NXP Blog Post: Revolutionizing Robotics

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NXP Blog Post: Revolutionizing Robotics

With NXP
May 16, 2024
4 min
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Advancements in Edge Processing, Power, Sensors and Communication

The mobile robotics industry is advancing rapidly thanks to technological improvements in sensors and electronics. As engineers integrate new technologies, all aspects of the mobile robotics ecosystem are evolving. Here’s a closer look at some significant trends driving processing, power, sensors and communication changes.

Blog post by Altaf Hussain, Director Industrial Segment Marketing for Transportation and Mobility, NXP Semiconductors

Edge Processing

Arm® launched the Cortex®-M family 20 years ago and the first microcontrollers hit the market two years later. Arm Cortex-based microcontrollers continue to push the industry forward with wider capabilities for low-power operation, high performance and exciting new peripherals.

NXP’s latest general-purpose MCUs, the MCX N series, are cutting edge in mobile robotics. These microcontrollers bring a neural processing unit (NPU) to the microcontroller level, offering machine learning (ML) acceleration. The eIQ® Neutron NPU supports a wide range of neural network types, including CNN, RNN, TCN, transformer networks and more, opening up new possibilities for the industry.

Edge computing is also seeing continuous improvement as microprocessors such as NXP’s new i.MX 9 series, which also includes an eIQ Neutron NPU among a wide range of powerful peripherals. functional safety is a major automotive and industrial mobile robotics consideration. Robotic systems can operate more safely with microprocessors featuring FuSa as a core principle now available.

Power

The commercialization of Gallium Nitride (GaN) has profoundly impacted the electronics industry, revolutionizing power electronics with its ability to deliver higher performance and significantly improved efficiency.

Motor drivers for mobile robots can be built into dramatically smaller volumes with much higher efficiency, resulting in longer battery life and reduced thermal management requirements.

The advantages of GaN also apply to switched-mode power converters. The rapid turn-on/turn-off speeds of GaN devices allow higher-frequency power converters allowing engineers to utilize smaller, lower-cost inductors and capacitors.

Exciting new battery chemistries are hitting the market and entering mass production. While it does not look like Lithium Polymer batteries will be removed from the top spot when it comes to power density, new battery technology is promising where this is less of a concern. Sodium-ion batteries may not have the same energy density but rely on far more naturally abundant metals. While Lithium has an uneven geographic distribution, high cost and high environmental impact, sodium is readily available in salt water.

Sodium-ion batteries do not require cobalt, nickel and copper for chemistries such as NaFeO2, further reducing cost while increasing material availability. Major battery manufacturers are investing heavily in increasing sodium-ion battery production capacity, which should result in lower battery costs that, in turn, can reduce the costs of mobile robots while increasing run times for applications less sensitive to volumetric energy density.

Sensors

Many mobile robotic platforms rely heavily on vision. As mentioned previously, microcontrollers and microprocessors with NPUs allow real-time inference and classification of images to improve a robot’s awareness of its environment.

The incredibly fast pulses possible with GaN devices also allow faster and higher-resolution 3D depth mapping with LiDAR. Robot navigation can take a major leap forward with advancements in Simultaneous Localization and Mapping (SLAM) algorithms. Once again, engineers can apply machine learning techniques to the 3D data environment for increased perception and decision-making capabilities.

As the robot’s situational awareness improves, so can its autonomy and capabilities outside tightly controlled environments.

Communication and Connectivity

Communication and connectivity play a crucial role in the advancement of mobile robotics. With the latest developments in wireless technologies, robots can now seamlessly communicate with other devices, systems and even humans. Integrating Wi-Fi, Bluetooth and 5G networks enable remote control, real-time data transmission and over-the-air updates, enhancing mobile robots’ flexibility and adaptability.

5G networks, with low latency and high bandwidth, are rapidly being rolled out worldwide. This technology opens up new possibilities for mobile robotics. Robots can now rely on cloud computing for resource-intensive tasks like complex data processing and decision-making while maintaining real-time responsiveness.

Mesh networking and swarm robotics are revolutionizing multi-robot collaboration. By establishing ad-hoc networks, robots can communicate and coordinate with each other, sharing information and tasks to achieve common goals. This capability enables the deployment of robot swarms in various applications, such as search and rescue, environmental monitoring and large-scale logistics.

Adopting IoT protocols, such as MQTT and CoAP, further facilitates the integration of mobile robots with other connected devices and systems.

Gear Up for the Future: Let Mobile Robotics Lead the Way to Exciting Innovations

The mobile robotics industry is experiencing rapid advancements driven by innovations in edge processing, power, sensors and communication technologies. The introduction of neural processing units in microcontrollers and microprocessors, coupled with the rise of GaN devices and new battery chemistries enable more efficient, intelligent and autonomous mobile robots.

Simultaneously, advancements in vision systems, SLAM algorithms and wireless connectivity enhance robots’ situational awareness and collaboration capabilities. As these trends continue to shape the industry, we can expect mobile robots to become increasingly versatile, adaptable and integrated into various aspects of our lives, revolutionizing industries and transforming how we live and work.

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