Embedded Hardware Solutions for Industrial Products

Sensor Integration

Robots can perceive their surroundings and interact intelligently with their environment thanks to embedded systems that integrate feedback from various sensors, such as proximity sensors, force sensors, and vision systems. The result is adaptive behavior, improved safety, and more efficient task execution. Sensor and actuator integration is key to achieving this.

Communication

Integration into the industrial workflow relies heavily on reliable industrial communication protocols. For efficient collaboration between robots and other automated equipment, embedded systems ensure communication between them and other automation systems on the factory floor, enabling coordinated operations and data exchange.

Applications

Embedded systems drive a wide range of robotic applications, including pick-and-place operations, assembly, and material handling. They enhance productivity, precision, and flexibility in manufacturing processes, highlighting the versatility of robotics and automation design and contributing to overall assembly line automation.

EOAT/Robotic Attachments

By controlling and communicating with various End-of-Arm Tooling (EOAT) and robotic attachments, such as grippers and adhesive dispensers, embedded systems expand the versatility and functionality of robots, allowing them to perform a wider range of tasks. Adaptability is crucial in modern robotics and automation design, and relies on effective sensor and actuator integration.

Sorting and Diverting

A conveyor system that intelligently directs items to their correct destinations is made possible by embedded systems working in conjunction with sensors and actuators. They can identify items based on various criteria—size, weight, type—and trigger diverters to guide them accordingly. This level of automated sorting capability improves material flow and minimizes manual intervention.

Tracking and Monitoring

By integrating tracking technologies like RFID or barcode scanners, these systems monitor the movement of items on conveyor belts. You get valuable real-time data on item location, status, and inventory levels, allowing you to optimize material flow and maintain precise control over your inventory.

Integration with Other Systems

A truly efficient conveyor system doesn’t exist in isolation. Embedded systems break down these silos by enabling seamless integration with other automation components. Robots, PLCs, warehouse management systems—they can all communicate and coordinate thanks to the embedded intelligence within the conveyor system.

Sensor and Actuator Integration

Embedded systems act as the central nervous system of a machine, seamlessly integrating data from a network of sensors. These sensors monitor critical parameters like temperature, pressure, vibration, and position. Based on this real-time sensory input, the embedded system directs actuators to make precise adjustments, ensuring the machine operates at peak performance.

Predictive Maintenance

Unplanned downtime can cripple productivity. Embedded systems offer a proactive solution through predictive maintenance. By continuously analyzing sensor data, they can detect subtle anomalies and performance degradation that often precede failures. Early detection allows for timely maintenance, preventing costly downtime and extending the lifespan of your valuable equipment.

Modbus/TCP

Known for its simplicity and versatility, Modbus/TCP is a popular choice for industrial communication. Embedded systems with Modbus/TCP capabilities connect a wide range of devices, supporting both master-slave and peer-to-peer communication. This protocol is commonly used for connecting sensors, actuators, and other industrial equipment, enabling efficient data acquisition and control.

OPC UA Integration

OPC UA (Unified Architecture) has emerged as a leading standard for industrial communication, providing platform independence, security, and interoperability. Embedded systems designed to support OPC UA enable quick integration with various SCADA and HMI platforms, ensuring data accessibility and exchange across different systems.

MQTT Integration

MQTT (Message Queuing Telemetry Transport) is a lightweight messaging protocol designed for resource-constrained devices and low-bandwidth, high-latency networks. Its publish-subscribe model makes it ideal for connecting numerous devices and sensors within a factory setting, enabling efficient data exchange for industrial IoT applications.

DEVELOP’s embedded systems can be seamlessly integrated with MQTT, facilitating communication between devices on the factory floor and SCADA/HMI systems.

Fieldbus Communication Systems

Fieldbus protocols like Profibus, DeviceNet, and CANopen offer robust and deterministic communication solutions for specific industrial applications. Embedded systems play a crucial role in interfacing with and managing fieldbus communication, ensuring reliable data transfer in harsh industrial environments.

Wireless Communication

Wireless communication offers flexibility and cost-effectiveness for connecting industrial devices. Embedded systems enable secure and reliable wireless communication in factories, leveraging protocols like Wi-Fi, Bluetooth, and Zigbee to connect machines, sensors, and control systems.

Bandwidth Optimization and Cost Savings

By processing data locally at the edge, edge computing in industrial automation reduces the need to transmit massive amounts of data to the cloud. By optimizing bandwidth usage and reducing network congestion, you can achieve significant cost savings on data transmission and cloud processing fees.

