Guide to Electronic System Development

The rollout of 5G communication networks and 6G networks on the horizon promise to be a boon for telecommunications companies and the manufacturing industry globally. Faster speeds will result in higher data rates for users, perhaps as much as ten times higher than 4G capabilities, using the 3.5 GHz frequency bands for area-wide services and the 26-28 GHz bands for high data rate hotspots. How will antenna manufacturers, wireless equipment manufacturers, automobile manufacturers and suppliers, and wireless operators rise to meet these challenges? In this guide, we’ll investigate the various electromagnetic and network planning simulation solutions Altair offers.

The Internet of Things (IoT) has transformed the way companies do business. New product lines, recurring revenue streams, more efficient operations, higher quality and faster time-to-market are all within reach with the introduction of smart interconnections between systems and assets. This guide is designed to help you realize your Smart Product Development vision from ideation, to optimization, to launch and operation. Try SmartWorks IoT today, for free - click here to start trial.

Welded assemblies are widely used across industrial sectors. The design processes in rail, construction, marine, heavy machinery, pressure vessel construction, and many other industries rely heavily on regulations, codes, and norms such as FKM, DVS-1612, and Eurocode-3. This guide describes the evaluation and standard based certification of welded constructions by combining CAE methodology with relevant norms and regulations in a guided and standardized workflow.

To get a beautifully designed electronic product safely delivered to your customer, the work must start at the product design phase. Leveraging simulation-driven design, manufacturers are gaining greater insight and control over the development of innovative products, consistent manufacturing processes, and cost-effective, sustainable packaging.

Any industry that produces bulk quantities of goods such as pharmaceuticals, food, chemicals, or cosmetics, is seeking to produce these products consistently while reducing cost factors like waste and down time. Due to the nature of process manufacturing, multiple ingredients are combined to be mixed, coated, or sorted, so understanding the behavior of these processes is of paramount importance for manufacturers. Through the use of simulation modeling and Smart Manufacturing principals, manufacturers are now able to optimize these processes, leading to greater productivity and profitability.

Nowadays to remain competitive, the need to constantly improve injection molding processes can benefit from modern technological advancements that simulation offers to overcome known disadvantages.

Additive manufacturing offers the medical community exciting opportunities to reduce cost and logistical hurdles while improving patient outcomes. Huge leaps in additive manufacturing innovation have been enabled by simulation-driven design. In this guide, we will explore the use of simulation and analysis technology in the medical field to design complex AM solutions, explore material decisions, optimize structures for performance, and ensure that designs can be printed efficiently.

This guide walks you through the decision-making process of taking additive manufacturing to production, answering some of the most important questions related to taking additive manufacturing to production