Good morning. I’m here today to talk about autonomous, flying beach balls. No, agile aerial robots like this one. I’d like to tell you a little bit about the challenges in building these and some of the terrific opportunities for applying this technology. So these robots are related to unmanned aerial vehicles. However, the vehicles you see here are big. They weigh thousands of pounds, are not by any means agile. They’re not even autonomous. In fact, many of these vehicles are operated by flight crews that can include multiple pilots, operators of sensors and mission coordinators.
What we’re interested in is developing robots like this — and here are two other pictures — of robots that you can buy off the shelf. So these are helicopters with four rotors and they’re roughly a meter or so in scale and weigh several pounds. And so we retrofit these with sensors and processors, and these robots can fly indoors without GPS.
The robot I’m holding in my hand is this one, and it’s been created by two students, Alex and Daniel. So this weighs a little more than a tenth of a pound. It consumes about 15 watts of power. And as you can see, it’s about eight inches in diameter. So let me give you just a very quick tutorial on how these robots work.
So it has four rotors. If you spin these rotors at the same speed, the robot hovers. If you increase the speed of each of these rotors, then the robot flies up, it accelerates up. Of course, if the robot were tilted, inclined to the horizontal, then it would accelerate in this direction. So to get it to tilt, there’s one of two ways of doing it. So in this picture you see that rotor four is spinning faster and rotor two is spinning slower. And when that happens there’s moment that causes this robot to roll. And the other way around, if you increase the speed of rotor three and decrease the speed of rotor one, then the robot pitches forward.
And then finally, if you spin opposite pairs of rotors faster than the other pair, then the robot yaws about the vertical axis. So an on-board processor essentially looks at what motions need to be executed and combines these motions and figures out what commands to send to the motors 600 times a second. That’s basically how this thing operates.
So one of the advantages of this design is, when you scale things down, the robot naturally becomes agile. So here R is the characteristic length of the robot. It’s actually half the diameter. And there are lots of physical parameters that change as you reduce R. The one that’s the most important is the inertia or the resistance to motion. So it turns out, the inertia, which governs angular motion, scales as a fifth power of R. So the smaller you make R, the more dramatically the inertia reduces. So as a result, the angular acceleration, denoted by Greek letter alpha here, goes as one over R. It’s inversely proportional to R. The smaller you make it the more quickly you can turn.
So this should be clear in these videos. At the bottom right you see a robot performing a 360 degree flip in less than half a second. Multiple flips, a little more time. So here the processes on board are getting feedback from accelerometers and gyros on board and calculating, like I said before, commands at 600 times a second to stabilize this robot. So on the left, you see Daniel throwing this robot up into the air. And it shows you how robust the control is. No matter how you throw it, the robot recovers and comes back to him.
So why build robots like this? Well robots like this have many applications. You can send them inside buildings like this as first responders to look for intruders, maybe look for biochemical leaks, gaseous leaks. You can also use them for applications like construction. So here are robots carrying beams, columns and assembling cube-like structures. I’ll tell you a little bit more about this. The robots can be used for transporting cargo. So one of the problems with these small robots is their payload carrying capacity. So you might want to have multiple robots carry payloads. This is a picture of a recent experiment we did — actually not so recent anymore — in Sendai shortly after the earthquake. So robots like this could be sent into collapsed buildings to assess the damage after natural disasters, or sent into reactive buildings to map radiation levels.
So one fundamental problem that the robots have to solve if they’re to be autonomous is essentially figuring out how to get from point A to point B. So this gets a little challenging because the dynamics of this robot are quite complicated. In fact, they live in a 12-dimensional space. So we use a little trick. We take this curved 12-dimensional space and transform it into a flat four-dimensional space. And that four-dimensional space consists of X, Y, Z and then the yaw angle.
And so what the robot does is it plans what we call a minimum snap trajectory. So to remind you of physics, you have position, derivative, velocity, then acceleration, and then comes jerk and then comes snap. So this robot minimizes snap. So what that effectively does is produces a smooth and graceful motion. And it does that avoiding obstacles. So these minimum snap trajectories in this flat space are then transformed back into this complicated 12-dimensional space, which the robot must do for control and then execution.
So let me show you some examples of what these minimum snap trajectories look like. And in the first video, you’ll see the robot going from point A to point B through an intermediate point. So the robot is obviously capable of executing any curve trajectory. So these are circular trajectories where the robot pulls about two G’s. Here you have overhead motion capture cameras on the top that tell the robot where it is 100 times a second. It also tells the robot where these obstacles are. And the obstacles can be moving. And here you’ll see Daniel throw this hoop into the air, while the robot is calculating the position of the hoop and trying to figure out how to best go through the hoop. So as an academic, we’re always trained to be able to jump through hoops to raise funding for our labs, and we get our robots to do that.
