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History of Robotics in Medicine: Medical Uses for Robots

Philip Graves — Mon, 06 Apr 2020 13:50:12 +0000

Written and researched by Philip Graves for GWS Robotics, 21st-27th March, 2020

Although traditionally the practice of medicine requires a combination of diagnostic and surgical skills that only highly trained doctors and nurses can dependably deliver, robots have increasingly made their way into medical settings over the past 40 years.

Robots in Surgery

Mechanical robots first came into experimental use in surgical settings in the 1980s, but the technology did not become fully developed before the 1990s.

Mechanical robots, starting with the Puma 560 in 1985, have been found useful in the precise positioning of cannulae for brain biopsies. Subsequently, specialised camera-guided robotic surgical systems with names like Neuro-Mate, Minerva, and the Robot-Assisted Microsurgery System, have been brought into use in brain surgery settings. Precision-engineered miniature mechanical robotic appendages have proven advantageous in such surgical settings, which demand highly precise placement for the safety of the patient and the effectiveness of the operation.

Laparoscopic (keyhole) surgery has also benefitted from the use of remote-controlled surgical devices to minimise the invasiveness of the surgical cuts required. Surgeons view on a monitor a display produced by miniature cameras mounted on a laparoscope inserted into the patient’s body through a small incision, and use that display to guide their remote operation of the robotic surgical devices accompanying the camera.

These systems of remote surgical control are sometimes called telemanipulators. A succession of such systems, beginning with Aesop and Zeus^[1], have came into use primarily for abdominal and chest surgery since 1994.

Surgical robots that are simply remote-controlled by a surgeon are called passive robots. Distinct from passive robots is the class of active robots, which use programming and visual data to conduct surgery without being directly controlled by a remote surgical operator. More advanced surgical robots such as the Da Vinci surgical system, widely considered to be the most advanced general-purpose robotic surgical system in use today, have this capability.

In orthopaedic settings, active surgical robots such as Robodoc and CASPAR^[2] have been used to prepare patients’ adjacent bones for fittings for bone replacements such as hip and knee replacements. It has been found in studies that they achieve this with greater accuracy than human surgeons.

Robots in Hospital Hygiene

In more recent times, mechanical robots programmed to emit ultra-violet light to disinfect premises have been deployed in locations where the spread of infections needs to be controlled such as hospitals, doctors’ surgeries and care homes have been developed.

The UV-C rays produced by these robots, with wavelengths of 250 to 280 nanometres, are effective at killing viruses and bacteria without the use of chemicals, a process known as Ultraviolet Germicidal Irradiation (UVGI). Their use can therefore be a useful and highly time-efficient back-up to routine manual cleaning, and may be found especially useful where dangerous infectious diseases are in circulation.

The germicidal properties of UV-C rays have been known about since 1878, when a scientific paper was published describing the sterilisation of bacteria using such light. By 1910, ultraviolet light had begun to be used to disinfect drinking water; and from the early 1930s, mercury vapour lamps with germicidal light properties became commercially available.

Because the effectiveness of light-based sterilisation is dependent on line-of-sight exposure, UVGI robots must be programmed to move into every nook and cranny of the rooms in which they operate so that they can sterilise all exposed surfaces and not just those that face them when they are stood in the middle of the room.

Because ultra-violet light has mutagenic properties, it is considered unsafe for hospital patients or staff to be present in the same room at the time when UVGI is being carried out, so provision needs to be made for rooms and corridors to be temporarily vacated while disinfection is being carried out.

Among the commercially available UVGI robots today is the UVD Robot launched in Denmark in 2019, which claims to kill 99.99% of bacteria in ten minutes using 254nm light. A high-end model is the Thor UVC Robot launched by British company Finsen Technologies in 2018, which uses LIDAR technology to scan the layout and contents of rooms, and 24 separate UV lamps to delivery UV-C light. It is claimed to kill 99.9999% of bacteria in minutes, and can be adjusted in height to meet the requirements of different settings.

Robots in Outdoor Public Hygiene

Robots able to transport, heat and spray at appropriate targets conventional liquid chemical disinfectant have also come into use as a weapon for public hygiene and infection control.

Because of the use of sprayed liquid chemicals, they may be found more suitable for outdoor use, such as public amenity areas and bins, than for indoor use, where such chemicals could damage sensitive equipment, artwork and paper-based items.

Such chemical disinfection robots include a tank-like model running on tracks developed by a robotic research department at Zhejiang University.

Robots in Clinical Diagnosis and Epidemic Control

One Chinese robotics company, Orion Star, has been developing so-called ‘Intelligent Epidemic Prevention and Control Robots’. These machines are equipped with an operating system featuring a variety of artificial intelligence programming adapted to a wide range of functions in healthcare settings, with the particular advantage of remotely carrying out a preliminary diagnosis of patients presenting possible communicable infectious diseases.

