AI-driven robots are changing the future of robotics by making systems smarter, more adaptable, and autonomous. Autonomous robots, once a topic of futuristic works, are now on their way to mass production.
Modern robotics: CPUs, GPUs, and AI accelerators are required to process computer vision, motion planning, and control algorithms in real time.
Humanoid robots are rapidly evolving from conceptual prototypes to practical tools for various industries, thanks to advances in artificial intelligence, robotics, and substantial investments from major technology companies. This development is transforming sectors such as healthcare, industrial manufacturing, and personal assistance, thereby positioning humanoid robots as an integral part of the future workforce.
The growth of AI-driven robots is being driven by increasing demands in healthcare and manufacturing, as well as government initiatives. Humanoid robots are expected to offset four percent of the labor shortage in U.S. manufacturing by 2030 by taking on dirty, dangerous, or tedious tasks.
Gallery
By 2030, these robots could cover two percent of the global demand for elderly care workers, helping in areas where there is a shortage of caregivers. In sectors such as mining, disaster relief, and the chemical industry, humanoid robots could take over five to 15 percent of hazardous tasks, thereby increasing safety and efficiency.
By 2050, 63 million humanoid robots could be in use in the United States alone. Countries like Japan are relying on caregiver robots for their aging population, while China is expanding production for industrial automation.
The Labor Shortage Promotes Humanoid Robots
The integration of humanoid robots into various industries is driven by technological advancements and the need to address the labor shortage. Companies like Tesla have introduced the Optimus Gen 2.0 — the latest iteration of their humanoid robot, aimed at pushing the boundaries of automation in both industry and caregiving.
Boston Dynamics, known for its robots like Atlas, is capable of performing complex movements and pushing the boundaries of humanoid mobility and real-world applications. The San Diego-based company Ainos has announced a strategic partnership with the Japanese company Ugo to develop a robot with odor detection capabilities. As humanoid robots are expected to play a key role in addressing labor shortages and increasing efficiency across various industries, and significant market growth is anticipated in the coming years, their energy demand will also rise.
AI Hardware Platforms for Humanoid Robots
AI hardware platforms such as the Nvidia Jetson, Qualcomm's Dragonwing IQ9 series processor, and the Synaptics SL1680 provide powerful, energy-efficient computing power essential for real-time perception, motion planning, and decision-making in humanoid robots. Qualcomm's Dragonwing IQ9 series processor is a newly introduced high-performance platform for robotics and industrial applications with long service life. It offers industry-leading power efficiency for edge processing and up to 100 trillion operations per second (TOPS) within a highly integrated, thermally efficient system-on-chip (SoC) that also includes dedicated real-time processing cores to manage the safety-critical routines required for the safe operation of robots in close proximity to vulnerable individuals. The Dragonwing IQ9 series processor from Qualcomm also features a camera ISP (Image Signal Processor) capable of connecting up to 16 high-resolution cameras simultaneously. The SoC can leverage camera and sensor inputs for object detection, object recognition, path planning, and other critical tasks for robot navigation and decision-making. Additionally, the device's dedicated NPU is powerful enough to run language models like Llama2, enabling humans to interact naturally with their robots.
The Synaptics SL1680 is based on a 64-bit quad-core ARM Cortex-A73 CPU, a 7.9 TOPS NPU, a highly efficient, feature-rich GPU, and a multimedia accelerator pipeline. It is ideally suited for home and industrial controls, smart devices, home security gateways, digital signage, displays, point-of-sale systems, and scanners.
New Solutions for the Energy Requirements of SoCs for Humanoid Robots
Sophisticated AI architectures require advanced core power solutions to support their high computational performance and real-time processing. These systems necessitate multi-phase voltage regulation, dynamic power scaling, and low-noise, highly efficient power delivery to ensure performance stability. As AI workloads in humanoid robots become increasingly demanding, power delivery architectures must ensure thermal efficiency, fast power response, and seamless integration with AI accelerators to prevent bottlenecks or overheating.
The core computing unit is the heart of the system, as it performs calculations and determines which specific solutions are required for power rails. High-performance core rails have strict specifications to deliver the power needed by the CPUs, GPUs, and accelerators in the system-on-chip (SoC).
Power Supply Solutions for SoC Core Rails
Conventional solutions for SoC core rails use analog PWM controllers, discrete MOSFETs, and discrete current and temperature sensing circuits (Figure 1). These solutions require numerous external components, driving up costs, reducing reliability in certain applications, and demanding larger PCB space. This can complicate the development of conventional solutions and result in a lack of flexibility and scalability, which are critical requirements for the types of SoCs used in high-performance computing (HPC) applications.
