In other words, mobile robotics works in the agricultural sector to improve productivity, specialization and environmental sustainability. The objective of agricultural robotics is to help the sector in its efficiency and in the profitability of the processes. Register for this webinar to discover the virtual commissioning technique that enables manufacturers to roll out a concurrent mechanical, software, E/E hardware design process and replace expensive and time-consuming physical tests with early virtual validation of controls.Innovation in terms of robotics applications in agriculture has advanced considerably in the last 5 years. The digital model, when coupled with inputs from a real sensor, can be used for AGV monitoring to perform predictive maintenance tasks. The virtual commissioning of an AGV/AMR digital mockup helps to develop control strategy in a risk-free environment. Virtual commissioning and controls validation of AGV/AMR Register for this webinar and discover how insights from simulation help to optimize stability, speed, and control of AGV/AMR. Using system simulation software, engineers can evaluate multiple scenarios (changing the shape of the trajectory, velocity, etc.) before committing to a prototype. Increasing AGV/AMR speed has a direct impact on vehicle stability and operational control. Optimize stability, speed and control of AGV/AMR Register for this webinar and learn which parameters influence robots’ autonomy and discharging. Leading AGV/AMR manufacturers utilize system simulation software to predict battery performance during the work cycle with the actual load and speed of the vehicle. Efficient management of fleet autonomy and vehicle charging strategy is important to maintain a steady throughput. Modern mobile robots including Automatic Guided Vehicle (AGV) and Autonomous Mobile Robots (AMR) are electrified vehicles that operate on battery. Overcome mobile robots’ autonomy and charging challenges Integration of robots within the factory environment and coupling to material handling systems.Balance vehicle performance attributes, namely: speed, load, stability etc.Utilizing virtual AI driving agent and effective controls validation.Overcome speed, self-steering and maneuver limitation without losing stability.Utilize system engineering principles to reduce the development time and cost of AGV/AMR systems.Join this system engineering webinar and learn about the six key pillars that are integral to the success of AGV/AMR. Tight integration of automation, energy management, environment, sensor and operation expertise during design is necessary to realize highly flexible and scalable AGV/AMRs. AGV/AMR original equipment manufacturers (OEMs) face several engineering challenges due to the intricate nature of the autonomous systems, the tight integration between physical hardware and control algorithms. However, developing an AGV that can be customized to meet the needs of various environments and driving spaces is complex and expensive. Automated guided vehicles (AGV) / Autonomous mobile robots (AMR) promise flexibility, productivity, maneuverability and safety while minimizing operational costs in the industry, warehouse, fulfillment centers, and civil/domestic applications.
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