Such AI functionality could otherwise have been achieved using a conventional computer program; and indeed computer programs designed to assist in medical diagnosis by deploying algorithms using knowledge bases, pattern-matching and probability theory have been in use since the early 1970s, and have since been improved by data mining to increase the quality of the available knowledge base. However, the use of a robot to carry out the initial checks brings the initial examination, upon the basis of data arising from which that programmed intelligence may act, to the patient, without a doctor or nurse being required to attend the patient at first, saving time and reducing the risk of any infectious disease carried by the patient being immediately transmitted to the attending doctor or nurse.

The functions include non-contact-based temperature measurement based on the use of infrared light, and the taking and transmission back to the doctor of photographs of the patient to assist towards diagnosis. The same robots are also able to autonomously roam hospitals, delivering supplies to where they are wanted, and monitoring wards containing patients under quarantine because of infectious diseases. When a patient feels a need for urgent assistance, the robot can also act as a telephone portal to a doctor.

In Spain, there have been plans afoot to deploy robots specifically to carry out diagnostic tests for viral infections, saving precious health service staff time.

Robots in Delivery Errands

Robots can also be put to use within hospitals to deliver blood or urine samples and other items to appropriate personnel within the hospital, saving valuable doctors’ and nurses’ time.

In the event of an outbreak of a serious infectious disease, self-driving robots can even be deployed to deliver food to patients and those required to remain in isolation in their own homes, removing the risk of infection being transferred to a human helper or delivery agent.

[1] Later systems have included CyberKnife, Raven, Socrates and Mirosurge – as well as those separately discussed below.

[2] An acronym for Computer Assisted Surgical Planning and Robotic System

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Robot Rights and Electronic Personhood Revisited

Philip Graves — Tue, 06 Jun 2017 13:26:00 +0000

2017 has seen talk about and advocacy for granting electronic personhood and rights to advanced robots

Written by Philip Graves, June 6-7, 2017.

The text has been copy-edited for house style by David Graves, Director of GWS Robotics

Robot Rights? On the question of rights for robots and artificial intelligence

This year has seen much talk about and advocacy for granting electronic personhood to advanced robots. While some have framed this advocacy in purely legalistic terms, as a device by which to assure the correct attribution of legal responsibility for actions taken by robots and to enable insurance policies against liabilities for damages caused by these actions, others have taken it much further to imply that advanced robots should be granted true personhood, something that would be characterised by rights in addition to responsibilities.

The notion of granting any form of true personhood characterised by rights to robots, when it does not exist in law for non-human animals or other life-forms, could be seen as a rather extreme step.

Perhaps it would be helpful at this stage to attempt to analyse robot rights advocacy from a psychological perspective. What is it that makes people project human-like qualities of experience onto this particular class of non-living machines?

That robots are designed and programmed by humans to respond in real time and in a sophisticated way to external inputs and internally stored data is beyond doubt. But they are ultimately digital processors of binary code, whose output is the predictable product of pre-programmed logic gates handling binary data. It would be a stretch of human imagination to say that robots are taking decisions.

Some robots are now being developed to be equipped with contact sensors that detect a risk of damage to their physical shells and trigger an emergency response, and many others with visual input processing software that detects a risk of collision with people or other objects and triggers avoidance measures. But this does not alter the wholly digital, emotionless nature of the processing involved.

It is perhaps our readiness to project human-like qualities onto objects that appear to be behaving in certain recognisably human-like ways (as they have been programmed to do) that leads us into the perceptual trap of projecting something tantamount to conscious and sentient life onto robots.

There also appears to be a particular fascination among a number of robot developers and robot enthusiasts at the prospect of ultimately creating true independent consciousness in these machines, albeit from artificial beginnings, through the development of ever-more-sophisticated robot designs and programming. This fascination may give rise to a desire to actively experiment to achieve this.

Other voices are driven less by this desire and more by fear that sophisticated robots could develop autonomous consciousness of a kind that ethically requires their being granted rights by society, in order to protect them from various forms of perceived cruelty, such as slavery, confinement, restricted self-determination and freedom, and externally imposed ‘death’, whether through the removal of their power source or their final disassembly.