Enhanced Reliability and Resilience

Edge computing can increase the resilience of industrial systems. By distributing processing power, even if the connection to the cloud is disrupted, critical operations can continue functioning locally. This is particularly important in remote or harsh environments where network connectivity may be unreliable.  

Real-time Monitoring and Analysis

By applying embedded systems for industrial automation in SCADA system design, operators gain real-time insights into critical process parameters. You get the immediate detection of anomalies, triggering alarms and enabling rapid responses to maintain optimal performance and prevent potential issues. This capability is crucial for ensuring the efficiency and reliability of real-time monitoring systems.

Process Optimization and Control

Beyond monitoring, embedded systems within SCADA systems provide the tools to actively control and optimize industrial processes. Operators can remotely adjust setpoints, initiate control actions, and implement automation sequences, all of which contribute to improved efficiency, reduced waste, and enhanced productivity. A high level of control is essential for effective SCADA system design and contributes to the overall effectiveness of assembly line automation.

Enhanced User Experience (UX)

Well-designed HMIs can significantly improve operator efficiency and reduce errors. Embedded systems enable the development of HMIs with a focus on UX design, creating simple navigation systems, clear visual cues, and user-friendly controls to minimize operator errors, improve situational awareness, and enhance overall efficiency.

Data Presentation and Analysis

Embedded systems within HMIs go beyond simply displaying data. They can also process and present it in meaningful ways, allowing operators to analyze historical trends, identify patterns, and make informed decisions. A data-driven approach, supported by embedded systems, contributes to improved process optimization, troubleshooting, and predictive maintenance.

Performance Testing

By applying embedded systems, manufacturers can simulate real-world operating conditions to assess a product’s performance under various loads and stresses. Identify potential weaknesses, optimize performance parameters, and ensure long-term reliability.

Stress Testing

To determine a product’s limits and identify potential failure points, embedded systems can subject it to extreme conditions. Stress testing helps to improve product design and ensure robustness in demanding environments.

Real-time Data Analysis

A key advantage of embedded systems in testing is their ability to collect and analyze test data in real-time, providing immediate feedback on product performance and identifying potential defects or areas for improvement. Accelerate the testing process and make rapid adjustments to manufacturing processes.

Statistical Process Control (SPC)

Embedded systems can be integrated with SPC software to monitor manufacturing processes, identify trends, and detect deviations from established control limits. Proactive interventions maintain consistent product quality and prevent defects.

Trend Analysis and Root Cause Analysis

By analyzing historical data, embedded systems can identify trends, patterns, and anomalies in product quality or manufacturing processes. A more data-driven approach ensures root cause analysis, allowing manufacturers to address underlying issues and implement corrective actions.

Rapid Prototyping

We accelerate the development process through hardware prototyping and the rapid iteration of design and testing cycles. Quick identification and resolution of potential issues ensures that the final product meets the highest standards of quality and reliability.

Early Issue Detection

By identifying and addressing potential issues early in the design phase, we’ll minimize the need for costly rework and redesign later in the production process. A commitment to thorough testing and debugging hardware contributes to improved product quality, reduced development costs, and a faster time-to-market for our clients.

Enhanced Safety and Reliability

For enhanced safety and reliability, embedded systems can be designed with robust safety mechanisms, ensuring reliable operation even in hazardous or demanding environments. Real-time monitoring systems can monitor critical parameters, detect anomalies, and trigger safety protocols to prevent accidents and protect personnel and equipment, making them essential industrial automation hardware.

Real-time Monitoring and Control

Get real-time insights into machine performance and process parameters. Make immediate adjustments, optimize your control, and proactively respond to changing conditions for improved efficiency, reduced waste, and enhanced product quality. Real-time control capability is crucial for applications like SCADA systems and other industrial automation processes.

Predictive Maintenance and Reduced Downtime

Minimize downtime and maximize the lifespan of your equipment with embedded systems. By analyzing data from sensors and identifying potential issues before they escalate into costly failures, they enable predictive maintenance systems. A proactive approach optimizes maintenance schedules and ensures smooth, uninterrupted operation.

Cost Optimization and Scalability

Embedded systems can be tailored to specific application requirements, optimizing resource utilization and minimizing unnecessary hardware costs. Their scalability allows for easy expansion and adaptation as operational needs evolve, providing a flexible and cost-effective solution for growing businesses, making them ideal embedded systems for production. This also supports efficient prototype scaling to meet future demands.