Date: 08.12.2025
Naturally, we always handle your personal data responsibly. Any personal data we receive from you is processed in accordance with applicable data protection legislation. For detailed information please see our privacy policy.
Consent to the use of data for promotional purposes
I hereby consent to Vogel Communications Group GmbH & Co. KG, Max-Planck-Str. 7-9, 97082 Würzburg including any affiliated companies according to §§ 15 et seq. AktG (hereafter: Vogel Communications Group) using my e-mail address to send editorial newsletters. A list of all affiliated companies can be found here
Newsletter content may include all products and services of any companies mentioned above, including for example specialist journals and books, events and fairs as well as event-related products and services, print and digital media offers and services such as additional (editorial) newsletters, raffles, lead campaigns, market research both online and offline, specialist webportals and e-learning offers. In case my personal telephone number has also been collected, it may be used for offers of aforementioned products, for services of the companies mentioned above, and market research purposes.
Additionally, my consent also includes the processing of my email address and telephone number for data matching for marketing purposes with select advertising partners such as LinkedIn, Google, and Meta. For this, Vogel Communications Group may transmit said data in hashed form to the advertising partners who then use said data to determine whether I am also a member of the mentioned advertising partner portals. Vogel Communications Group uses this feature for the purposes of re-targeting (up-selling, cross-selling, and customer loyalty), generating so-called look-alike audiences for acquisition of new customers, and as basis for exclusion for on-going advertising campaigns. Further information can be found in section “data matching for marketing purposes”.
In case I access protected data on Internet portals of Vogel Communications Group including any affiliated companies according to §§ 15 et seq. AktG, I need to provide further data in order to register for the access to such content. In return for this free access to editorial content, my data may be used in accordance with this consent for the purposes stated here. This does not apply to data matching for marketing purposes.
Right of revocation
I understand that I can revoke my consent at will. My revocation does not change the lawfulness of data processing that was conducted based on my consent leading up to my revocation. One option to declare my revocation is to use the contact form found at https://contact.vogel.de. In case I no longer wish to receive certain newsletters, I have subscribed to, I can also click on the unsubscribe link included at the end of a newsletter. Further information regarding my right of revocation and the implementation of it as well as the consequences of my revocation can be found in the data protection declaration, section editorial newsletter.
Figure 2 shows a state-of-the-art SoC core power solution with digital multiphase controllers and monolithic DrMOS power stages. The DrMOS integrates the gate driver IC, current sensing circuit, and temperature sensing circuit. This allows for a simpler solution by eliminating multiple external components that would be required in traditional solutions.
The DrMOS is a monolithic design with incredibly high power density, offering precise current sensing and accurate on-die temperature sensing. MPS provides a 22V and a 6V DrMOS portfolio to support single-stage and two-stage power conversion. The MPQ86760, for example, is a DrMOS from the 6V portfolio, well-suited for SoCs used in autonomous driving and infotainment. The MPQ86960, on the other hand, is a DrMOS from the 22V portfolio and can be used in humanoid robots.
Figure 3 shows a DrMOS that, combined with MPS's multi-phase controllers, can supply power rails from 30A to 80A (and even higher under certain conditions). This combination of a DrMOS and a dedicated controller can be used to efficiently regulate the core power rail of the SoC in a humanoid robot while delivering high currents in a compact design.
These digital controllers offer flexibility and scalability, as the number of phases can be configured depending on the current requirements of the respective SoC core rail. Digital controllers do not require external compensation of the feedback loop, simplifying the design process and reducing development time. They also feature non-volatile memory (NVM), allowing register settings to be configured and reconfigured up to 1000 times. Additionally, the controller and DrMOS provide various monitoring and protection functions that can be used to implement system-level telemetry.
SoC Power Supply for Humanoid Robots
Modern robot platforms use either a 48V or a 22V lithium-ion battery. A 48V lithium-ion battery is becoming the standard high-voltage rail for full-sized humanoid robots. MPS provides solutions to efficiently step down both 48V and 22V to deliver the necessary voltage for the core rails.