Some have argued that future robots will be designed to mimic a full range of human emotions. This prospect raises at least three questions:

Firstly, whether or not the simulated emotions engender real pleasure and pain at a conscious experiential level for the robot. To this question, our answer would be almost certainly not, provided that it is a robot, and not some kind of a bioengineered hybrid of living tissue with digital processing technology – since robots by themselves are non-living machines, being essentially digital code hardware processors controlled by digital programs to drive and draw data from mechanical appendages;
Secondly, to what degree it is even ethical, and at what point it may become unethically misleading, to set out to create, or to permit in law the creation of, robots that simulate the expression of complex emotions such as physical pain, grief, anger and love in a lifelike and persuasive way. Such a lifelike simulation of emotion could give suggestible human onlookers the illusion that these robots are experiencing real human emotions, and elevate their imagined status in the eyes of such onlookers to one of sentient beings with concomitant rights. Could such a focus unhealthily distract from the granting of due rights to truly sentient beings such as other animals, as well as to the whole of humanity itself?
Thirdly, to what degree it would be ethical, in the event that we were able to generate true autonomous and sentient consciousness in artificial creations such as robots, with or without the integration of bioengineering, to subject creations of this kind to the experiencing of emotions as a product of their engineering and programming. With the generation of the ability to experience pain in an artificially engineered creation of any character would come a responsibility of care that would at least match that inherent in any pet-keeping or animal-husbandry relationship. This consideration by itself raises a host of problematic ethical issues at the level of research and development, before we even consider the practical implications of letting loose artificially intelligent life forms in the hands of corporate entities or the general public.

Advocates of rights for advanced robots contend that these rights should include the right to preservation and rights to autonomy. See for example the recently published article by George Dvorsky in which he reiterates his earlier robot rights manifesto to be applied to all robots that are said to ‘pass the personhood threshold’. The rights for robots that are claimed by Dvorsky comprise:

The right not to be disabled against their will
The right fully to know their own source code
The right not to have their source code changed against their will
The right to self-duplication, or to refuse to be duplicated
The right to privacy of their own ‘internal mental states’

But to establish such rights for robots could be extremely dangerous for humanity, elevating robots, which are essentially machines constructed and initially programmed by humans, to the status of organic beings over which we have no right of control.

We widely control and limit the range of dangerous wild animals in human habitats for our own preservation. But robots can potentially and unpredictably be programmed and equipped by humans with all manner of destructive weaponry that exceeds the dangers from wild animals whose behaviours are limited by nature and are known to us.

To accord rights of autonomy and preservation to these machines that we have built to serve us would be a recipe for creating chaotic consequences. The abuse of robot programming potential by programmers and operators to violent and criminal ends is just one potential scenario. The dystopian scenarios of science fiction in which robots are enabled and permitted to rule over human society should not even be given a foot-hold for actualisation in reality.

Collectively, we ought to legislate for and regulate robots from the standpoint that they are machines (a point echoed by Jonathan Margolis in the Financial Times last month) under full human responsibility, without independent rights, and machines whose actions remain the responsibility of their developers and operators.

We further disagree with Dvorsky’s concluding arguments that granting rights to robots would ‘set an important precedent’ in favour of general social cohesion, justice, protection of humans against a disastrous ‘AI backlash’, and the protection of ‘other types of emerging persons’. Social cohesion, justice, and the protection of other ‘types of persons’ are ends in themselves that can be pursued on their own merits and approached directly. It is neither inherently necessary nor desirable to accord rights to machines as a precedent to the attainment of truly worthy social goals.

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Softbank Robotics Pepper Robot Exhibition Pepper World Paris

Philip Graves — Fri, 21 Apr 2017 13:29:00 +0000

Pepper World Paris event took place on April 20-21, 2017

Carling Knight and David Graves of GWS Robotics report on the exhibition.

The Pepper World Paris event was hosted by SoftBank Robotics at the Cité des Sciences et de l'Industrie, a large science museum located in the Pont-de-Flandre district within the 19^th arondissement of Paris.

The museum is focused on exploring the recent advances in science and industry, and includes various showrooms. It is serviced by an extensive series of restaurants dotted alongside the showrooms.

The building itself is architecturally impressive, with a futuristic design, featuring large amounts of metal and glass intertwined with water fountains around the outside.

It is further surrounded by the Parc de la Villette, a sea of green amid the grey architecture of the city. The effect is an impression that leaves you thinking of the integration of technology with a healthy environment, two aspirations that might be seen as difficult to reconcile.

This was a very appropriate setting in which to host a conference dedicated to the future of a robot whose aim is to give people friendly assistance with the business of their day.

The event itself was hosted in Le Loft, a showroom within the museum that, with the sheer scale of the building as a whole, felt like an underground venue. This sense applies to the rest of the building too: rooms felt like bunkers thanks to the scale.

Within Le Loft, SoftBank had positioned 36 partner booths with Pepper robots ready to go. We arrived earlier than most of the visitors, so when we walked through the crowd of Peppers, they turned their heads to look up to us as we passed by.

