Difference between revisions of "Category:Robotic"

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Here you can find a very brief overview of robots used in manufacturing. It talks about what is it that makes a machine a robot, what differentiates the various types of robots, different ways robots can move, and three types of power sources for robots.
 
  
[[File:Iaac robotic fabrication.jpg]]
 
 
Iaac - Robotic fabrication workshop with Tom Pawlofsky. 2013
 
 
 
[[File:RoboFab 2018 - Robot Intro_Página_02.jpg]]
 
 
=== The term Robot ===
 
Karl Capek coined the term robot in 1920. He was a Czech playwright who wrote R.U.R. which stands for Rosumovi Univerzální Roboti (Rossum’s Universal Robots).
 
 
=== Robots ===
 
 
'''What is a robot?'''
 
 
Rather than defining what a robot is right away, let's pause for a moment and discuss
 
whether we need to answer a question like this after all. Everybody knows the hat a
 
a robot is some sort of a machine that can move around depending on what movie
 
you saw or which book you read, it can either help humans in their day-to-day life or
 
mean the end of humanity.
 
It's clear that there is some controversy and lots of misunderstandings about robots
 
and their role in the past, present, and the future. In order to better understand the
 
situation, let's first examine closely the term "robot" itself. Then, we will try to define
 
it a bit more formally to prevent any misunderstanding or controversy.
 
History of the term robot
 
The term "robot" was used for the first time by Karel Čapek, a Czech writer in
 
his play Rossum's Universal Robots (R.U.R) that he wrote in 1920, to denote an
 
artificial human made out of synthetic organic matter. These robots (roboti in Czech)
 
were made in factories and their purpose was to replace human workers. While
 
they were very efficient and executed orders they were given perfectly, they lacked
 
any emotion. It seemed that humans would not need to work at all because robots
 
seemed to be happy to work for them. This changed after a while and a robot revolt
 
result in the ed in the extinction of the human race.
 
R.U.R is quite dark and disturbing, but it does not leave the future hopeless.
 
It was considered quite a success back in the day and we certainly do recommend
 
you to read it. As its copyright had already expired in many countries at the time of
 
writing this book, it should not be a problem to find a version online, which is in the
 
public domain.
 
 
''"When he (Young Rossum) took a look at human anatomy he saw immediately
 
that it was too complex and that a good engineer could simplify it. So he undertook
 
to redesign anatomy, experimenting with what would lend itself to omission or
 
simplification. Robots have a phenomenal memory. If you were to read them a
 
twenty-volume encyclopedia they could repeat the contents in order, but they never
 
think up anything original. They'd make fine university professors."''
 
– Karel Capek, R.U.R. (Rossum's Universal Robots), 1920
 
 
While many attribute the term robot to Karel Čapek as he wrote the play in which it
 
appeared for the first time, there are sources suggesting that it was actually Čapek's
 
brother Josef who came up with the term (it seems that there was an article in Czech
 
daily print written by Karel Čapek himself, in which he wants to set the record
 
straight by telling this story). Karel wanted to use the term laboři (from Latin labour,
 
work), but he did not like it. It seemed too artificial to him, so he asked his brother
 
for advice. Josef suggested robotic and that was what Karel used in the end.
 
 
Now that we know when the term robot was used for the first time and who actually
 
created it, let's find out where does it come from. The explanation that many use is that
 
it comes from the Czech words robota and robotník, which literally means "work" and
 
"worker" respectively. However, the word robota also means "work" or "serf labour" in
 
Slovak. Also, we should take into account that some sources suggest that by the time
 
Karel was writing R.U.R, he and his brother often visited his father in a small Slovak
 
spa town called Trenčianske Teplice. Therefore, it might very well be that the term
 
robot was inspired by the usage of the word "robota" in the Slovak language, which is
 
coincidental, the native language of one of the authors of this book.
 
 
Whether the term robot comes from Czech or Slovak, the word robota might be a
 
matter of national pride, but it does not concern us too much. In both cases, the literal
 
meaning is "work", "labour", or "hard work" and it was the purpose of the Čapek's
 
robots. However, robots have evolved dramatically over the past hundred years. To
 
say that they are all about doing hard work would probably be an understatement.
 
So, let's try to define the notion of a robot as we perceive it today.
 
 
'''Modern definition of a robot'''
 
 
When we try to find a precise definition of some term, our first stop is usually some
 
sort of encyclopedia or a dictionary. Let's try to do this for the term robot.
 
