Connect with us

AI

70% of job seekers think automation skills are the key to finding a new position

A new Harris Poll finds that Americans looking to gain an edge are trying to bolster their CV credentials with the most in-demand skills.

Published

on

A new Harris Poll finds that Americans looking to gain an edge are trying to bolster their CV credentials with the most in-demand skills.

Presentation about automation to improve reliability and productivity

Image: Getty Images/iStockphoto

More about artificial intelligence

There are 30 million unemployed Americans. A new Harris Poll commissioned by Zapier found that two out of five workers say they were let go by their employer due to COVID-19. At least 70% of current job seekers—those unemployed or employed and looking—believe the key to landing a new job is automation. The number is even higher (86%) among those with a college degree or higher.

According to the survey, “The Job Seekers Report,” 30% have added automation to their resumes, while 31% said they planned to do so. With so many job-seekers adding to their skill set with the key word “automation,” the Zapier survey queried, “is it possible employers will notice the omission?”

SEE: Managing AI and ML in the enterprise 2020: Tech leaders increase project development and implementation (TechRepublic Premium)

It makes sense that many Americans are looking to develop new skills or hone-in on existing ones—they’re competing with the 41% who lost jobs due to the pandemic, and those also unemployed, as well as those who have jobs but need or want to make a change. 

A majority (83%) either have learned automation skills or planned to do so in the near future. The need and desire for efficiency could be from the need to maximize crucial, available time. Work hours invariably come at the expense of those in the home who are remote-learning or those tasked with helping or even teaching those remote learners. 

Many are still working remotely, with offices closed, and are burdened with the uncertainty of when and if they’ll return to their offices. Many businesses have already declared a switch to all remote, a virtual office.

Those surveyed find the biggest benefits of automation are:

  • Makes you more efficient—42%
  • Helps you save time—42%
  • Allows you to get more done in a day—37%
  • Helps you be a better employee—35%
  • Saves you frustration on tedious tasks—29%
  • Helps you concentrate on important tasks—26%
  • Saves you from having to learn technical skills—24%

Automation skills are valued across a swath of industries and projects, including the obvious (and popular) robotics, mobile phones, healthcare, entertainment, manufacturing, education, product delivery, transportation, DevOps, IT Ops, software testing, home-help products, and more.

It’s not only Zapier finding the rise of automation. As TechRepublic reported in May, automation could lead to another jobless recovery, according to Forrester. The firm’s report, “The COVID-19 Crisis Will Accelerate Enterprise Automation Plans,” indicated how critical automation will be to companies looking to “lower their exposure to future business disruption.”

Leslie Joseph, author of the Forrester report, said: “[A]utomation is a very big motion within most of the large SI’s and consulting firms, who are aggressively upskilling their manpower. In fact, many SI’s with large automation practices began with aggressively applying automation to their own internal delivery and back-office function, at significant scale.”

The article in TechRepublic noted, “Another caveat that may lead to fewer job losses is the expectation that large-scale automation of business processes and routine, repetitive tasks will not necessarily lead to large-scale job replacement.”

Joseph told TechRepublic: “Automation is not just like any standard technology implementation. It requires significant participation and support from the existing workforce. Successful automation leaders will bring their people along on the journey. This will include elements of reskilling of people whose jobs are sidelined by bots, to bring them back into helping run and manage the automation program itself.”

Methodology: Harris conducted the poll of 2,069 US adults, 18 or older, online between July 14 to July 16.

Also see 

Source: https://www.techrepublic.com/article/70-of-job-seekers-think-automation-skills-are-the-key-to-finding-a-new-position/#ftag=RSS56d97e7

Continue Reading

AI

How does it know?! Some beginner chatbot tech for newbies.

Published

on

Wouter S. Sligter

Most people will know by now what a chatbot or conversational AI is. But how does one design and build an intelligent chatbot? Let’s investigate some essential concepts in bot design: intents, context, flows and pages.

I like using Google’s Dialogflow platform for my intelligent assistants. Dialogflow has a very accurate NLP engine at a cost structure that is extremely competitive. In Dialogflow there are roughly two ways to build the bot tech. One is through intents and context, the other is by means of flows and pages. Both of these design approaches have their own version of Dialogflow: “ES” and “CX”.

Dialogflow ES is the older version of the Dialogflow platform which works with intents, context and entities. Slot filling and fulfillment also help manage the conversation flow. Here are Google’s docs on these concepts: https://cloud.google.com/dialogflow/es/docs/concepts

Context is what distinguishes ES from CX. It’s a way to understand where the conversation is headed. Here’s a diagram that may help understand how context works. Each phrase that you type triggers an intent in Dialogflow. Each response by the bot happens after your message has triggered the most likely intent. It’s Dialogflow’s NLP engine that decides which intent best matches your message.

Wouter Sligter, 2020

What’s funny is that even though you typed ‘yes’ in exactly the same way twice, the bot gave you different answers. There are two intents that have been programmed to respond to ‘yes’, but only one of them is selected. This is how we control the flow of a conversation by using context in Dialogflow ES.