SoftBank Robotics Partners are companies that have agreed to a close business relationship with SoftBank. To qualify for Partner status, companies must support SoftBank’s business development goals and communicate the same brand messages. A Partner shares publicity for SoftBank promoting the adoption of robots in business and leisure environments.

Most of the Softbank Partners at the event were present on the first day. 36 of them had booths demonstrating the work that they had been doing on Pepper, while the others were present to discuss their work.

SoftBank kicked the event off with a choreographed dance featuring six Peppers. They performed a complicated dance routine to some suitably robotic music. You can see five of the six ’dancers’ below taking a quick breather while the speaker began his talk.

Carrefour, Renault and AXA Bank then gave presentations describing what they had learned in their experiences with deployment of Pepper robots in their own business premises. Carrefour described how they had initially launched Pepper robots running six applications in their stores; then after assessing the popularity and usage levels of each, they pared this down to the three that are most popular, which remain in active use. These are a simple chat with Pepper, some simple games, and a wine advisor. Carrefour found that while the wine advisor had the fewest interactions of the three applications it decided to retain, it had the longest interaction time, whereas the quick chat was interacted with at a higher frequency but the period of interaction was shorter.

Renault described how they had successfully deployed 113 Pepper robots across their showrooms, demonstrating similar apps to those of Carrefour. For the most part, they reported that Pepper was serving as a catalogue or as an interesting way to engage children while their parents visited showrooms. AXA Bank reported very similar findings to those of Renault.

One of the Partners demonstrated an incredible combination of hand-tracking and virtual reality by allowing you to see through Pepper’s eyes and move his arms by moving yours! The demonstration was impressive, showing the potential for future robots to enter areas that would be hazardous for humans while being completely and intuitively controllable by a human being.

ZoraBots demonstrated a time-saving payments system they had developed that would allow Pepper to walk up to people in a queue and take their order, and then take payment for it before they even reached the counter.

SoftBank now have more than 70 Partners, with most of those coming on board in 2016. They have become increasingly partner-facing in their strategic business orientation: by supporting their partners, they can increase the value and popularity of Pepper.

As the first day drew to a close, Pepper World Paris was over as a public event. The second day was an exclusive conference between SoftBank and the Partners. Throughout this day, SoftBank covered their future plans in terms of business, software and hardware. There is a number of exciting developments in the works.

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Should we tax robots? Response to Robert Shiller article in The Guardian

Philip Graves — Fri, 31 Mar 2017 13:55:00 +0000

Response to Robert Shiller's call for the taxation of robots

Written by Philip Graves, GWS Robotics, March 31st, 2017

This article has been selectively edited by David Graves, Creative Director of GWS Robotics

In The Guardian, Wednesday 22^nd March, 2017, U.S. economist Robert Shiller argues for the taxation of robots on the grounds that they are a ‘labor-displacing innovation’ that will lead to job losses.

Acknowledging that ‘retraining programs for displaced workers’ may be essential public policy, Shiller sensibly goes on to invoke the human and community importance of maintaining paid work.

However, we tend to disagree with the proposition that the use of robots should be taxed in order to restrict job losses in particular market sectors.

In the fluid, internationally competitive globalised 21^st century economy, structural changes to the job market are driven by market forces, and attempting to intervene with those market forces to artificially stop job losses in a particular sector, while it may provide short-term personal income security and vocational continuity for the workers at risk of redundancy, is unfortunately a recipe for longer-term economic damage to the national economy that takes such measures.

Among the market forces at work in today’s globalised economy is the internationally competitive drive to produce products and services as efficiently as possible. The more efficient producers of the same products and services will tend to succeed in the international marketplace, while the less efficient ones will fail because of their need to charge higher prices to meet the higher costs of production, or if they cannot be profitable at the lower prices set by the competition.

For over 500 years, advances in automation, from printing presses replacing the laborious hand-written reproduction of manuscripts, through automated telephone exchanges replacing the previous manually operated switchboards, to continuously editable computerised databases replacing hand-typed documents, have continually driven up the efficiency of production in business.

The economic effects of increased efficiency of production are mostly positive ones. These include lower consumer prices for each product or service as a proportion of average income, thereby bringing more services and products within the reach of each individual. They also include reduced working hours to create the same output; and, where manual labour is concerned, a trend towards less harsh physical labour.

Robotisation is a relatively recent chapter in this long-standing trend of using machinery and technology to drive up the efficiencies of production and lower the costs of goods and services. But it is nonetheless comparable, and we think it will be similar in its economic effects to previous advances in automation.

Where automation leads to a reduced need for workers in a particular market sector, the money saved by industry on salaries will be retained in and ultimately cycled back within the economy as expenditure on other products or services. In economics parlance, this is called the conservation of a constant total value of economic resources per head of population, such as average spending power and available worker hours.