Our first stop will be Encyclopedia Britannica. Its definition of a robot is as follows:
 
 
''"Any automatically operated machine that replaces human effort, though it
 
might not resemble human beings in appearance or perform functions in a
 
humanlike manner."''
 
 
This is quite a nice definition, but there are quite a few problems with it.
 
First of all, it's a bit too broad. By this definition, a washing machine should also be
 
considered a robot. It does operate automatically (well, most of them do), it does
 
replace human effort (although not by changing the same tasks a human would do),
 
and it certainly does not resemble a human.
 
 
Secondly, it's quite difficult to imagine what a robot actually is after reading this
 
definition. With such a broad definition, there are way too many things that can be
 
considered a robot and this definition do not provide us with any specific features.
 
It turns out that while Encyclopedia Britannica's definition of a robot does not fit our
 
needs well enough, it's actually one of the best ones that one can find. For example,
 
The Free Dictionary defines a robot as "A mechanical device that sometimes resembles a
 
human and is capable of performing a variety of often complex human tasks on command or
 
by being programmed in advance."
 
 
This is even worse than what we had and it seems that a washing machine should still be considered a robot.
 
The inherent problem with these definitions is that they try to capture a vast amount
 
of machines that we call robots these days. The result is that it's very difficult, if not
 
impossible, to come up with a definition that will be comprehensive enough and
 
not include a washing machine at the same time. John Engelberger, founder of the
 
world's first robotics company and industrial robotics (as we know it today) once
 
famously said, "I can't define a robot, but I know one when I see one."
 
 
So, is it even possible to define a robot? Maybe not in general. However, if we limit
 
ourselves just to the scope of this book, there may be a definition that will suit our
 
needs well enough. In her very nice introductory book on the subject of robotics
 
called The Robotics Primer (which we also highly recommend), Maja J. Mataric uses
 
the following definition:
 
 
''"A robot is an autonomous system which exists in the physical world, can sense its
 
environment, and can act on it to achieve some goals."''
 
 
At first sight, it might not seem like a vast improvement over what we have so far,
 
but let's dissect it part by part to see whether it meets our needs.
 
The first part says, "A robot is an autonomous system". By autonomous, we mean
 
that a robot makes decisions on its own—it's not controlled by a human. This
 
already seems to be an improvement as it weeds out any machine that's controlled
 
by someone (such as our famous washing machine). Robots that we will talk about
 
throughout this book may sometimes have some sort of a remote function, which
 
allows a human to control it remotely, but this functionality is usually built-in as
 
sort of a safety measure so that if something goes wrong and the robot's autonomous
 
systems fail to behave as we would expect them to, it's still possible to get the robot
 
to safety and diagnose its problems afterwards. However, the main goal still stays
 
the same, that is, to build robots that can take some direction from humans and are
 
able to act and function on their own.
 
However, just being an autonomous system will certainly not be enough for a robot
 
in this book. For instance, we can find many computer programs that we can call
 
autonomous systems (they are not controlled by an individual and make decisions
 
on their own) and yet we do not consider them to be robots.
 
To get around this obstacle, we need the other part of the sentence that says, "which
 
exists in the physical world".
 
 
Given the recent advances in the fields of artificial intelligence and machine
 
learning, there is no shortage of computer systems that act on their own and
 
perform some work for us, which is what robots should be for. As a quite notorious
 
example, let's consider spam filters. These are computer programs that read every
 
e-mail that reaches your e-mail address and decides whether you may want to read
 
it (and that the e-mail is indeed legitimate) or whether it's yet another example of an
 
unwanted e-mail.
 
 
There is no doubt that such a system is helpful (if you disagree, try to read some
 
of the e-mails in your Spam folder—I am pretty sure it will be a boring read). It's
 
estimated that over 60 per cent of all e-mail traffic in 2014 can be attributed to spam
 
e-mails. Being able to automatically filter them can save us a lot of reading time.
 
Also, as there is no human involved in the decision process (although, we can help
 
it by marking an e-mail as spam), we can call such a system as autonomous. Still,
 
we will not call it a true robot. Rather, we call them "software robots" or just "bots"
 
(the fact that their name is shorter may come from the fact that they are short of the
 
physical parts of true robots).
 