Unfortunately the way we program context into a bot on Dialogflow ES is not supported by any visual tools like the diagram above. Instead we need to type this context in each intent without seeing the connection to other intents. This makes the creation of complex bots quite tedious and that’s why we map out the design of our bots in other tools before we start building in ES.

The newer Dialogflow CX allows for a more advanced way of managing the conversation. By adding flows and pages as additional control tools we can now visualize and control conversations easily within the CX platform.

source: https://cloud.google.com/dialogflow/cx/docs/basics

This entire diagram is a ‘flow’ and the blue blocks are ‘pages’. This visualization shows how we create bots in Dialogflow CX. It’s immediately clear how the different pages are related and how the user will move between parts of the conversation. Visuals like this are completely absent in Dialogflow ES.

It then makes sense to use different flows for different conversation paths. A possible distinction in flows might be “ordering” (as seen here), “FAQs” and “promotions”. Structuring bots through flows and pages is a great way to handle complex bots and the visual UI in CX makes it even better.

At the time of writing (October 2020) Dialogflow CX only supports English NLP and its pricing model is surprisingly steep compared to ES. But bots are becoming critical tech for an increasing number of companies and the cost reductions and quality of conversations are enormous. Building and managing bots is in many cases an ongoing task rather than a single, rounded-off project. For these reasons it makes total sense to invest in a tool that can handle increasing complexity in an easy-to-use UI such as Dialogflow CX.

This article aims to give insight into the tech behind bot creation and Dialogflow is used merely as an example. To understand how I can help you build or manage your conversational assistant on the platform of your choice, please contact me on LinkedIn.

Source: https://chatbotslife.com/how-does-it-know-some-beginner-chatbot-tech-for-newbies-fa75ff59651f?source=rss—-a49517e4c30b—4

Continue Reading

AI

Who is chatbot Eliza?

Between 1964 and 1966 Eliza was born, one of the very first conversational agents. Discover the whole story.

Published

on


Frédéric Pierron

Between 1964 and 1966 Eliza was born, one of the very first conversational agents. Its creator, Joseph Weizenbaum was a researcher at the famous Artificial Intelligence Laboratory of the MIT (Massachusetts Institute of Technology). His goal was to enable a conversation between a computer and a human user. More precisely, the program simulates a conversation with a Rogérian psychoanalyst, whose method consists in reformulating the patient’s words to let him explore his thoughts himself.

Joseph Weizenbaum (Professor emeritus of computer science at MIT). Location: Balcony of his apartment in Berlin, Germany. By Ulrich Hansen, Germany (Journalist) / Wikipedia.

The program was rather rudimentary at the time. It consists in recognizing key words or expressions and displaying in return questions constructed from these key words. When the program does not have an answer available, it displays a “I understand” that is quite effective, albeit laconic.

Weizenbaum explains that his primary intention was to show the superficiality of communication between a human and a machine. He was very surprised when he realized that many users were getting caught up in the game, completely forgetting that the program was without real intelligence and devoid of any feelings and emotions. He even said that his secretary would discreetly consult Eliza to solve his personal problems, forcing the researcher to unplug the program.

Conversing with a computer thinking it is a human being is one of the criteria of Turing’s famous test. Artificial intelligence is said to exist when a human cannot discern whether or not the interlocutor is human. Eliza, in this sense, passes the test brilliantly according to its users.
Eliza thus opened the way (or the voice!) to what has been called chatbots, an abbreviation of chatterbot, itself an abbreviation of chatter robot, literally “talking robot”.

Source: https://chatbotslife.com/who-is-chatbot-eliza-bfeef79df804?source=rss—-a49517e4c30b—4

Continue Reading

AI

FermiNet: Quantum Physics and Chemistry from First Principles

Weve developed a new neural network architecture, the Fermionic Neural Network or FermiNet, which is well-suited to modeling the quantum state of large collections of electrons, the fundamental building blocks of chemical bonds.

Published

on

Unfortunately, 0.5% error still isn’t enough to be useful to the working chemist. The energy in molecular bonds is just a tiny fraction of the total energy of a system, and correctly predicting whether a molecule is stable can often depend on just 0.001% of the total energy of a system, or about 0.2% of the remaining “correlation” energy. For instance, while the total energy of the electrons in a butadiene molecule is almost 100,000 kilocalories per mole, the difference in energy between different possible shapes of the molecule is just 1 kilocalorie per mole. That means that if you want to correctly predict butadiene’s natural shape, then the same level of precision is needed as measuring the width of a football field down to the millimeter.

With the advent of digital computing after World War II, scientists developed a whole menagerie of computational methods that went beyond this mean field description of electrons. While these methods come in a bewildering alphabet soup of abbreviations, they all generally fall somewhere on an axis that trades off accuracy with efficiency. At one extreme, there are methods that are essentially exact, but scale worse than exponentially with the number of electrons, making them impractical for all but the smallest molecules. At the other extreme are methods that scale linearly, but are not very accurate. These computational methods have had an enormous impact on the practice of chemistry – the 1998 Nobel Prize in chemistry was awarded to the originators of many of these algorithms.