Seamless Transition to Production

Successfully making the transition from prototype to production is crucial for any hardware project. Our expertise ensures that your designs are optimized for manufacturability, cost-effectiveness, and scalability, making the journey from prototype to production as smooth as possible.

Scaling for Mass Production

Achieving mass production readiness requires careful planning and execution. Whether you need a small batch or a large-scale production run, we have the capabilities to scale your embedded hardware solutions effectively. Our expertise in prototype scaling ensures that your designs can meet the demands of mass production without compromising quality or performance.

High-Speed PCB Design

When your industrial applications demand high-speed signal transmission, careful PCB design is crucial.  DEVELOP employs a range of techniques to ensure signal integrity, minimize interference, and optimize performance. This includes techniques like impedance matching, controlled impedance routing, and careful component placement and termination to reduce signal reflections and crosstalk.  Our expertise in this area guarantees reliable operation even in demanding environments.

Controlled Impedance Routing

We meticulously design controlled impedance routing to maintain signal integrity and prevent signal reflections in high-speed applications, ensuring reliable performance and compliance with industry standards.

High-Volume PCB Assembly

At our facility in the US, we have the capacity and expertise to handle high-volume PCB assembly, meeting the demands of large-scale production runs with consistent quality and efficiency.

Advanced Quality Control

We use advanced quality control techniques and equipment to identify and address potential issues, guaranteeing the performance and longevity of your PCBs in demanding industrial environments.

Model Predictive Control

By using a model of the system to predict future behavior, this advanced method optimizes actuator control for improved performance and efficiency.

Full State Feedback

For complex systems with multiple actuators, this technique leverages complete system state information to achieve precise and responsive control.

Environmental Hardening

Components are selected and integrated to tolerate extreme temperatures, humidity, vibration, and physical impacts, guaranteeing longevity and consistent performance in demanding industrial settings.

Cable Integrity

Recognizing the vulnerability of connections, DEVELOP implements strategies to protect against cable damage and ensure signal integrity, even in environments with heavy machinery or potential physical interference.

Fieldbus Proficiency

Deep knowledge of fieldbus protocols like Profibus, DeviceNet, and CANopen allows for the creation of robust communication solutions for specific industrial applications. Embedded systems interfacing with and managing fieldbus networks ensure reliable data transfer even in harsh environments. When necessary, we can also incorporate industrial protocol gateways to bridge communication between different fieldbus systems or to connect them to Ethernet networks.

Network Security

At DEVELOP, every industrial communication solution is designed with network security as a top priority. Robust security measures, including firewalls, encryption, and authentication protocols, are implemented to protect your critical data and prevent unauthorized access.

Remote Access and Cloud Connectivity

Secure remote access to your industrial systems allows for remote monitoring, control, and troubleshooting. Cloud connectivity is also encouraged for data logging, analysis, and integration with cloud-based applications, arming you with valuable insights and enhanced control over your operations.

Integration with Existing Infrastructure

Recognizing that industrial facilities often have a mix of legacy and modern equipment, DEVELOP’s expertise lies in integrating embedded systems with your existing industrial infrastructure, ensuring compatibility and minimizing disruption during upgrades or expansions.

API Development and Integration

Application programming interfaces (APIs) are developed and integrated to enable constant communication and data exchange between different software components and systems. Ensure interoperability and allow your embedded systems to interact effectively with other industrial automation platforms.

User-Friendly Interfaces

User experience is a core component of every software solution we develop. Our experience in user interface (UI) design and human-machine interface (HMI) design ensures that your embedded systems are intuitive and easy to operate, minimizing training time and maximizing user efficiency.

Integration with Hardware

Close collaboration between our software and hardware engineers ensures seamless integration of software and hardware components. A collaborative approach guarantees optimal performance, reliability, and functionality of your embedded systems.

Electromagnetic Compatibility (EMC) Testing

Comprehensive EMC testing ensures that embedded systems comply with industry standards and do not interfere with other electronic devices. This includes testing for radiated and conducted emissions, as well as susceptibility to electromagnetic interference.

Reliability Testing

To assess the long-term reliability of embedded systems, accelerated life testing, stress testing, and failure analysis are performed. Reliability testing helps identify potential weaknesses, improve design robustness, and ensure long-term performance in industrial applications.

Compliance Testing

DEVELOP is committed to meeting all relevant industry standards and regulatory requirements. Embedded systems undergo comprehensive compliance testing to ensure they meet safety, performance, and environmental regulations, allowing for faster integration into your industrial operations.