(Applause)
So another thing the robot can do is it remembers pieces of trajectory that it learns or is pre-programmed. So here you see the robot combining a motion that builds up momentum and then changes its orientation and then recovers. So it has to do this because this gap in the window is only slightly larger than the width of the robot. So just like a diver stands on a springboard and then jumps off it to gain momentum, and then does this pirouette, this two and a half somersault through and then gracefully recovers, this robot is basically doing that. So it knows how to combine little bits and pieces of trajectories to do these fairly difficult tasks.
So I want change gears. So one of the disadvantages of these small robots is its size. And I told you earlier that we may want to employ lots and lots of robots to overcome the limitations of size. So one difficulty is how do you coordinate lots of these robots? And so here we looked to nature. So I want to show you a clip of Aphaenogaster desert ants in Professor Stephen Pratt’s lab carrying an object. So this is actually a piece of fig. Actually you take any object coated with fig juice and the ants will carry them back to the nest. So these ants don’t have any central coordinator. They sense their neighbors. There’s no explicit communication. But because they sense the neighbors and because they sense the object, they have implicit coordination across the group.
So this is the kind of coordination we want our robots to have. So when we have a robot which is surrounded by neighbors — and let’s look at robot I and robot J — what we want the robots to do is to monitor the separation between them as they fly in formation. And then you want to make sure that this separation is within acceptable levels. So again the robots monitor this error and calculate the control commands 100 times a second, which then translates to the motor commands 600 times a second. So this also has to be done in a decentralized way. Again, if you have lots and lots of robots, it’s impossible to coordinate all this information centrally fast enough in order for the robots to accomplish the task. Plus the robots have to base their actions only on local information, what they sense from their neighbors. And then finally, we insist that the robots be agnostic to who their neighbors are. So this is what we call anonymity.
So what I want to show you next is a video of 20 of these little robots flying in formation. They’re monitoring their neighbors’ position. They’re maintaining formation. The formations can change. They can be planar formations, they can be three-dimensional formations. As you can see here, they collapse from a three-dimensional formation into planar formation. And to fly through obstacles they can adapt the formations on the fly. So again, these robots come really close together. As you can see in this figure-eight flight, they come within inches of each other. And despite the aerodynamic interactions of these propeller blades, they’re able to maintain stable flight.
(Applause)
So once you know how to fly in formation, you can actually pick up objects cooperatively. So this just shows that we can double, triple, quadruple the robot strength by just getting them to team with neighbors, as you can see here. One of the disadvantages of doing that is, as you scale things up — so if you have lots of robots carrying the same thing, you’re essentially effectively increasing the inertia, and therefore you pay a price; they’re not as agile. But you do gain in terms of payload carrying capacity.
Another application I want to show you — again, this is in our lab. This is work done by Quentin Lindsey who’s a graduate student. So his algorithm essentially tells these robots how to autonomously build cubic structures from truss-like elements. So his algorithm tells the robot what part to pick up, when and where to place it. So in this video you see — and it’s sped up 10, 14 times — you see three different structures being built by these robots. And again, everything is autonomous, and all Quentin has to do is to get them a blueprint of the design that he wants to build.
So all these experiments you’ve seen thus far, all these demonstrations, have been done with the help of motion capture systems. So what happens when you leave your lab and you go outside into the real world? And what if there’s no GPS? So this robot is actually equipped with a camera and a laser H finder, laser scanner. And it uses these sensors to build a map of the environment. What that map consists of are features — like doorways, windows, people, furniture — and it then figures out where its position is with respect to the features. So there is no global coordinate system. The coordinate system is defined based on the robot, where it is and what it’s looking at. And it navigates with respect to those features.
So I want to show you a clip of algorithms developed by Frank Shen and Professor Nathan Michael that shows this robot entering a building for the very first time and creating this map on the fly. So the robot then figures out what the features are. It builds the map. It figures out where it is with respect to the features and then estimates its position 100 times a second allowing us to use the control algorithms that I described to you earlier. So this robot is actually being commanded remotely by Frank. But the robot can also figure out where to go on its own. So suppose I were to send this into a building and I had no idea what this building looked like, I can ask this robot to go in, create a map and then come back and tell me what the building looks like. So here, the robot is not only solving the problem, how to go from point A to point B in this map, but it’s figuring out what the best point B is at every time. So essentially it knows where to go to look for places that have the least information. And that’s how it populates this map.
