
  4. Bosch Mid Range Radar (MRR) Sensor reverse engineering & costing report.

     

Sponsored Recommendations

Frequency Modulation Fundamentals

March 14, 2024
The development of crystal-clear FM communications was an innovation of genius and toil. Utilized today in applications such as radar, seismology, telemetry and two-way radios...

44 GHz Programmable Signal Generator

March 14, 2024
The Mini-Circuits SSG-44G-RC is a 0.1 to 44 GHz signal source with an RF output range of -40 to +17 dBm with fine resolution. This model supports CW and pulsed (? 0.5 ?s) outputs...

50W SSPA with Built-In Signal Source & Control

March 14, 2024
The RFS-2G42G5050X+ takes Mini-Circuits robust line of solid state, connectorized, high-power amplifiers for RF energy to a new level by integrating the versatility of a signal...

Webinar: Introduction to OTA Measurement for mmWave and Sub-THz

Feb. 19, 2024
Join Jeanmarc Laurent, a leading expert from MilliBox, for an exclusive live webinar showcasing a complete Over-the-Air (OTA) testing system setup. In this immersive session, ...