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Why IoT Sensors Need Standards

They could improve performance and spur development of new applications

3 min read
A photo of white gloved hands holding a circuit board.

Standards will ensure radar sensor main circuit boards, such as the one above made at the Continental automated driving technology factory in Ingolstadt, Germany, will consider rules of the road and their regional and temporal dependencies.

Alex Kraus/Bloomberg/Getty Images

Sensors traditionally have been used for camera imaging, as well as communicating information about humidity, temperature, motion, speed, proximity, and other aspects of the environment. The devices have become key enablers for a host of new technologies essential to business and to everyday life, from turning on a light switch to managing one’s health.

Several factors are fueling sensors’ growth, including miniaturization, increased functionality, and higher levels of integration into electronic circuitry. There are also greater levels of automation being incorporated into products and systems, such as with Internet of Things and Industrial Internet of Things applications.


Prominent users of sensors include the defense, energy, health care, and transportation industries. The global sensor market is large and growing fast. By one estimate, it is projected to reach US $346 billion in sales by 2028, up from $167 billion in 2019.

SAFE AND RELIABLE APPLICATIONS

As the sensor industry races to take advantage of market opportunities, the need to ensure the devices will operate safely and reliably is a growing concern.

In the energy industry, for example, drill rigs for oil and gas exploration are now equipped with sensors to achieve optimal, safe performance at the lowest cost possible. The sensors must operate under harsh environmental conditions. Their failure could result in a rig being taken out of service, leading to significant, costly downtime.

In industrial applications, worker safety would be compromised if gas sensors fail to detect the presence of toxic fumes. If the light detection and ranging remote-sensing system lidar fails in semiautonomous vehicles, they will be unable to function properly. Lidar is fundamental to advanced driver-assistance systems (ADAS).

Because there are now thousands of sensor products on the market, adherence to standards that could improve their performance or accelerate development of new applications has grown in importance, as has the need for independent conformity and certification protocols.

It has become challenging to effectively deploy sensors in complex IoT and IIoT applications given the interoperability issues that can arise when attempting to integrate systems from multiple vendors. Hardware compatibility, wired and wireless connectivity, security, software development, and cloud computing are key interoperability considerations as well as major issues in their own right.

STANDARDS FOR IOT SENSORS

For many years, the IEEE Standards Association (IEEE SA) has provided an open platform for users, those in academia, and technical experts from sensor manufacturers to come together to develop standards. Here are a few examples of IEEE standards and projects that have come from the collaboration.

  • IEEE P1451.99: IEEE Standard for Harmonization of Internet of Things Devices and Systems. Current implementations of IoT devices and systems do not provide a way to share data or for an owner of such devices to authorize who has the right to control them or access the devices’ data. This standard will define a metadata bridge to facilitate IoT protocol transport for sensors, actuators, and other devices. It will address issues of security, scalability, and interoperability for cost savings and reduced complexity. The standard will offer a data-sharing approach that leverages current instrumentation and devices used in industry.
  • IEEE P2020: Standard for Automotive System Image Quality. Most automotive camera systems have been developed independently, with no standardized reference point for calibration or measurement of image quality. This standard will address the fundamental attributes that contribute to image quality for ADAS applications; identify existing metrics and other useful information relating to the attributes; define a standardized suite of objective and subjective test methods; and specify tools and test methods to facilitate standards-based communication and comparison among system integrators and component vendors.

REGISTRY AND CERTIFICATION

IEEE SA offers the IEEE Sensors Registry. The global Web-based service for manufacturers allows them to enter their sensors’ certifications, the standards they adhere to, and product data sheets so that buyers can find the right product. IEEE conducts an audit process on the submitted information to ensure its accuracy.

WEBINARS AND ROUNDTABLE

These free on-demand and upcoming webinars are available:

The first in a series of new webinars, Are Sensors the Weakest Link to Cyber Attacks?, is scheduled for 2 February at 1 p.m. Eastern Time.

IEEE SA plans to host an industry roundtable during the first quarter this year. It will focus on the creation of a comprehensive plan and timeline to address interoperability and cybersecurity issues for IoT sensor networks. Participants will include technology leaders from industry, government, and academia. Contact sensors-rt@ieee.org for more information.

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The First Million-Transistor Chip: the Engineers’ Story

Intel’s i860 RISC chip was a graphics powerhouse

21 min read
Twenty people crowd into a cubicle, the man in the center seated holding a silicon wafer full of chips

Intel's million-transistor chip development team

In San Francisco on Feb. 27, 1989, Intel Corp., Santa Clara, Calif., startled the world of high technology by presenting the first ever 1-million-transistor microprocessor, which was also the company’s first such chip to use a reduced instruction set.

The number of transistors alone marks a huge leap upward: Intel’s previous microprocessor, the 80386, has only 275,000 of them. But this long-deferred move into the booming market in reduced-instruction-set computing (RISC) was more of a shock, in part because it broke with Intel’s tradition of compatibility with earlier processors—and not least because after three well-guarded years in development the chip came as a complete surprise. Now designated the i860, it entered development in 1986 about the same time as the 80486, the yet-to-be-introduced successor to Intel’s highly regarded 80286 and 80386. The two chips have about the same area and use the same 1-micrometer CMOS technology then under development at the company’s systems production and manufacturing plant in Hillsboro, Ore. But with the i860, then code-named the N10, the company planned a revolution.

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