adminInternet of Things has been an exclusive topic to be discussed for the last few years. We all know about the opportunities it unveils in business. How adopting this technology can add more benefits and success to the company. But do you know how the choice of connectivity can affect the performance of the solution offered by IoT? One must consider the network, its effective range, reliability, device battery use, how much data of different types it can transfer, and the speed for implementing Industrial IoT projects.
Many connectivity options are available, and cellular connectivity is the most popular as it is a simple, scalable, and secure way to connect industrial IoT devices.
Today manufacturers all around the world are stepping ahead to make their business competent and more efficient by integrating it with IoT applications as it can boost productivity, reduce equipment downtime and enhance the efficiency of factory operations and processes.
Cellular IoT networks and devices are cheap and widespread, alluring more interest. Many organizations have already deployed cellular IoT networks to cut out the different business problems and start smart manufacturing. Organizations establish connectivity to gather data from various devices to adopt these projects successfully.
Cellular Connectivity In Industrial IoT Application
Integrating connected devices with cellular connectivity has been a long-time attempt of industrial engineers in creating autonomous manufacturing equipment and factory automation systems. Mobile technology has offered the skill for organizations to seamlessly accelerate the speed and extend the data processing capability of the systems.
Cellular connectivity empowers companies to transmit and process large amounts of information in a jiff without the requirement to send all the data through a centralized IT infrastructure. This provides organizations with an opportunity to execute strategies for machine health monitoring with the aid of wireless industrial IoT sensors without any requirement to construct their infrastructure.
Influence of Different Cellular Standards on IoT Connectivity
Cellular connections are pretty flexible with different protocols. Mostly LTE, i.e. Long Term Evolution is the prevalent worldwide approach. IIoT service providers prefer it because of its lower cost, ease of implementation quality, and less power need.
Device vendors are launching new cellular IoT devices, gateways, IoT inclined routers and new solutions that fit into IIoT solutions like IoT apps, IIoT system integration, and device analytics.
Including cellular connectivity to extend IoT solutions will boost the range of Plug and Play Sensors applications, enhancing the efficiency of Industrial IoT roll-outs and fast reconfigurations to fulfil the business requirements. Robust connectivity is necessary to achieve critical information about the health and performance of the machines; hence industries are focusing on getting the latest technologies that provide faster and more precise information. For successful deployment of cellular IoT systems, solution providers and multi-national end-user companies seek solutions that offer worldwide support (2G, 3G, and LTE). These are already becoming part of businesses scaling IoT solutions and assuring seamless deployment worldwide.
eSIM
Cellular standards impact the performance, range, ease of development, reliability, security and cost of implementation for expanding IoT in the manufacturing industry. Traditional sim cards which are utilized in cellular IoT devices are confined to single network carriers. They need a technical to manually insert or replace sim cards which cause deployment bottlenecks, especially in remote locations.
These challenges can end with the latest eSIM platforms, which have a non-removable chip that can download the carrier profile over the air and permit multiple telecom providers to programme in advance so that the device can choose the best connection.
IoT devices with eSIM have a single sim card with a cellular module that offers the ease of deploying anywhere globally and guarantee dependable connectivity due to their ability to switch carriers without any need for physical human interaction.
These devices are a blessing for monitoring machines in complex and remote areas and help to slay logistical challenges during movement. All these features provide speedier scalability for IoT applications.
Benefits of Cellular IoT Connectivity
Today, cellular connectivity is attaining unexpected height for implementing integrated machine-to-machine communications that facilitate wireless condition monitoring of industrial assets. This is all possible because Cellular IoT connectivity enables high network dependability. The cellular IoT devices data (transfers with high data rates) are not disturbed by bad weather conditions. The distance between the device and the base location does not impact it compared to other wireless communication options. This shows that cellular connectivity provides the best coverage and the capacity to avoid overload problems. It also offers greater freedom of mobility that supports obtaining connectivity even in complex environments where equipment is not stationary.
Mobile technology impressively transforms Industrial IoT applications and solutions because of its advantages. In IIoT, various manufacturing verticals will keep using cellular IoT devices as the most successful implementation.
Digitalization
Digitalization of manufacturing operations guarantees lowered downtime & enhanced productivity, and cellular networks are essential to accomplish it. Cellular networks provide organizations with the opportunity to use these technologies to speed their Industry 4.0 journey potentially.
The availability of cellular network coverage eases the work by making it prompt and cost-saving for manufacturers to keep a watch on industrial assets even in remote areas. The incoming of 5G provides a more robust opportunity for organizations to leverage data through faster connections, ultimately improving capacity to handle real-time information to discover the most fitting and highly potential Industrial IoT.