 
While software robots are definitely an interesting group on its own, it's the physical
 
world in which robots operate that makes the process of creating them so exciting
 
and difficult at the same time. When creating a software robot, you can count on the
 
fact that the environment it will run in (usually the operating system) will be quite
 
stable (as in, not too many things may change unexpectedly). However, when you
 
are creating a real robot, you can never be sure.
 
This is why a real robot needs to know what is happening in the environment in
 
which it operates. Also, this is why the next part of the definition says, "can sense
 
its environment".
 
 
Sensing what is happening around a real robot is arguably its most important
 
feature. To sense their surrounding environments, robots usually have sensors.
 
These are devices that measure physical characteristics of the environment and
 
provide this information back to the robot so that it can, for instance, react to sudden
 
changes of temperature, humidity, or pressure. This is quite a big difference from
 
software robots. While they just get the information they need in order to operate
 
somewhat magically, real robots need to have a subsystem or subsystems that take
 
care of obtaining this information. If we look at the differences between robots and
 
humans, we will not find many (in our very high-level view, of course). We can think
 
of sensor subsystems as artificial replacements for human organs that provide this
 
sort of information to the brain.
 
 
One important consequence of this definition is that anything that does not sense
 
its environment cannot be called a robot. This includes any devices that just "drive
 
blind" or move in a random fashion because they do not have any information from
 
the environment to base their behaviour on.
 
Any roboticist will tell you that robots are very exciting machines. Many will
 
also, argue that what makes them so exciting is actually their ability to interact
 
with the outside world (which is to move or otherwise change the environment
 
they are in). Without this, they are just another static machine that might be useful,
 
but rather unexciting.
 
 
Our definition of a robot reflects this in its last part when it says, "can act on it to
 
achieve some goals".
 
 
Acting on the environment might sound like a very complex task for a robot, but in
 
this case, it just means changing the world in some (even very slight) way. We call
 
these parts of robots that perform this as effectors. If we look at our robot vs human
 
comparison, effectors are the artificial equivalents of hands, legs, and other body
 
parts that allow it to move. Effectors make use of some lower-level systems such
 
as motors or muscles that actually carry out the movement. We call them actuators.
 
Although, the artificial ones may seem to function similar to the biological ones, a
 
closer look will reveal that they are actually quite different.
 
You may have noticed that this part is not only about acting on the robot's
 
environment, but also about achieving some goals. While many hobby roboticists
 
build robots just for the fun of it, most robots are built in order to carry out (or, should
 
we rather say, to help with) some tasks, such as moving heavy parts in a factory or
 
locating victims in areas affected by natural disasters.
 
 
As we said before, a system or a machine that behaves randomly and does not use
 
information from its environment cannot really be considered a robot. However,
 
how can it use this information somehow? The easiest thing to do is to do
 
something useful, which we can rephrase as trying to reach some goal that we
 
consider useful, which in turn brings us back to our definition. A goal of a robot does
 
not necessarily need to be something as complex and ambitious as "hard labour for
 
human". It can easily be something simple, such as "do not bump into obstacles" or
 
"turn the light switch on".
 
 
Now, as we have at least a slight idea of what a robot is, we can move on to briefly
 
discuss where robots come from, in other words, the history of robotics.
 
 
'''Where do robots come from?'''
 
 
As the title suggests, this part of the chapter should be about the history of robots.
 
We already know a few quite important facts, such as the term robot was coined by
 
a Czech author Karel Čapek in 1920. As it turns out, there are many more interesting
 
events that happened over the years, other than this one. In order to keep things
 
organized, let's start from the beginning.
 
 
It's quite difficult to pinpoint a precise date in history, which we can mark as the
 
date of birth of the first robot. For one, we have established quite a restrictive
 
definition of a robot previously; thus, we will have to wait until the 20th century to
 
actually see a robot in the proper sense of the word. Until then, let's at least discuss
 
the honourable mentions.
 
 
The first one that comes close to a robot is a mechanical bird called "The Pigeon".
 
This was postulated by a Greek mathematician Archytas of Tarentum in the 4th
 
century BC and was supposed to be propelled by steam. It cannot be considered
 
a robot by our definition (not being able to sense its environment already disqualifies
 
it), but it comes pretty comes for its age. Over the following centuries, there were
 
many attempts to create automatic machines, such as clocks measuring time
 
using the flow of water, life-sized mechanical figures, or even first programmable
 
humanoid robots (it was actually a boat with four automatic musicians on it). The
 
problem with all these is that they are very disputable as there is very little (or none)
 
historically trustworthy information available about these machines.
 