Figure 3 shows a block diagram of a highly efficient power supply system for a robotics SoC. A battery is routed through the front-end protection to two digital MPQ2967 controllers. Each controller then configures and manages 4 MPQ86960 DrMOS stages in multi-phase configurations. This ensures the supply of four power rails ranging from 30A to 80A. The multi-phase operation improves efficiency, current sharing, and thermal distribution. The controllers can communicate with the SoC via the I2C interface or any other standard interface supported by our controllers. This setup is ideal for high-performance robots requiring a compact and reliable power supply.
The Future of Robotics Requires Powerful Power Supply Systems
The robotics industry is shifting from decentralized controls to centralized high-performance computing platforms. Modern robots use CPUs, GPUs, and AI accelerators to process computer vision, motion planning, and control algorithms in real time. This shift necessitates powerful low-voltage and high-current power supply systems. SoCs used in central data processing require advanced power management solutions, especially for core voltage rails. Traditional power supply solutions are no longer suitable for the next generation of power delivery applications for central computing. With multi-phase digital controllers like the MPQ2967 and DrMOS power stages like the MPQ86960 employed in robot SoC core power applications, scalable, flexible, and compact power supply solutions with high efficiency and fast transient response can be provided. (mk)
*Thomas Berner is Product Marketing Manager at Codico, Shivani Saravanan is Product Marketing Manager at MPS.
:quality(80)/p7i.vogel.de/wcms/88/53/8853f7df2fe47a3d2c6f1879f6ac38e6/newsimage417073-1500x843v1v1.jpeg "Measuring setup for friction stir welding: Modular acoustic measuring system with flexibly positioned microphones for recording tool wear and process deviations in real time. (Image:Fraunhofer IDMT)")
:quality(80)/p7i.vogel.de/wcms/28/75/28751a17e2bcca46e53a1e7b8a84c433/schmersal-tiepner-029-6749x3796v1v1.jpeg "Tiepner's compact system produces ID cards made of laminated plastic, which are used as customer cards, ID cards or cheque cards, among other things. Left in the picture: Christian Höltge, Managing Director of Tiepner GmbH. (Image:Tiepner GmbH)")
:quality(80)/p7i.vogel.de/wcms/68/44/6844f9ae752767034c525d8dcdffe13e/0129139999v1.jpeg "Won-jong Kim, CEO of DN Solutions, and Dr. Thorsten Schmidt, CEO of the Heller Group, agree: \"This strategic partnership strengthens the position of both companies in precision technology.\" (Image:Heller)")
:quality(80)/p7i.vogel.de/wcms/c1/5b/c15b198344a31c237d35f919235fa73e/blechnext-20maas-1161x653v1v1.png "Blechnext offers sheet metal processors the Machine-as-a-Service partner model with a Tru Laser Center 7030 from Trumpf. (Image:Blechnext)")
:quality(80)/p7i.vogel.de/wcms/ba/a0/baa0c49f17909b10766fb582d1f8b531/sandvik-olp-case-study-hero-1377x774v1v1.png "With Visual Components' offline programming software, Sandvik has more than halved robot programming time, improved welding quality and repeatability, and increased robot cell utilization. (Image:Visual Components)")
:quality(80)/p7i.vogel.de/wcms/29/1e/291eaf788c2befc4d71686cd260fef3b/0129214102v1.jpeg "RobCo's robots consist of flexibly combinable hardware modules and use AI software for learning. (Image:RobCo)")
:quality(80)/p7i.vogel.de/wcms/de/75/de750a367b39ed3167210c6941b067b6/0129059153v1.jpeg "Figure 1: Preparation for the Cyber Resilience Act. By December 2027, device manufacturers must have implemented a series of mandatory measures. (Image:Microchip)")
:quality(80)/p7i.vogel.de/wcms/e6/e0/e6e0dae794b9068953f24ace08b6b0ca/0113143253v1.jpeg "In our China Market Insider, we regularly provide you with relevant information directly from China. (Image:© Eisenhans - stock.adobe.com)")
