Tag: autism

The Devil is in the Detail: Lessons from Animal Welfare? (Temple Grandin)

Several cows poking their heads through railings to look at the camera.
Cows image by -Rita-👩‍🍳 und 📷 mit ❤ from Pixabay

What can Computer Scientists learn from a remarkable woman and the improvements she made to animal welfare and the meat processing industry?

Temple Grandin is an animal scientist – an animal welfare specialist and a remarkable innovator on top. She has extraordinary abilities that allow her to understand animals in ways others can’t. As a result her work has reduced the suffering of countless farm animals. She has designed equipment, for example, to restrain animals. It makes it easier to give them shots because, in contrast to the equipment it replaces, it does not discomfort the animals as they enter. By being able to see the detail that an animal perceives she is able to design to overcome the problems. Paradoxically perhaps for someone who cares so much about animals, she works with slaughter houses – Meat Processing factories like those of McDonalds.

Her aim, given people do eat meat, is to ensure the animals are treated humanely throughout the process of rearing an animal until its death. Her work has been close to miraculous in the changes she has brought about to ensure that farm animals do not suffer. She is good for business too. If cattle are spooked by something as they enter the processing factory (also known as a ‘plant’), whether by the glint of metal or a deep shadow, the plant’s efficiency drops. Fewer animals are processed per hour and that is a big problem for managers.

As a result of her work she has turned round plants, both in welfare terms and in terms of rescuing plants that might otherwise have been shut down. Suddenly plants she audits are treating their livestock humanely.

See the Bigger Picture

Where do Temple’s extraordinary abilities come from? In fact she was originally labelled as being mentally disabled. She is actually autistic. As a result her brain doesn’t quite work the way most people’s do. Autistic people as a result of these brain differences often have difficulties socialising with others. They can find it very hard to understand the nuances of human-human communication that the rest of us take for granted. This is in part because autistic people perceive the world differently. A non-autistic person misses vast amounts of the detail in front of their eyes. Instead just a bigger picture of what they are seeing is passed to their conscious selves. An autistic person doesn’t have that sub-conscious ability to filter out detail, but instead perceives every small thing all at once. That is why autistics can sometimes be overcome by their surroundings, finding the world too much to cope with. They think in terms of a series of pictures full of detail, not abstractly in words.

Temple Grandin argues that that is what makes her special when it comes to understanding farm animals. In some ways they see the world very much like she does. Just as a cow does, she notices the shadows and the glint of metal, the bright patch on the floor from the overhead lights or the jacket laid over the fence that is spooking it. The plant managers and animal handlers don’t even register them never mind see them as a problem.

Who ya gonna call?

Because of this ability to quickly spot the problems everyone else has missed, Temple gained a reputation for being the person to call when a problem seemed intractable. She has also turned it into a career as an animal welfare auditor, checking processing plants to ensure their standards are sufficiently high. This is where she has helped force through the biggest improvements, and it all boils down to checklists.


Tick that box

Checking that lists of guidelines are being adhered to is a common way to audit quality in many areas of life. Checklists are used in a computer science context as checks for usability (for example that a new version of some application is easy to use) and accessibility (could a blind person, or for that matter someone who was autistic, successfully use a website say). Checklists tend to be very long. After all it must be the case that the more you are checking, the higher the quality of the result, mustn’t it? Surprisingly that turns out not always to be true! That is why Temple Grandin has been so successful. Rather than have a checklist with hundreds of things to check she boiled her own set of questions to ask down to just 10.

Traditional animal welfare audits have checklist questions such as “Is the flooring slippery?” and “Is the electric prod used as little as possible?”. Even apart from the number to work through this kind of checklist can be very hard to follow, not least due to the vagueness.

Ouch!

Temple’s checklist includes questions like: “Do all animals remain unconscious after being stunned?”, “Do no more than 3% of animals vocalise during handling or stunning?” (a “Moo” in this situation means “Ouch”) They are precise, with little room for dispute – it isn’t left to the inspectors judgement. That also means everyone knows the target they are working towards. The fact that there are only 10 also means it is easy for everyone involved to know them all well. Perhaps most importantly they do not focus on the state of the factory, or the way things are done. Instead, they focus on the end results – that animals are humanely treated. The point is that one item covers a multitude of sins that could be causing it. If too many animals are crying out in pain then you have to fix ALL the causes, even if it is something new that no-one thought of putting on a checklist before.