 
It would have stayed like this for quite some time if it was not for Leonardo
 
Da Vinci's notebooks that were rediscovered in the 1950s. They contain a complete
 
drawing of a 1945 humanoid (a fancy word for a mechanical device that resembles
 
humans), which looks like an armoured knight. It seems that it was designed so that
 
it could sit up, wave its arms, move its head, and most importantly, amuse royalty.
 
In the 18th century, following the amusement line, Jacques de Vaucanson created
 
three automata: a flute player that could play twelve songs, a tambourine player,
 
and the most famous one, "The Digesting Duck". This duck was capable of moving,
 
quacking, flapping wings, or even eating and digesting food (not in a way you
 
will probably think—it just released matter stored in a hidden compartment).
 
It was an example of "moving anatomy"—modeling human or animal anatomy using
 
mechanics.
 
 
Our list will not be complete if we omitted these robot-like devices that came
 
about in the following century. Many of them were radio-controlled, such as Nikola
 
Tesla's boat, which he showcased at Madison Square Garden in New York. You
 
could command it to go forward, stop, turn left or right, turn its lights on or off, and
 
even submerge. All of this did not seem too impressive at that time because the press
 
reports attributed it to "mind control".
 
 
At this point, we have once again reached the time when the term robot was used for
 
the first time. As we said many times before, it was in 1920 when Karel Čapek used it
 
in his play, R.U.R. Two decades later, another very important term was coined. Issac
 
Asimov used the term robotics for the first time in his story "Runaround" in 1942.
 
Asimov wrote many other stories about robots and is considered to be a prominent
 
sci-fi author of his time.
 
 
However, in the world of robotics, he is known for his three laws of robotics:
 
 
• First law: A robot may not injure a human being or through inaction allow a
 
human being to come to harm.
 
 
• Second Law: A robot must obey the orders given to it by human beings,
 
except where such orders would conflict with the first law.
 
 
• Third law: A robot must protect its own existence, as long as such protection
 
does not conflict with the first or second law.
 
 
After a while, he added a zeroth law:
 
 
• Zeroth law: A robot may not harm humanity or by inaction allow humanity
 
to come to harm.
 
 
These laws somehow reflect the feelings people had about machines they called
 
robots at that time. Seeing enslavement by some sort of intelligent machine as a
 
real possibility, these laws were supposed to be some sort of guiding principles one
 
should at least keep in mind, if not directly follow when designing a new intelligent
 
machine. Also, while many were afraid of the robot apocalypse, the time has shown that
 
it's still yet to come. In order for it to take place, machines will need to get some sort
 
of intelligence, some ability to think and act based on their thoughts. Also, while we
 
can see that over the course of history, the mechanical side of robots went through
 
some development, the intelligence simply was not there yet.
 
This was part of the reason why in the summer of 1956, a group of very wise
 
gentlemen (which included Marvin Minsky, John McCarthy, Herbert Simon, and
 
Allan Newell) was later called to be the founding fathers of the newly founded field
 
of Artificial Intelligence. It was at this very event where they got together to discuss
 
creating intelligence in machines (thus, the term artificial intelligence).
 
 
Although, their goals were very ambitious (some sources even mention that their
 
idea was to build this whole machine intelligence during that summer), it took quite
 
a while until some interesting results could be presented.
 
One such example is Shakey, a robot built by the Stanford Research Institute
 
(SRI) in 1966. It was the first robot (in our modern sense of the word) capable to
 
reason its own actions. The robots built before this usually had all the actions they
 
could execute preprogrammed. On the other hand, Shakey was able to analyze
 
a more complex command and split it into smaller problems on his own.
 
 
The following image of Shakey is taken from https://en.wikipedia.org/wiki/
 
File:ShakeyLivesHere.jpg:
 
 
[[File:Learning Robotics using Python- shakey.jpg]]
 
 
Shakey, resting in the Computer History Museum in Mountain View, California
 
 
His hardware was quite advanced too. He had collision detectors, sonar range
 
finders, and a television camera. He operated in a small closed environment of
 
rooms, which were usually filled with obstacles of many kinds. In order to navigate
 
around these obstacles, it was necessary to find a way around these obstacles while
 
not bumping into something. Shakey did it in a very straightforward way.
 
 
At first, he carefully planned his moves around these obstacles and slowly
 
(the technology was not as advanced back then) tried to move around them.
 