So I want to leave you with one last application. And there are many applications of this technology. I’m a professor, and we’re passionate about education. Robots like this can really change the way we do K through 12 education. But we’re in Southern California, close to Los Angeles, so I have to conclude with something focused on entertainment. I want to conclude with a music video. I want to introduce the creators, Alex and Daniel, who created this video.
(Applause)
So before I play this video, I want to tell you that they created it in the last three days after getting a call from Chris. And the robots that play the video are completely autonomous. You will see nine robots play six different instruments. And of course, it’s made exclusively for TED 2012. Let’s watch.
These equations started the era from which Quantum Mechanics emerged. This is one of the greatest triumph of mathematics, which revealed the electromagnetic nature of light. This is what inspired Einstein. It has carried forward the bastion of theoretical physics.
A change in electric field produces the magnetic field. A change in magnetic field produces the electric field. If a wave is created out of electric field, the wave of magnetic field is produced naturally along with it. The “up and down” of a wave seems to be replaced by electric and magnetic fields.
Here we seem to be looking at the disturbance in space itself. Disturbance in one direction appears as an Electric Field. Disturbance in opposite direction appears as a magnetic field. When space is disturbed in one direction, conditions set in immediately to restore it back to equilibrium, but then it overshoots the point of equilibrium and then the disturbance occurs in the opposite direction. And so it continues. This disturbance propagates in space as the electromagnetic wave.
But what causes the disturbance to start with, because the energy of the initial disturbance seems to be conserved as this wave. It is interesting to note that charge and current are to be made zero to arrive at the electromagnetic wave equation from Maxwell’s equations. I would now say that energy is not a condensation of space, instead it appears that
Energy is an excitation that is conserved in space.
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[Added March 4, 2012]
Per Maxwell’s Equation #3, a changing magnetic field induces a circulating electric field. It is as if “charges” are fixed in space somehow by the magnetic field. When the magnetic field changes relative to a circuit then the “charges” coinciding with that circuit seem to move along that circuit in such a way so as not to appear affected by relative changes between the circuit and the magnetic field. This motion of “charges” may appear as the electric field. When we imagine paths in space in terms of vectors, then we find that a change in magnetic field forces the “points in space” to move relative to those paths, and the motion of these “points in space” appears as the electric field. Furthermore, the motion of these “points in space” is such as to minimize the net effect of change. The magnetic and electric fields appear to be two different frames of references from which to look at the points in space. From the magnetic frame of reference a point may appear static, but the same point may appear to be kinetic (in motion) from the electric frame of reference. These two frames may switch back and forth, while the points maintain their position as if subjected to some kind of inertia. This is just a conjecture toward imagining a structure to space itself. The electromagnetic phenomenon may itself provide a structure to space. The questions that arise are: (1) Do the space and electromagnetic phenomenon go hand in hand? (2) Will there still be space in a region if the electromagnetic phenomenon does not exist there?
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[Added March 3, 2012]
It is fascinating to observe from Maxwell’s equation #3 that there are two types of electric fields. Both types of electric fields accelerate electric charges, both have the same units, and both can be presented by field lines. But charge-based electric fields have field lines that originate on positive charge and terminate on negative charge (and thus have non-zero divergence at these those points), while induced electric fields produced by changing magnetic fields have field lines that loop back on themselves, with no points of origination or termination (and thus have zero divergence). The induced electric field is directed so as to drive an electric current that produces magnetic flux that opposes the change in flux due to the changing magnetic field. This seems to point toward a very fundamental form of inertia, or to a tendency toward some sort of equilibrium. A point charge seems to represent some sort of a stopped flow that builds up at negative charge and empties out at the positive charge. Thus, the presence of a positive-negative pair of charge seems to represent a flow buildup that is frozen in place by some kind of “electrical” pressure. This “pressure” has to be maintained somehow. A changing magnetic field usually provides such “pressure.” The questions that arise are: (1) What separates a negative charge from the corresponding positive charge? (2) How is this separation maintained in free space?
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[Added February 26, 2012]
Maxwell’s equation #1 acknowledges that sources and sinks are present in Electric fields. It means that there are positive and negative electrical charges. Thus, the electric field diverging out from a source (positive charge) may indicate de-condensing of the charge. The electric field diverging into a sink (negative charge) may indicate condensing of the charge. Maxwell’s equation #2 tells us that there are no sources and sinks connected with magnetic fields. Thus, magnetic fields do not condense or de-condense into “particles” as electrical fields do. Magnetic field comes about only when an electrical charge is moving. Thus, one may say that the magnetic field is a kinetic aspect of an electrical field. An electric field not only condenses and de-condenses, but it also shifts those points of condensation and de-condensation. This seems to be somehow connected with the structure of space.