Temple’s 10 point approach to checklists can apply to more than just animal welfare of course. The principles behind it could just as well apply to other areas like usability and accessibility of websites.

Some usability evaluation techniques do follow similar principles. Cognitive Walkthrough, a method of auditing that systems are easy to use on first encounter, has some of the features of this kind of approach. The original version involved a longish set of questions that an expert was to ask him/herself about a system under evaluation. After early trials the developers of the method Cathleen Wharton, John Rieman, Clayton Lewis and Peter Polson quickly realised this wasn’t very practical and replaced it by a 4 question version. It has since then even been replaced by a 3-question walkthrough. One of the questions, to be asked of each step in achieving a task, is: “Will a user know what to try and do at this point?” This has some of the flavour of the Grandin approach – it is about the end result not about some specific thing going wrong.

Let’s look at accessibility. Currently, where web designers think about it at all (UK law requires them to) the long checklist approach tends to be followed. Typical items to check are things like “Ensure that all information conveyed with colour is also available without colour”. Automatic systems are often used to do audits. That is good in one sense as the criteria have then to be very precise for a mere computer to make the decision. On the other hand it encourages items in the checklist to just be things a computer can check. It also encourages the long list of fine detail approach that Temple rejected. Worse, it also can lead to people conforming to the checklist without deeply understanding what the point actually is. A classic example is a web designer adding as the last item on a web page “If you are partially sighted click here”. As far as an automatic checker is concerned they may have done everything right – even providing alternative facilities that are clearly available (if you can see them). A partially sighted person however would only get to that instruction on the screen after they have struggled through the rest of the page. The designer got the right idea but missed the point.

Temple Grandin’s approach would suggest instead having checklists that ask about the outcomes of using the page: “Do 97% of partially-sighted people successfully complete their objective in using the site?” for example. That is why “user testing” is so important, at least as one of the evaluation approaches you follow. User testing involves people from a wide variety of backgrounds actually trying using your prototype software or web pages before they are released. It allows you to focus on the big picture. Of course if you are trying to ensure a web page is accessible your users must include people with different kinds of disabilities.


The Big Picture

One of Temple Grandin’s main messages is that the big advantage that arises as a result of her autism is that she thinks in concrete pictures not in abstract words. Whilst thinking verbally is good in some situations it seems to make us treat small things as though they were just as important as the big issues.

So whatever you are doing, whether looking after animals or designing accessible websites, don’t get lost in the detail. Focus on the point of it all.

Paul Curzon, Queen Mary University of London

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EPSRC supports this blog through research grant EP/W033615/1.

Future Friendly: Focus on Kerstin Dautenhahn

by Peter W McOwan, Queen Mary University of London

(from the archive)

Large robot facing a man in his home
Robot at home Image by Meera Patil from Pixabay

Kerstin Dautenhahn is a biologist with a mission: to help us make friends with robots. Kerstin was always fascinated by the natural world around her, so it was no surprise when she chose to study Biology at the University of Bielefeld in Germany. Afterwards she went on to study a Diploma in Biology where she did research on the leg reflexes in stick insects, a strange start it may seem for someone who would later become one of the world’s foremost robotics researchers. But it was through this fascinating bit of biology that Kerstin became interested in the ways that living things process information and control their body movements, an area scientists call biological cybernetics. This interest in trying to understand biology made her want to build things to test her understanding, these things would be based on ideas copied from biological animals but be run by computers, these things would be robots.

Follow that robot

From humble beginning building small robots that followed one another over a hilly landscape, she started to realise that biology was a great source of ideas for robotics, and in particular that the social intelligence that animals use to live and work with each other could be modelled and used to create sociable robots.

She started to ask fascinating questions like “What’s the best way for a robot to interrupt you if you are reading a newspaper – by gesturing with its arms, blinking its lights or making a sound?” and perhaps most importantly “When would a robot become your friend?” First at the University of Hertfordshire, now a Professor at the University of Waterloo she leads a world famous research group looking to try and build friendly robots with social intelligence.

Good robot / Bad robot – East vs West

Kerstin, like many other robotics researchers, is worried that most people tend to look on robots as being potentially evil. If we look at the way robots are portrayed in the movies that’s often how it seems: it makes a good story to have a mechanical baddie. But in reality robots can provide a real service to humans, from helping the disabled, assisting around the home and even becoming friends and companions. The baddie robot ideas tends to dominate in the west, but in Japan robots are very popular and robotics research is advancing at a phenomenal rate. There has been a long history in Japan of people finding mechanical things that mimic natural things interesting and attractive. It is partly this cultural difference that has made Japan a world leader in robot research. But Kerstin and others like her are trying to get those of us in the west to change our opinions by building friendly robots and looking at how we relate to them.