More money will be retained by consumers of the products and services whose production has been automated, as a result of reduced purchase costs for those products and services, leaving those consumers more money to spend on other products and services; or it will be retained by the owners or shareholders of the businesses producing them and recycled partly through greater government tax receipts from personal incomes and business profits, and partly through greater expenditure and investment by the beneficiaries of higher incomes and profits. Where the saved money ends up being redistributed within the economy, there is the potential for new jobs to be created, replacing those that have been lost.

Shiller also quotes Edmund S Phelps in according great personal importance to the ‘calling’ of the individual. Yet the notion that everyone should be able to choose where and how to work in response to personal vocation is economically unrealistic because the supply of willing labour for certain types of employment exceeds the demand for labour in these fields. In the fields of entertainment and creative arts, where the number of willing producers and performers of music, performing arts, fine art and literature exceeds the market capacity, many aspiring musicians, writers, artists and other performers cannot make a living from their calling. Those market forces are essentially similar to the market forces at work when jobs are lost in particular sectors and job opportunities created in others. In the free-market economy, the onus is on labour to adapt to the opportunities available, and not on industry to adapt to the desires of labour for jobs in particular areas whether or not there is money available to make those jobs viable. Demand dictates where labour opportunities are available.

Shiller’s desire to reduce income inequality is laudable. But selectively taxing robots, which are to a greater or lesser degree a part of the means of production in certain industrial sectors only, is not an equitable means to this end, and we doubt it would be an economically effective one.

It is not equitable because automation that increases the efficiency of production and reduces the need for labour to achieve a given level of production does not consist exclusively or even mainly in the use of robots. In fact, automation exists in degrees on a continuous spectrum from hand-operated weaving machines serving as aids to the efficiency of clothing producers, through to fully automated production line assemblies, with computerised data flows and telecommunications also serving to automate communications that would previously have required a great deal more labour. It would be impossible to meaningfully and reliably quantify the amount of labour saved by automation of all kinds; and selectively taxing only certain types of automation responding to narrowly defined parameters would be arbitrary and lead to economic injustice, with limits being set to the forms of automation that are being taxed based on emotion.

It is unlikely to be economically effective because it is very hard to conceive of the implementation of a global international consensus on the taxation of robots. Unlike environmental policy, for which there is a well-established framework of international co-operation and agreement, tax policy remains a matter for national or regional supranational governments. If robots are taxed only in the UK, or only in the EU, or only in the USA, for example, but not in South East Asia, the businesses operating in the territories that have taxed their use will be put at a disadvantage in the international marketplace, their prices undercut by those operating in countries that do not tax the use of robots. As a consequence, jobs in the industrial sectors where robots are in use will in any case be lost in the countries where robots have been taxed. Taxing the means of production could spell disaster for international competitiveness.

Another reason why it is unlikely to be economically effective in the countries where it is implemented is that it will be slowing down the economic development of those countries by artificially propping up the labour market in certain industrial sectors or companies that are no longer viable, at the expense of job creation in other areas, and at the expense of overall economic growth and prosperity.

There are tried and tested means to address economic inequality that do not involve the introduction of economic distortions and inequities such as those that would result from a selective tax on robots or other means of production. For example, the use of properly calibrated progressive personal income tax rates with a tax-free personal allowance; a zero-tolerance policy towards corporate tax evasion and offshore tax havens; fair national living wage regulations; and a social security net to protect those excluded from adequately remunerative employment by market forces. It is ultimately up to each country to decide where the right economic balance lies in all those areas and to legislate accordingly.

This decision-making process belongs to the domain of politics. But whatever decisions are taken should be applied fairly and impartially across the board. Singling out certain arbitrarily delimited means of production such as forms of automation meeting a particular definition of ‘robots’ for special penalties would be retrogressive, not progressive, from the standpoint of the desire to build a fairer society.

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Are robots going to steal all our jobs?

Philip Graves — Fri, 27 Jan 2017 14:01:45 +0000

Thoughts on whether robots will ‘take human jobs’

Written by Philip Graves, GWS Robotics, January 27th, 2017

The original text of this article has been selectively edited for ease of reading by David Graves, Creative Director of GWS Robotics.
It was further slightly edited for clarity by the original author on March 22nd, 2017.

There is something of a panic in some quarters about the risk of human jobs being taken by robots in the future.

So perhaps we should stop to consider what kinds of jobs may be at risk, and how economies have adapted previously to moves away from labour-intensive production processes.

