We are seeing huge benefits from iot in many areas. However, automatic probe station we can not be satisfied with the existing achievements of the Internet of Things industry, we must think about the next development to do what can be done to elevate the industrial application to a new level?
Looking at the Internet of Things (IoT) today, we already have 35-40 billion devices installed, and that number is growing fast. But how did we get to where we are today through technology? And how do we ensure that this growth continues? Over the past 10 years, several factors have made this possible:
We have acquired sufficient cloud infrastructure;
We have a mature wireless data network that is fast, reliable and cheap;
Most of us use smartphones and Internet-connected computers every day;
We now have billions of low-cost, powerful connectivity solutions that can be deployed anywhere in the enterprise and in virtually any other market segment, private 5g including an embedded, consumer application and data center.
We are seeing huge benefits from iot in many areas. For example, in the retail industry, supermarkets use electronic shelf labels (ESL) so that employees do not have to manually change labels. This makes it easy to update prices frequently and creates new opportunities for promotions and targeted offers.
However, we can not be satisfied with the existing achievements of the Internet of Things industry, private lte we must think about the next step to take the industrial application to a new height. To drive the growth of iot, we must pay attention to the following four trends:
Acceleration software
Protect product safety (protect products).
Connecting teams
Authorized data governance
Many of the future challenges of iot will be software, not hardware. A real-time operating system (RTOS) is a key component needed to create secure, maintainable, and portable products that can be deployed at scale. RTOS provides an underlying framework for consistent connectivity to the cloud. It also includes features such as over-the-air Transfer (Ota) firmware updates that enable edge-installed iot products to operate for 25 years or more.
Next, consider the security of embedded devices. The chip must be secure against physical attacks so that no one can read or tamper with the data in the chip. We also need a secure way to connect to the cloud, using certified protocols and working with technologies like key exchange authentication and encryption.
So for iot, we need end-to-end secure connectivity from the chip to the cloud. No matter what the application is, or how low its cost and power consumption - you still have to make sure it's a secure one.
Some argue that embedded applications are somehow different from other areas of computing - they don't need to run authenticated code to know if a remote device is trusted.
That idea may no longer exist. In the next five to 10 years, we will see embedded systems in this trusted software model run on a global scale, gradually increasing from a small percentage to 100%.
Most companies in this industry have two kinds of teams: device teams that build physical products and cloud software teams that work to manage devices throughout their lifecycle. How do we connect the hardware to the cloud team? We have to do better.
The embedded world tends to use small, power-limited devices that are programmed at the bare metal level, but this makes it difficult to update after a few years. Instead, we should use RTOS with sufficient memory and performance to facilitate containerization of embedded development.
Finally, it's about the data. How do we manage this data? What should we have done differently? Many times, this data only has a simple use case, but you can choose to do more with it. Good data management will maximize the use of data and keep all information secure.