Of course, getting from a stable position to movement wouldn't be possible without
 
some shaky moves. The problem was that Shakey's movements were mostly of this
 
shakey nature, so he could not be called anything other than Shakey.
 
The lessons learned by the researchers who were trying to teach Shakey how
 
to navigate in his environment turned out to be very important. It comes as no
 
surprise that one of the results of the research on Shakey is the A* search algorithm
 
(an algorithm that can very efficiently find the best path between two goals). This is
 
considered to be one of the most fundamental building blocks not only in the field of
 
robotics or artificial intelligence but also in the field of computer science as a whole.
 
Our discussion on the history of robotics can go on and on for a very long time.
 
Although one can definitely write a book on this topic (as it's a very interesting one),
 
it's not this book; we shall try to get back to the question we tried to answer, which
 
was: where do robots come from?
 
 
In a nutshell, robots evolved from the very basic mechanical automation through
 
remotely-controlled objects to devices or systems that can act (or even adopt) on
 
their own in order to achieve some goal. If this sounds way too complicated, do not
 
worry. The truth is that to build your own robot, you do not really need to deeply
 
understand any of this. The vast majority of robots you will encounter are built from
 
simple parts that are not difficult to understand when you see the big picture.
 
So, let's figure out how we will build our own robot. Let's find out what are the
 
robots made of.
 
 
'''What can we find in a robot?'''
 
 
In the very first part of this chapter, we tried to come up with a good (modern)
 
definition of a robot. It turns out that the definition we came up with does not
 
only describe a robot as we know it (or would like to know it), but also gives us
 
some great pointers as to what parts can we most definitely find in (or on) a robot.
 
Let's see our definition again:
 
"A robot is an autonomous system which exists in the physical world, can sense its
 
environment, and can act on it to achieve some goals."
 
So, what will these most important parts be? Here is what we think should be on
 
this list.
 
 
=== Basic terminologies ===
 
 
'''Work Cell''': All the equipment needed to perform the robotic process (robot, table, fixtures, etc.)
 
 
'''Work Envelope''': All the space the robot can reach.
 
 
Degrees of Freedom: The number of movable motions in the robot. To be considered a robot there needs to be a minimum of 4 degrees of freedom. The Kuka Agilus robots have 6 degrees of freedom.
 
 
'''Payload''': The amount of weight a robot can handle at full arm extension and moving at full speed.
 
 
'''End Effector''': The tool that does the work of the robot. Examples: Welding gun, paint gun, gripper, etc.
 
 
[[File:End_effector.JPG]]
 
 
'''Manipulator''': The robot arm (everything except the End of Arm Tooling).
 
 
'''TCP''': Tool Center Point. This is the point (coordinate) that we program in relation to.
 
 
Positioning Axes: The first three axes of the robot (1, 2, 3). Base / Shoulder / Elbow = Positioning Axes. These are the axes near the base of the robot.
 
 
Orientation Axes: The other joints (4, 5, 6). These joints are always rotary. Pitch / Roll / Yaw = Orientation Axes. These are the axes closer to the tool.
 
 
'''Coordinates Systems'''
 
 
[[File:RoboFab 2018 - Robot Intro_Página_09.jpg]]
 
 
=== Classification ===
 
 
Industrial robots can be classified into six categories based on the following characteristics:
 
 
Degrees of Freedom
 
Arm Geometry
 
Power Source
 
Types of Motion
 
Path Control
 
Intelligence
 
 
'''Degrees of Freedom'''
 
 
The number of movable motions in a robot defines its degrees of freedom. In articulated robots such as those in the Fab Lab have at least 6 degrees of freedom. These joints, or axes, are broken into two categories. The three joints nearest the base of the manipulator are called the positioning axes. The three closest to the tool are called the orientation axes. Robots can have larger degrees of freedom by having external axes, for instance, the entire robot can be mounted on a sledge which moves along a track. This would be the seventh degree of freedom.
 
 
'''Arm geometry'''
 
 
The arm geometry, that is the configuration and type of joints used, determines the shape of the work envelope.
 
 
Rectangular (Cartesian)
 
The work envelope is a box. All three axes are linear.
 
 
[[File:Rectangular.jpg]]
 
 
 
Cylindrical
 
The work envelope is a cylinder. Axis 1 is rotary. Other axes are linear.
 