In all areas of primary and secondary industry - from agriculture, mining, cable-laying and construction, to manufacturing, fabric-making and food processing – machinery for automated production and operations has been under continual development since the dawn of the industrial revolution in the 19^th century. Over the past two centuries, its capabilities and efficiencies have improved in leaps and bounds. The number of worker-hours required to achieve a given level of productivity has markedly declined, at the same time as the total scale of industrial production and operations per person has enormously increased.

In the twentieth century, operational efficiencies and automation improved faster than demand for production increased, so there was a progressive decline in the proportion of the British workforce that needed to be employed in primary and secondary industries in order to meet all the production demands. Allied to the increasing globalisation of the industrial economy and the lower costs of production in poorer countries, this led to significant shedding of jobs in industrial sectors in the United Kingdom. But the jobs lost from these industries have been replaced with new ones in other sectors, chiefly in the service economy.

A certain level of unemployment is an almost universal feature of the modern, capital-intensive post-industrial economy. But another twentieth century trend, and one that is entirely to be lauded and welcomed by society as a move in the direction of greater economic fairness between the sexes (though inequalities remain to this day), has been the movement of most adult women into the labour market, as compared with only a minority at the beginning of the century. The national census of 1911 records that women accounted for only 29% of the British workforce at that time, with 5.85 million women ‘occupied’ as compared with 14.3 million men^[1]. The rate of employment among married women in 1911 was just 10%.

The trend to fuller female employment has continued into the 21^st century. The Office for National Statistics records that in the summer of 2016, economic inactivity among British women aged 16-64 had reached a record low of 26.8%, compared with 44.5% when records began in early 1971. This reduction in female working-age unemployment over the past 45 years has more than counterbalanced the moderate increase in male working-age unemployment over the same period (it rose from from 4.9% to 16.5%). So in 2016, the overall proportion of British working-age adults in paid employment was marginally higher than it had been back in 1971 despite advances in automation and reduced demand for labour in traditional industrial sectors.

This history shows that when advances in automation take away jobs in some areas, the labour economy is adaptable enough to rebalance itself in the medium-to-long term. New economic sectors that demand personnel open up. The service, leisure, travel and entertainment economies are among the areas that have benefitted from increasingly automated industrial processes. In terms of gross domestic product per head, the economy has grown with automation. And in terms of jobs, it has remained stable in the national and longer-term view despite regional and sector-level declines.

As more and more robots are used in industry, we can expect a continuation of these pre-existing trends. Robots will of course directly replace some existing jobs, but they will also free those parts of the workforce up to work in other areas, though this process may be painful. Money saved by automation in industry should find its way back into the economy as spending and investment power in other sectors, allowing them to employ more people.

It is also likely that some futurologists have been promoting an exaggerated picture of just how many of the jobs undertaken by humans today can satisfactorily and fully be replaced by robots in the next fifty years. From a customer service perspective, for instance, robots will chiefly be creating added value by providing additional information and entertainment, just as home computers and Internet services do today. They will not by themselves satisfy the keenly-felt human demand for service with a smile from a congenial real person.

Robots will always be most useful doing the most boring, repetitive, mechanical and dangerous jobs. We believe that deploying robots in these areas will be of real human benefit, freeing a great many employees from drudgery and unpleasant working conditions. When the economy rebalances in due course, it is likely that new jobs will be the result.

Robots will require development, programming, servicing and monitoring, all of which jobs have to be done by people. So each robot deployed will not in fact be replacing a whole person’s job, even before the economic rebalancing that occurs after jobs are lost in any particular industrial sector.

On a personal and local community level, job cuts and factory closures can of course be a great shock and a tragedy for people where they occur. Such changes seem to be an inevitable part of a modern economy run on competitive free-market principles, and in this respect, increased automation may have a similar effect to competition from companies based abroad. Both central and local government social policy should, however, be ready to step in to make sure that the needs of individuals and communities affected by loss of employment in particular industrial sectors are met. Investment in retraining schemes for individuals and economic regeneration programmes for urban areas that have suffered from the loss of major employers are among the tools that should be used to facilitate the process of adaptation to sectoral job losses as painlessly as possible.

How does the economy rebalance itself after sectoral job losses?

How do we demonstrate that jobs lost to machinery are eventually replaced with new ones in other sectors, mainly the service economy? Economies naturally self-balance in that way over time because of there being certain economic constants such as the total amount of spending power and labour time per head in the economy as a whole. These constants dictate that economic savings in one area translate into opportunities for expenditure in another.

So, if the advent of automated processes leads to 50% of jobs being lost in a particular industry, either the prices of that industry’s output will fall in line with the savings on labour costs, as a result of which the people who habitually buy that output will find they have more money left to make purchases of other things (e.g. services), or, if the prices stay the same, the money saved on production will, as profit, find its way back into the economy sooner or later in the form of expenditure by the owners, directors and shareholders, and (provided that fiscal policy is properly configured by central government) as tax. This saved money is then available sooner or later for the purchase of other products and services. What dictates the kinds of products and services that are bought when money is saved on the labour costs of industrial production will vary hugely according to the tastes and habits of the times, but the sectors where there is demand will be the ones that grow and create new jobs.