Polite Robots roam the room

When at the University of Hertfordshire, Kerstin decided that the best way to see how people would react to a robot around the house was to rent a flat near the university, and fill it with robots. Rather than examine how people interacted with robots in a laboratory, moving the experiments to a real home, with bookcases, biscuits, sofas and coffee tables, make it real. She and her team looked at how to give their robots social skills: what was the best way for a robot to approach a person, for example? At first they thought that the best approach would be straight from the front, but they found that humans felt this too aggressive, so the robots were trained to come up gently from the side. The people in the house were also given special ‘comfort buttons’, devices that let them indicate how they were feeling in the company of robots. Again interesting things happened, it turned out that not all, but quite a lot of people were on the whole happy for these robots to be close to themselves, closer in fact than they would normally let a human approach. Kerstin explains ‘This is because these people see the robot as a machine, not a person, and so are happy to be in close proximity. You are happy to move close to your microwave, and it’s the same for robots’. These are exciting first steps as we start to understand how to build robots with socially acceptable manners. But it turns out that robots need to have good looks as well as good manners if they are going to make it in human society.

Looks are everything for a robot?

This fall in acceptability
is called the ‘uncanny valley’

How we interact with robots also depends on how the robots look. Researchers had found previously that if you make a robot look too much like a human being, people expect it to be a human being, with all the social and other skills that humans have. If it doesn’t have these, we find interaction very hard. It’s like working with a zombie, and it can be very frightening. This fall in acceptability of robots that look like, but aren’t quite, human is what researchers call the ‘uncanny valley’, so people prefer to encounter a robot that looks like a robot and acts like a robot. Kerstin’s group found this effect too, so they designed their robots to look and act they way we would expect robots to look and act, and things got much more sociable. But they are still looking at how we act with more human like robots and built KASPAR, a robot toddler, which has a very realistic rubber face capable of showing expressions and smiling, and video camera eyes that allow the robot to react to your behaviours. He possesses arms so can wave goodbye or greet you with a friendly gesture. Most recently he was extended with multi-modal technology that allowed several children to play with him at the same time, He’s very lifelike and their hope was hopefully as KASPAR’s programming grew, and his abilities improved he, or some descendent of him, would emerge from the uncanny valley to become someone’s friend, and in particular, children with autism.

Autism – mind blindness and robots

The fact that most robots at present look like and act like robots can give them a big advantage to help them support children with autism. Autism is a condition that prevents you from developing an understanding of how to interact socially with the world. A current theory to explain the condition is that those who are autistic cannot form a correct understanding of others intentions, it’s called mind blindness. For example, if I came into the room wearing a hideous hat and asked you ‘Do you like my lovely new hat?’ you would probably think, ‘I don’t like the hat, but he does, so I should say I like it so as not to hurt his feelings’, you have a mental model of my state of mind (that I like my hat). An autistic person is likely to respond ‘I don’t like your hat’, if this is what he feels. Autistic people cannot create this mental model so find it hard to make friends and generally interact with people, as they can’t predict what people are likely to say, do or expect.

Playing with Robot toys

It’s different with robots, many autistic children have an affinity with robots. Robots don’t do unexpected things. Their behaviour is much simpler, because they act like robots. Using robots Kerstin’s group examined how we can use this interaction with robot toys to help some autistic children to develop skills to allow them to interact better with other people. By controlling the robot’s behaviours some of the children can develop ways to mimic social skills, which may ultimately improve their quality of life. There were some promising results, and the work continues to be only one way to try and help those suffering with this socially isolating condition.

Future friendly

It’s only polite that the last word goes to Kerstin from her time at Hertfordshire:

‘I firmly believe that robots as assistants can potentially be very useful in many application areas. For me as a researcher, working in the field of human-robot interaction is exciting and great fun. In our team we have people from various disciplines working together on a daily basis, including computer scientists, engineers and psychologist. This collaboration, where people need to have an open mind towards other fields, as well as imagination and creativity, are necessary in order to make robots more social.’

In the future, when robots become our workmates, colleagues and companions it will be in part down to Kerstin and her team’s pioneering effort as they work towards making our robot future friendly.

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EPSRC supports this blog through research grant EP/W033615/1, and through EP/K040251/2 held by Professor Ursula Martin.