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[Added February 13, 2012]
On Permittivity (Ɛ): (1) The smaller is the permittivity, the more is the electric flux that is generated in a medium from a unit charge. (2) Permittivity of free space seems to be the lowest. (3) Therefore, maximum electric flux is generated in free space from a unit charge. (4) Storage capacity for charge at a location in free space is the lowest. (5) If the charge is not stored in free space then it spreads out as electromagnetic wave (conjecture). So, the smaller is the permittivity of space the faster would seem to be the speed of light.
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[The original post]
It has been my conjecture for some time that
ENERGY IS CONDENSATION OF SPACE.
This is simply a starting point. I believe that even if “condensation” is not the right word, there is definitely a fundamental relationship between space and energy. Looking at Maxwell Equation #1 (Gauss’s law for electric field), the electric field lines seem to emerge from a positive charge and terminate at a negative charge. This electric flux is directly proportional to the charge it originates from and terminates into. The proportionality factor is constant for free space. It is called the permittivity of free space. It is a factor that also contributes to the constant speed of light. This permittivity seems to point to some fundamental property related to space. Could this permittivity of free space be regarded as a factor by which the electric flux in free space condenses into a point charge? I don’t know; but it is fun to look at it that way. Maybe space itself could be defined as some sort of flux. There is no aether that fills the space. Maybe space itself is that elusive aether. There may not be any aether, but space is definitely there. Anyway, this area interests me greatly and I shall be working on it. I just thought that I shall put this conjecture in the open. . NOTE: I am currently studying the following book:
In the first section of this book, Einstein makes the following points:
Truth is relative to one’s experience.
If the experience is limited then one’s “truth” is limited.
Euclidean Geometry is based on limited experience.
How do we consider a straight line? How do we consider distance?
We assume locations in space to exist as if on a rigid body.
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Points from Section II:
Let’s use a “rigid” Cartesian Coordinate System, and a rigid body as a unit, to describe positions in space.
But, since optical observations are involved, let’s also take into account the properties of the propagation of light in determining the measurements.
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Points from Section III:
Regarding “motion in space,” there is no such thing as an independently existing trajectory but only a trajectory relative to a particular body of reference.
The finiteness of the velocity of propagation of light would influence the perception of change in position with time.
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Points from Section IV:
A system of co-ordinates of which the state of motion is such that the law of inertia holds relative to it is called a “Galileian system of co-ordinates.”
We cannot use a system of coordinates rigidly attached to earth, because, in that system of coordinates, stars would appear to be moving in a circle in violation of the law of inertia.
We assume a Galileian systems of co-ordinates, which are rigid but not attached to earth.
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Points from Section V:
Principle of Relativity: Natural phenomena run their course according to exactly the same general laws with respect to all Galileian co-ordinate systems that are translating uniformly, and not rotating or accelerating, relative to each other.
We may assume, as our body of reference, a Galileian coordinate system K0, in which natural laws are capable of being formulated in a particularly simple manner.
We may then assume K0 to be “absolutely at rest,” and all other Galileian systems K “in motion.”
The “motion” of Galileian systems K shall contribute to their diminished simplicity, or increased complexity, of the formulation of natural laws.
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Points from Section VI:
The theorem of the addition of velocities employed in classical mechanics, as we shall see, does not hold in reality.
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Points from Section VII:
The velocity of light of any wave-length is constant in vacuum. It does not depend on the motion of the body emitting the light.
The theorem of the addition of velocities employed in classical mechanics does not hold for the velocity of light, which remains the same with respect to all bodies of reference.
This result comes into conflict with the principle of relativity set forth in Section V, because it would appear that different laws of propagation of light must necessarily hold for different coordinate systems.
It seems that the principle of relativity must be rejected because the theoretical investigations into electromagnetic phenomena, leads conclusively to the constancy of the velocity of light in vacuo.
In reality there is not the least incompatibility between the principle of relativity and the law of propagation of light, as shown in the special theory of relativity, by an analysis of the physical conceptions of time and space.
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Points from Section VIII:
“Time” should be defined as a measure in the immediate vicinity (in space) of the event.
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Points from Section IX:
Events that are simultaneous with reference to one co-ordinate system are not necessarily simultaneous with reference to another co-ordinate system because of the finite velocity of light.
Every reference-body (co-ordinate system) has its own particular time.