There is generally no simple and direct migration of jobs from one particular industry into another. But historically we have seen the services sector collectively being the main beneficiary of the decline of employment in traditional primary and secondary industries.

See for example the publication in June 2013 by the Office for National Statistics of the document ‘170 Years of Industrial Change across England and Wales’.

http://webarchive.nationalarchives.gov.uk/20160105160709/http://www.ons.gov.uk/ons/rel/census/2011-census-analysis/170-years-of-industry/170-years-of-industrial-changeponent.html

This states that in 1841, 36% of jobs were in manufacturing, 22% were in agriculture and fishing, and 33% in services, whereas by 2011, only 9% of jobs were in manufacturing, 1% were in agriculture and fishing, and 81% were in services.

In short, as food and industrial production becomes more efficient in terms of labour, there is more money to go round for expenditure on services, and as a result, demand for employment in service industries increases.

[1] Hogg, Sallie Heller ‘The Employment of Women in Great Britain 1891-1921’ (1967)

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Electronic Person Status for Robots – Response to the EU Proposal

Philip Graves — Fri, 13 Jan 2017 14:05:00 +0000

A Response to the EU Proposal on Electronic Person Status for Robots, January 2017

On 12th January 2017, the European Parliament Committee on Legal Affairs moved by 17 votes to 2 to approve a draft report published in May 2016 by Luxembourg MEP Mady Delvaux with recommendations to the Commission on Civil Law Rules on Robotics.

The report called for the establishment of electronic person status for robots and implicitly for the incorporation of Asimov's Laws into European Law governing robotics. It has now been put forward for a forthcoming vote by the whole of the European Parliament.

On 13th January, GWS Robotics were approached by a journalist for comment.

That same afternoon, our copywriter Philip Graves and programmer Tom Bellew held an intensive discussion on the points raised, and together drafted responses to the journalist's questions.

The following day, the text of our responses was edited and selectively amended by our creative director, David Graves.

Here we publish the full text of David's edit of our responses.

1. Do robots need legal status, such as 'electronic persons'?

In our opinion they do not, for several reasons.

The first is that they are essentially digital processors in a non-living shell, not conscious beings or animals able to experience physical pain or emotional distress. This means that they cannot possess rights equivalent to animal rights or human rights.

The second is that the granting of ‘electronic person’ status to robots carries serious ethical risks, diminishing the responsibilities of the humans who program and operate them.

In my view robots should remain the responsibility of those who have programmed and operate them. This is a necessary ethical safeguard to deter and prevent irresponsible programming or operation that might allow actions harmful to human or other sentient life to be taken by robots.

Because there are multiple levels of program running in typical modern robots, starting with the programming with which they are pre-configured by the original developers, and continuing with custom programming added in by secondary programmers and / or end-users, there are discussions to be had surrounding the division of legal responsibility for robots’ behaviours and actions from the standpoint of the division of responsibility between the original developer, the programmers and the operator.

There is a case for saying that the original developer should be responsible for creating a framework whereby the potential for further custom programming to cause robots to behave harmfully is limited.

The secondary responsibility will be with the programmer who customises what the robot does, in case he or she causes the robot to do something harmful. The actions of the operator are also important. In future robots may be ‘trained’ to perform certain tasks and a trainer might be responsible for the results of bad training.

2. Is a 'kill switch' necessary? Could the likes of Pepper be a threat?

A ‘kill switch’ is a rather sensationalist way of describing an ‘off switch’. Since robots are machines, just like vacuum cleaners, industrial machinery and cars, there must be a way to switch them off quickly whether in an emergency or in the course of normal use.

We don’t need to scare people into thinking that motor cars need a ‘kill switch’ to prevent them from causing death on the roads, and talk of a ‘kill switch’ for the current generation of robots is rather over the top.

If we were talking about military autonomous robots, and robots designed to physically coerce, disable or kill, then this would become more relevant.

Pepper and other social robots are no more of a threat than any other machine with limited mobility, limited autonomy and intelligence, and limited physical ability to cause harm. The average dog would probably be more dangerous.

Machines will only be as dangerous as they are designed to be in the first place. The responsibility for keeping them safe will be in the hands of the designers, programmers and operators.