Fermionic Neural Networks

Despite the breadth of existing computational quantum mechanical tools, we felt a new method was needed to address the problem of efficient representation. There’s a reason that the largest quantum chemical calculations only run into the tens of thousands of electrons for even the most approximate methods, while classical chemical calculation techniques like molecular dynamics can handle millions of atoms. The state of a classical system can be described easily – we just have to track the position and momentum of each particle. Representing the state of a quantum system is far more challenging. A probability has to be assigned to every possible configuration of electron positions. This is encoded in the wavefunction, which assigns a positive or negative number to every configuration of electrons, and the wavefunction squared gives the probability of finding the system in that configuration. The space of all possible configurations is enormous – if you tried to represent it as a grid with 100 points along each dimension, then the number of possible electron configurations for the silicon atom would be larger than the number of atoms in the universe!

This is exactly where we thought deep neural networks could help. In the last several years, there have been huge advances in representing complex, high-dimensional probability distributions with neural networks. We now know how to train these networks efficiently and scalably. We surmised that, given these networks have already proven their mettle at fitting high-dimensional functions in artificial intelligence problems, maybe they could be used to represent quantum wavefunctions as well. We were not the first people to think of this – researchers such as Giuseppe Carleo and Matthias Troyer and others have shown how modern deep learning could be used for solving idealised quantum problems. We wanted to use deep neural networks to tackle more realistic problems in chemistry and condensed matter physics, and that meant including electrons in our calculations.

There is just one wrinkle when dealing with electrons. Electrons must obey the Pauli exclusion principle, which means that they can’t be in the same space at the same time. This is because electrons are a type of particle known as fermions, which include the building blocks of most matter – protons, neutrons, quarks, neutrinos, etc. Their wavefunction must be antisymmetric – if you swap the position of two electrons, the wavefunction gets multiplied by -1. That means that if two electrons are on top of each other, the wavefunction (and the probability of that configuration) will be zero.

This meant we had to develop a new type of neural network that was antisymmetric with respect to its inputs, which we have dubbed the Fermionic Neural Network, or FermiNet. In most quantum chemistry methods, antisymmetry is introduced using a function called the determinant. The determinant of a matrix has the property that if you swap two rows, the output gets multiplied by -1, just like a wavefunction for fermions. So you can take a bunch of single-electron functions, evaluate them for every electron in your system, and pack all of the results into one matrix. The determinant of that matrix is then a properly antisymmetric wavefunction. The major limitation of this approach is that the resulting function – known as a Slater determinant – is not very general. Wavefunctions of real systems are usually far more complicated. The typical way to improve on this is to take a large linear combination of Slater determinants – sometimes millions or more – and add some simple corrections based on pairs of electrons. Even then, this may not be enough to accurately compute energies.

Source: https://deepmind.com/blog/article/FermiNet

Continue Reading
AI8 hours ago

How does it know?! Some beginner chatbot tech for newbies.

AI8 hours ago

Who is chatbot Eliza?

AI22 hours ago

FermiNet: Quantum Physics and Chemistry from First Principles

AI1 day ago

How to take S3 backups with DejaDup on Ubuntu 20.10

AI2 days ago

How banks and finance enterprises can strengthen their support with AI-powered customer service…

AI2 days ago

GBoard Introducing Voice — Smooth Texting and Typing

AI3 days ago

Automatically detecting personal protective equipment on persons in images using Amazon Rekognition

AI3 days ago

Automatically detecting personal protective equipment on persons in images using Amazon Rekognition

AI3 days ago

Automatically detecting personal protective equipment on persons in images using Amazon Rekognition

AI3 days ago

Automatically detecting personal protective equipment on persons in images using Amazon Rekognition

AI3 days ago

Automatically detecting personal protective equipment on persons in images using Amazon Rekognition

AI3 days ago

Automatically detecting personal protective equipment on persons in images using Amazon Rekognition

AI3 days ago

Automatically detecting personal protective equipment on persons in images using Amazon Rekognition

AI3 days ago

Automatically detecting personal protective equipment on persons in images using Amazon Rekognition

AI3 days ago

Automatically detecting personal protective equipment on persons in images using Amazon Rekognition

AI3 days ago

Automatically detecting personal protective equipment on persons in images using Amazon Rekognition

AI3 days ago

Automatically detecting personal protective equipment on persons in images using Amazon Rekognition

AI3 days ago

Automatically detecting personal protective equipment on persons in images using Amazon Rekognition

AI3 days ago

Automatically detecting personal protective equipment on persons in images using Amazon Rekognition

AI3 days ago

Automatically detecting personal protective equipment on persons in images using Amazon Rekognition

Trending