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Points from Section X:
Owing to the consideration of simultaneity, the measure of the same distance from two different coordinate systems, which are in relative motion to each other, is not necessarily the same.
There is no loss of energy in a pure standing wave. In other words, the energy would be conserved. We may then look at this physical universe as an example of pure standing wave, because energy is conserved in this universe.
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The most fundamental phenomenon in this universe seems to be a back-and-forth motion around a reference value. Call it a vibration that creates waves; but this phenomenon seems to underlie all other phenomena.
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Light seems to be tied to the vacuum of the space itself rather than to anything existing in that space. In other words, light does not seem to travel relative to anything in space. The velocity of light is the same regardless of the motion of the frame of reference that is used.
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The velocity of light is finite. Einstein used this fact to query the very basis of perception on cosmic scales.
At atomic scales, light seems to condense as standing waves instead of reflect. It seems to be the fractal iteration of this condensation that appears as electrons, protons, neutrons, etc. This makes perception at atomic scales questionable too. Our perception seems to be limited to the middle band.
The frequency and wave-length of light corresponds in such a way that the velocity of light always remains the same. That is the basis of confirming that the universe is expanding using the redshift of the Doppler effect. We apply the same argument to the shift in the pitch of the sound of whistle of a passing train. This brings up the following questions:
(1) The velocity of sound is constant with respect to a medium, such as air. Would we perceive the same shift in the pitch of sound if the air is not all displaced and moved around by the passing train?
(2) The velocity of light is constant in space. Can we treat space as a “medium” made up of not the usual material, but dark matter perhaps!
(3) Does this dark matter get disturbed by passing light, similar to the way air gets disturbed by the passing train?
(4) How does this dark matter appear to behave at atomic dimensions?
Note: This seems to be looking at the old ether theory again.
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Counting goes up to infinity; then that collection of infinity may be regarded as “one.” For example, Infinity of fundamental particles may take the shape of an apple. We may then count apples. Not all apples will have the same number of fundamental particles, but each would be regarded as a unit apple.
The counting to infinity may be repeated with this new “one.” This procedure may continue without limit. This procedure may be reversed without limit also.
This raises the question, “Do we have a rigid relationship between the “numbers” used to account for the atomic phenomena and the numbers used to account for the cosmic phenomena?”
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The following is the basic assumption underlying Euclidean Geometry, which was pointed out by Einstein:
Euclidean geometry assumes that points, directions and distances behave as if they are associated with a rigid body. We are conditioned to think this way because the rigid body of earth provides our frame of reference.
But the question remains, “Does the “fabric” of space behaves like a rigid body, and if not, then do the laws of Euclidean Geometry still apply?”
Comment (03/14/26): Light is not a disturbance in some medium like sound. Light is a very thin substance occupying a very large space. It has attributes similar to frequency and wavelength.
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Here is a very interesting comment on mechanical brain and free will by Alan Turing (AMT/B/5 Image 5):
Your Majesty, Your Royal Highnesses, Ladies and Gentlemen.
This year’s Nobel Prizes for Physics are dedicated to the new atomic physics. The prizes, which the Academy of Sciences has at its disposal, have namely been awarded to those men, Heisenberg, Schrödinger, and Dirac, who have created and developed the basic ideas of modern atomic physics.
It was Planck who, in 1900, first expressed the thought that light had atomic properties, and the theory put forward by Planck was later more exhaustively developed by Einstein. The conviction, arrived at by different paths, was that matter could not create or absorb light, other than in quantities of energy which represented the multiple of a specific unit of energy. This unit of energy received the name of light quantum or photon. The magnitude of the photon is different for different colours of light, but if the quantity of energy of a photon is divided by the frequency of oscillation of the ray of light, the same number is always obtained, the so-called Planck’s constant h. This constant is thus of a universal nature and forms one of the foundation stones for modern atomic physics.
Since light too was thus divided into atoms it appeared that all phenomena could be explained as interactions between atoms of various kinds. Mass was also attributed to the atom of light, and the effects which were observed when light rays were incident upon matter could be explained with the help of the law for the impact of bodies.
Not many years passed before the found connection between the photon and the light ray led to an analogous connection between the motion of matter and the propagation of waves being sought for.
For a long time it had been known that the customary description of the propagation of light in the form of rays of light, which are diffracted and reflected on transmission from one medium to another, was only an approximation to the true circumstances, which only held good so long as the wavelength of the light was infinitesimally small compared with the dimensions of the body through which the light passed, and of the instruments with which it was observed. In reality light is propagated in the form of waves which spread out in all directions according to the laws for the propagation of waves.
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[Click on the link above to read the whole speech]
