Archive 03.02.2018

By Meg Murphy
K. Daron Acemoglu, the Elizabeth and James Killian Professor of Economics at MIT, is a leading thinker on the labor market implications of artificial intelligence, robotics, automation, and new technologies. His innovative work challenges the way people think about these technologies intersect with the world of work. In 2005, he won the John Bates Clark Medal, an honor shared by a number of Nobel Prize recipients and luminaries in the field of economics.

Acemoglu holds a bachelor’s degree in economics from University of York. His master’s degree in mathematical economics and econometrics and doctorate in economics are from the London School of Economics. With political scientist James Robinson, Acemoglu co-authored the much discussed book “Why Nations Fail” (Crown Business, 2012) and “Economic Origins of Dictatorship and Democracy” (Cambridge University Press, 2006). He also wrote the book, “Introduction to Modern Economic Growth” (Princeton University Press, 2008). Acemoglu recently answered a few questions about technology and work.

Q: How do we begin to understand the rise of artificial intelligence and its future impact on society?

A: We need to look to the past in the face of modern innovations in machine learning, robotics, artificial intelligence, big data, and beyond. The process of machines replacing labor in the production process is not a new one. It’s been going on pretty much continuously since the Industrial Revolution. Spinning and weaving machines took jobs away from spinners and weavers. One innovation would follow another, and people would be thrown out of work by a machine performing the job in a cheaper way.

But at the end of the day, the Industrial Revolution and its aftermath created much better opportunities for people. For much of the 20th century in the U.S., workers’ wages and employment kept growing. New occupations and new tasks and new jobs were generated within the framework of new technological knowledge. A huge number of occupations in the American economy today did not exist 50 years ago — radiologists, management consultants, software developers, and so on. Go back a century and most of the white-collar jobs today did not exist.

Q:  Do you think public fears about the future of work are just?

A: The way we live continuously changes in significant ways — how we learn, how we acquire food, what we emphasize, our social organizations.

Our adjustments to technology — especially transformative technologies — are not a walk in the park. It is not going to be easy and seamless and just sort itself out. A lot of historical evidence shows the process is a painful one. The mechanization of agriculture is one of the greatest achievement of the American economy but it was hugely disruptive for millions of people who suffered joblessness.

At the same time, we are capable technologically and socially of creating many new jobs that will take people to new horizons in terms of productivity and freedom from the hardest types of manual labor. There are great opportunities with artificial intelligence but whether or not we exploit them is a different question. I think you should never be too optimistic but neither should you be too pessimistic.

Q: How do you suggest people prepare for the future job market?

A: We are very much in the midst of understanding what sort of process we are going through. We don’t even necessarily know what skills are needed for the jobs of the future.

Imagine one scenario. Artificial intelligence removes the need for seasoned accountants to fulfill numeracy-related tasks. But we need tax professionals, for instance, to inform clients about their choices and options in some sort of emphatic human way. They will have to become the interface between the machines and the customers. The jobs of the future, in this instance and many others, would require communications, flexibility, and social skills.

However, I don’t know if my hypothesis is true because we haven’t tested it. We haven’t lived through it. I see the biggest void in our knowledge. People at institutions like MIT must learn more about what’s is going on so that we are better prepared to understand the future.

David K. Williams for Forbes: The result: production has moved from one machine every 4-6 weeks to an average of 5 machines per month for a total of 130 worldwide and predominance in its sector, with pre-orders booked through June 2018.

OptoForce Sensors Providing Industrial Robots with

a “Sense of Touch” to Advance Manufacturing Automation

 

Global efforts to expand the capabilities of industrial robots are on the rise, as the demand from manufacturing companies to strengthen their operations and improve performance grows.

Hungary-based OptoForce, with a North American office in Charlotte, North Carolina, is one company that continues to support organizations with new robotic capabilities, as evidenced by its several new applications released in 2017.

The company, a leading robotics technology provider of multi-axis force and torque sensors, delivers 6 degrees of freedom force and torque measurement for industrial automation, and provides sensors for most of the currently-used industrial robots.

It recently developed and brought to market three new applications for KUKA industrial robots.

The new applications are hand guiding, presence detection, and center pointing and will be utilized by both end users and systems integrators. Each application is summarized below and what they provide for KUKA robots, along with video demonstrations to show how they operate.

• Hand Guiding:  With OptoForce’s Hand Guiding application, KUKA robots can easily and smoothly move in an assigned direction and selected route. This video shows specifically how to program the robot for hand guiding.

• Presence Detection: This application allows KUKA robots to detect the presence of a specific object and to find the object even if it has moved. Visit here to learn more about presence detection.
• Center Pointing: With this application, the OptoForce sensor helps the KUKA robot find the center point of an object by providing the robot with a sense of touch. This solution also works with glossy metal objects where a vision system would not be able to define its position. This video shows in detail how the center pointing application works.

The company’s CEO explained how these applications help KUKA robots and industrial automation.

“OptoForce’s new applications for KUKA robots pave the way for substantial improvements in industrial automation for both end users and systems integrators,” said Ákos Dömötör, CEO of OptoForce. “Our 6-axis force/torque sensors are combined with highly functional hardware and a comprehensive software package, which include the pre-programmed industrial applications. Essentially, we’re adding a ‘sense of touch’ to KUKA robot arms, enabling these robots to have abilities similar to a human hand, and opening up numerous new capabilities in industrial automation.”

Along with these new applications recently released for KUKA robots, OptoForce sensors are also being used by various companies on numerous industrial robots and manufacturing automation projects around the world. Examples of other uses include: path recording, polishing plastic and metal, box insertion, placing pins in holes, stacking/destacking, palletizing, and metal part sanding.

Specifically, some of the projects current underway by companies include: a plastic parting line removal; an obstacle detection for a major car manufacturing company; and a center point insertion application for a car part supplier, where the task of the robot is to insert a mirror, completely centered, onto a side mirror housing.

For more information, visit www.optoforce.com.

This post was provided by: OptoForce

The post OptoForce Industrial Robot Sensors appeared first on Roboticmagazine.

Machine vision technologies based on CNNs and deep learning can be used profitably in a wide range of different industrial sectors and applications, allowing the automation and significant acceleration of inspection processes in the electronics industry, for example.

Automation-intensive sectors such as the automotive industry are not the only ones to rely on robots. In more and more agricultural settings, automation systems are superseding strenuous manual labor. As part of the EU's CATCH project, the Fraunhofer Institute for Production Systems and Design Technology IPK is developing and testing a dual-arm robot for the automated harvesting of cucumbers. This lightweight solution has the potential to keep crop cultivation commercially viable in Germany.

Sure, there have already been 3-D printed houses. And you can pick up a Nest Thermostat with artificial intelligence at your local hardware store. But a new book co-written and co-edited by Mahesh Daas, dean of the University of Kansas School of Architecture & Design, argues that robotics can and soon will be even further integrated into the design processes at the heart of architecture.