 
[[File:Cylindrical.jpg]]
 
 
SCARA
 
This is a variation of a cylindrical work envelope robot. SCARA is an acronym for Selective Compliance Articulated Robot Arm. Joints 1 and 2 of this type are rotary and in the same plane. Joint 3 is linear.  These are often called Pick and Place robots.
 
 
[[File:SCARA.jpg]]
 
 
 
Spherical
 
This type of arm geometry produces a ball-shaped work envelope.
 
Axes 1 and 2 are rotary. Axis 3 is linear.
 
 
[[File:Spherical.jpg]]
 
 
Articulated
 
This type of arm geometry, which is what we use in the Fab Lab is also referred to as Jointed Spherical.
 
 
[[File:Articulated.jpg]]
 
 
 
'''Types of Motion'''
 
 
Robot Programming allows us to develop several motion types:
 
 
[[File:RoboFab 2018 - Robot Intro_Página_12.jpg]]
 
 
 
- PTP: POINT TO POINT
 
 
The robot guides the TCP along the fastest path to the endpoint. The fastest path is generally not the shortest path and is thus not a straight line. As the motions of the robot axes are rotational, curved paths can be executed faster than straight paths. The exact path of the motion cannot be predicted.
 
 
- CIRC: Circular
 
 
The robot guides the TCP at a defined velocity along a circular path to the endpoint. The circular path is defined by a start point, auxiliary point and endpoint.
 
 
- LIN: Linear
 
 
The robot guides the TCP at a defined velocity along a straight path to the end point. This path is predictable.
 
 
'''Singularities'''
 
 
This is a condition in which the manipulator loses one or more degrees of freedom and change in joint variables does not result in change in end effector location and orientation variables. This is a case when the determinant of the Jacobian matrix is zero ie. It is a rank deficit.
 
 
Intuitively, Singularities play a significant role in the design and control of robot manipulators. Singularities of the kinematic
 
mapping, which determines the position of the end–effector in terms of the manipulator’s joint variables, may impede control algorithms, lead to large joint velocities, forces and torques and reduce instantaneous mobility.
 
 
However they can also enable fine control, and the singularities exhibited by trajectories of the points in the end–effector can be used to mechanical advantage. A number of attempts have been made to understand kinematic singularities and, more specifically, singularities of robot manipulators, using aspects of the singularity theory of smooth maps.
 
 
[[File:RoboFab 2018 - Robot Intro_Página_13.jpeg]]
 
 
'''Power source'''
 
 
The three most common method of powering robots are air pressure (pneumatic), fluid pressure (hydraulics) and electricity.
 
The main characteristics of each of these methods are listed below:
 
 
Pneumatic
 
 
Weakest
 
Fastest
 
Clean
 
Inexpensive
 
Low Tech
 
Open loop (non-servo)
 
Stop-to-stop for path control
 
Uses hard-stops determine program locations
 
Loud - referred to as "bang bang" robots
 
 
Hydraulic
 
 
Most powerful (greatest payload)
 
Messy to repair
 
Closed loop (servo)
 
More flexible than pneumatic
 
Mid-range in noise
 
Oil used can contaminate paints
 
Most expensive (have to buy both hydraulic and electronic systems)
 
Most costly to repair (have to fix both hydraulic and electronic systems)
 
 
Electric
 
 
Most popular
 
Clean
 
Quiet
 
Closed loop (servo motors)
 
Most flexible
 
Can use sealed motors for painting
 
 
'''Robotic Processes'''
 
 
To make working with robots easier for everybody, the Iaac Atelier Lab has divided the workflow into two groups: ''Existing Robotic processes'' and ''New Robotic processes''. The existing robotic processes are processes which have been tested in the recent past, which means they can be easily accessed but still have to be checked with the lab about their current usage. New robotic process is techniques still not developed / in process, so they might need extra support for setting up. It is to be considered that they would need additional time for calibration.
 
 
Following are the Existing Robotic Processes :
 
 
[[File:Robotic_processes.jpg]]
 
 
 
All this information is coming from:
 
 
Alexandre Dubor,
 
 
Kunal Chadha,
 
 
Ricardo Mayor Luque
 
 
and many people at IAAC
 
 
Learning Robotics Using Python, Lentin Joseph. Packt Publishing Ltd, May 27, 2015.
 
 
Singularities of Robot Manipulators. Peter Donelan
 
 
and http://mkmra2.blogspot.com/
 
 
[[Category:Technologies]][[Category:Robotic]]
 

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