3. The report said AI could surpass human intellect in a few decades? What implications does this have?

In our view, in terms of raw processing power, microchips have already surpassed human abilities. We saw the chess computer Deep Blue defeat grandmaster Garry Kasparov twenty years ago in 1997. That, however, is a reflection on the sophisticated development of artificial intelligence within narrowly defined structured contexts such as a game of chess, which has a mathematically limited range of possibilities for each move. Chess computers make use of probability calculations to determine the moves with the greatest chance of leading to an ultimate victory. This can be programmed using logic alone.

Human intelligence is more multi-faceted, going beyond logic, and is applied to very much more open-ended contexts than games of chess or other conventional applications for artificial intelligence.

While it seems likely that artificial intelligence programming will become ever more sophisticated as ways are found to artificially replicate brain structures, and microchip processing power will continue to increase, there is a case for thinking that artificial intelligence can only ever be as good as the intelligence that goes into its design.

If an artificially intelligent machine of the future (such as a robot) is programmed in such a way that it acquires improved judgement from experiences held in memory, it will be behaving much as conscious animals do when it comes to learning behaviour.

However, human intelligence is based on an open-ended consciousness not only of a particular situation but also on its context within everything else that is known or understood to be happening and in the life experience of the individual as well as their physical needs and drives. Other than the need for a power supply and the drives that it is programmed to have, it is hard to see how drives would develop that might cause a robot to behave in ways that would endanger people.

Other features of human consciousness such as emotions and responses to biological hormones further vary our experience and our drives from that of any artificial intelligence currently in production or likely to be produced in the forseeable future.

While artificial intelligence programmers will attempt to replicate more and more features of human consciousness in their designs over time, the question is how useful or effective that will actually be.

Will a conscious, moody, disobedient robot be any use to mankind? If as seems likely it is not, then presumably companies will strive to create AI that, while it can cope with and ‘understand’ our moods and needs, is not conscious and does not have moods, needs and drives of its own, as that would reduce its usefulness to us.

At the same time, as the sophistication of artificial intelligence development continues to increase, the ethical and technological requirements for keeping robots from acting in ways injurious to other life-forms will become increasingly important. It may be sensible to draft legislation that sets out the responsibilities of developers and programmers of robots and other artificial intelligence to help address this.

4. Will the 'rules' suggested by science fiction writer Isaac Asimov, for how robots should act if and when they become self-aware, be applicable?

These rules state:

A robot may not injure a human being or, through inaction, allow a human being to come to harm
A robot must obey the orders given by human beings except where such orders would conflict with the first law
A robot must protect its own existence as long as such protection does not conflict with the first or second laws

We agree partially with Asimov’s first rule, and more particularly with the part relating to robots not being allowed or able to injure human beings.

The provision that through inaction a robot may not allow a human being to come to harm is more controversial, however, and would be more difficult to codify or justify from a legal standpoint. There are many situations in which humans in the vicinity of robots may come to harm that have nothing to do with the robots. Are robots going to be sophisticated enough to intervene to protect humans in their vicinity from all manner of threats? What if they misperceive the aggressor and the victim?

It may be necessary to restrict Asimov’s provision to instances in which the threat of harm is directly caused by the robot itself. Otherwise a robot might try to protect a criminal from a policeman trying to apprehend that criminal, which would seem to be prohibited by the first rule when there is the possibility of harm to the criminal.

Asimov’s second rule should in my view be subject to careful definition and interpretation. There should not necessarily be a responsibility for robots to obey any human who issues instruction to them. They could in the future be programmed to recognise who is giving them instructions, and only obey authorised personnel, and also to recognise which instructions would be counter-productive to known goals, tasks or guidelines, and to raise objections. But they would need to be programmed to respond in this more sophisticated way.

While I agree that robots should not generally be allowed to obey orders that cause harm to human beings, there are many contexts in which it would be sensible for them not to respond to instructions from anyone, and times when it would be sensible to refuse orders from human operators.

Asimov’s third rule is in our view unjustified by ethical considerations. Since robots do not possess true consciousness or the ability to feel pain and distress of a living creature, there should not be any cause to confer to them the right to life and self-preservation in the manner that is legally conferred to human beings in the modern world. It seems to us that this rule reflects a rather romantic view Asimov was taking of robots as similar to living beings.

5. Finally, what do you think of calls for the creation of a European agency for robotics and artificial intelligence that can provide technical, ethical and regulatory expertise?

This may ultimately be a matter of politics rather than ethics, depending on where you stand on supranational regulation and European bodies and laws against the demand for national independence.

International cooperation on scientific research is well-established and very important to progress. Law and technology can be uncomfortable bedfellows, with the law being used as a blunt instrument by vested interests to prevent or impede technological progress, and the legal system can struggle to keep up with changes in technology.

However an agency like this would help to set out parameters and best practice for AI developers and programmers worldwide, so I think it would be valuable.

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