:quality(80)/p7i.vogel.de/wcms/0e/52/0e52ee794e7d24f8ddcb3e230f192e08/wscad-electrix-ai-2026-fill-cabinet-04-zoom-en-1720x967v1v1.png "The use of artificial intelligence makes it possible to systematically automate enclosure planning for the first time. This brings a number of advantages. (Image:WSCAD)")
:quality(80)/p7i.vogel.de/wcms/08/7e/087e5cbeb0039395c8759c8fdb54e24c/0129120874v1.jpeg "Digital consistency: Using Fresenius as an example, the article shows how companies benefit from integrated development processes. (Image:Fresenius Medical Care)")
:quality(80)/p7i.vogel.de/wcms/3d/63/3d637efb6dfefc529f08738bab2dc968/adobestock-1271004590--c2-a9-20the-20pixel-20store-20-e2-80-93-20stock-adobe-com-ki-generiert-2787x1568v1v1.jpeg "We present three innovations from the PLM and ALM world. (Image:The Pixel Store stock.adobe.com AI-generated)"){kind=tracking}
:quality(80)/p7i.vogel.de/wcms/59/37/5937b916a3d8bcbe2984391be7c18d8e/0129152959v1.jpeg "Mathworks and dSpace deepen their partnership: Road models created with RoadRunner can now be used directly in ASM OpenX. (Image:dSpac)")
:quality(80)/p7i.vogel.de/wcms/22/dd/22dd3f89e27950caea78d18b4a41766c/0129157014v1.jpeg "Volkswagen's first self-developed zonal electronics architecture goes into series production in China (Image:Volkswagen)")
:quality(80)/p7i.vogel.de/wcms/f5/22/f52293d339d8c952563eb00876da7cab/0129137154v1.jpeg "Joby Aviation is preparing for the first wave of pilot training for eVTOLs with CAE flight simulators. (Image:Joby Aviation)")
:quality(80)/p7i.vogel.de/wcms/36/c6/36c67f2e5e8fcb78c5a5b8d07673eec6/0129154312v1.jpeg "Yuchai intends to use its flywheel system - on the right-hand side of the engine - primarily in commercial vehicles. (Image:Yuchai)")
:quality(80)/p7i.vogel.de/wcms/2e/62/2e62e5977481169dd2a0301ab847dc2b/0129163687v1.jpeg "Increasing the voltage reduces the cable cross-sections and therefore the copper requirement considerably. (Image:Fraunhofer ISE)")
:quality(80)/p7i.vogel.de/wcms/5d/73/5d73b37d605e3d5f44de11d22447cedd/0129209328v1.jpeg "Agent BigEarth is based on a novel combination of several AI modules that work together as specialized sub-agents. (Image:BIFOLD)")
:quality(80)/p7i.vogel.de/wcms/d8/f8/d8f8fc64e23a1ed726fc8ac7ab697747/0129101600v1.jpeg "A new imaging technology makes it possible to detect early signs of heart disease through the skin. This opens up new markets for portable imaging systems. (Image:freely licensed)")
:quality(80)/p7i.vogel.de/wcms/95/e7/95e77e1c2ad5ee51222a6e287609643e/0129119186v1.jpeg "Photo of Micron's \"Site 3\" in Singapore, where NAND flash memory is manufactured. The memory manufacturer plans to invest a further 24 billion US dollars in the construction of an additional fab in Southeast Asia. The new plant is scheduled to go into operation by 2028. (Image:Micron)")
:fill(fff,0)/images.vogel.de/vogelonline/companyimg/76800/76895/65.jpg "FAULHABER_120mm.jpg ()")
:fill(fff,0)/p7i.vogel.de/companies/67/eb/67eba621ef6ea/logo2.png "logo2 (Wuxi InfiMotion)"){kind=logo}
:quality(80)/p7i.vogel.de/wcms/04/1e/041edca2b89230745b95e36268abbf81/0127796950v1.jpeg "Figure 1:
Traditional SoC solution.(Image: MPS)")
:quality(80)/p7i.vogel.de/wcms/89/34/8934fc3dc5e38cb09c7d62368022a520/0127796945v1.jpeg "Figure 2:
Digital PWM controllers and monolithic DrMOS ICs.(Image: MPS)")
:quality(80)/p7i.vogel.de/wcms/b9/c0/b9c0943e9489b135adc8044bce45dfc3/0127796947v1.jpeg "Figure 3:
Example of a robotic SoC power tree.(Image: MPS)")
:quality(80)/p7i.vogel.de/wcms/a1/39/a139cb0ce1c9a8c33c82d212b5bbb1c6/0125253336v1.jpeg "IQ9: The Thundercomm Development Kit from Qualcomm contains a QCA SoC. (Image:Qualcomm)")
:quality(80)/p7i.vogel.de/wcms/c9/c4/c9c4e42b9b054ec7ae0a3045170c07b6/0128162746v1.jpeg "Development workflow with Renesas e² studio: With Renesas e² studio, IoT applications can be downloaded from GitHub, configured, developed, and deployed on RA, RX, or RZ controllers – including connectivity to AWS and Microsoft Azure. (Image:Renesas Electronics Corporation)")