We are just now beginning to see the possibilities of orchestrated drone swarms and how they can be used for entertainment. In the not too distant future firework shows in American will be replaced with organized drone shows and halftime shows at the Super Bowl will showcase a synchronized display of visuals that align with the entertainment.
The 30 second mark is quite interesting and odd how the robots move the way they do when humans are walking bye. Manus is a set of ten industrial robots that are programmed to behave like a pack of animals. While each robot moves independently, they share the same central brain. So instead of acting in isolation, they have intertwined behaviors that ripple through the group as people walk by.
This is a prototype of the animatronic figure in Walt Disney World's Pandora: The World of Avatar
Spot is a four-legged robot designed for indoor and outdoor operation. It is electrically powered and hydraulically actuated. Spot has a sensor head that helps it navigate and negotiate rough terrain. Spot weighs about 160 lbs.
The cute side of the robocalypse: Balancing robots from Japan
muRata manufacturing wants to cheer people up with its latest balancing machine. It’s part of a group of swarm robots, called the murata cheerleaders. But it’s not exactly clear what they’re cheering for.
Shit is getting real. Last Friday, near a cornfield in North Dakota, four underage men were pulled over under suspicion of drunk driving. The four men hopped out of their car and bolted into the cornfield. Grand Forks police didn't follow them: Instead, they put a drone in the sky.
"One of them was walking through the cornfield. It took about three minutes to find him," Alan Frazier, Deputy Sheriff in charge of the Grand Forks Police Department's unmanned aerial vehicle system unit told me. "The other was found on a second flight, after maybe 25 minutes."
The two other suspects were apprehended at another time—they had the unlucky distinction of becoming the first Americans ever tracked down and arrested with the help of a police quadcopter.
The Qube drone that was used to chase down four DUI suspects last weekend. Image: Author
That it happened around Grand Forks is not a surprise.
Two years ago, a cattle rancher near there was arrested with the help of a Department of Homeland Security Predator drone, becoming the first man arrested in the US with the help of a drone. These four men become the first to be arrested in the US with the help of a local police drone (as of 2013, there were roughly 24 police agencies using drones).
Two weeks ago, in something of a coincidence, I sat in a conference room in Grand Forks as Frazier pitched me and several other journalists on the force's use of drones.
To start off the presentation, he pulled up this video, made by AeroVironment, the company that makes the Qube, the drone that Frazier and his team and several other police departments around the country use:
Frazier called the video, in which a fugitive is tracked down with a drone, "a little Hollywood," but that's essentially what happened there, last week. The Grand Forks Police Department is the first in the United States to get Federal Aviation Administration approval to fly at night, and last weekend's mission was the very first time the department had ever used the Qube at night on a mission.
"There's a misnomer that these are covert spy tools," Frazier told me when I was in Grand Forks. "We utilize them for events that are already occurring. We look for felony suspects, we do further analysis, we use them for totally overt missions. There's no plans to use them covertly."
DOES HE HAVE A REASONABLE EXPECTATION OF PRIVACY? IF SO, THEN WE'D SEEK A SEARCH WARRANT.
"That's not to say they can't be used for covert missions, but they haven't been," he added. A video he showed us pitched the Qube as a "powerful surveillance tool."
The back of the "UAS Unit" SUV. Image: Author
Tim Schuh, the police officer most often tasked with actually flying the thing, says it's been used about a dozen times in the last year—only once while actually looking for a suspect (before this last case). "We're not flying over downtown looking for trouble," he said.
Still, the department seems a bit gung-ho about drones in a way that many others are not. Frazier balked at the idea that the department should or would get a warrant before flying one. (California Gov. Jerry Brown just vetoed a bill that would have required police in the state to get a warrant before using a drone).
A fourth suspect has remained unnamed because he is believed to be under 18. Image: Valley News Live
When I asked Frazier if he thinks a warrant should be necessary, he said, "absolutely not. We do a quick litmus test—'does he have a reasonable expectation of privacy?' If so, then we'd seek a search warrant."
So far, the drone had been flown on 11 different occasions, only once to search for a fugitive (it wasn't successful that time). It's been used to monitor flooding, look for missing persons, take videos of a sexual assault scene, take photos of a murder scene, and once to get photos of a traffic accident scene.
After telling us about the drone program, Frazier took me outside, where Schuh was on hand to show off the Qube's capabilities. The Qube lives in the back of a police SUV that's marked "UAS Unit." Schuh set it up, and the Qube, a quadcopter not much bigger than the white Phantom drones that have become so popular with hobbyists, took off and immediately began sending footage back down to the ground station.
At this point, the process has become routine. Maybe that's why, when those four men ran off into the cornfield, police didn't chase them, Frazier said. Instead, the drone was called in and found them.
"From there, it was just like any other foot pursuit," he told me. "You chase them down and take them to jail."
I'm posting this sole' for the Autopilot preview at the end of this video. Giving up control of something that could end your life is a scary thought but automation is here and Telsa has brought the discussion to the forefront. Zero to 60 in 3.2 seconds. A high-end, all-wheel-drive option of the Model S on Thursday, Tesla CEO Elon Musk said the target for acceleration was the world's greatest supercars. What the company ended up with was 3.2 seconds from 0 to 60, something that really doesn't look like much on paper, but feels like being in a rocket ship when you're actually inside a vehicle, and ultimately behind the wheel.
In a robot lab at TEDGlobal, Raffaello D'Andrea demos his flying quadcopters: robots that think like athletes, solving physical problems with algorithms that help them learn. In a series of nifty demos, D'Andrea show drones that play catch, balance and make decisions together -- and watch out for an I-want-this-now demo of Kinect-controlled quads.
Cirque du Soleil, ETH Zurich, and Verity Studios have partnered to develop a short film featuring 10 quadcopters in a flying dance performance. The collaboration resulted in a unique, interactive choreography where humans and drones move in sync.
Get an exclusive look at the story behind the short film SPARKED: a collaboration between Cirque du Soleil, ETH Zurich, and Verity Studios. SPARKED demonstrates how state of-the-art technology can be used to combine human actors and quadcopters in a symbiotic, choreographed performance.
What if every soldier could run a four-minute mile? That's the goal behind 4MM, or 4 Minute Mile, a student project to create a wearable jetpack that enhances speed and agility. Working with the Defense Advanced Research Projects Agency and a faculty mentor, Jason Kerestes is the mastermind behind 4MM. He built a prototype of the jetpack and is now testing and refining his design to be as effective as possible. The 4MM project is part of an ASU program called iProjects, which brings students and industry together to find innovative solutions to real-world problems.
In this video, Harvard faculty member Conor Walsh and members of his team explain how the biologically inspired Soft Exosuit targets enhancing the mobility of healthy individuals and restoring the mobility of those with physical disabilities. Credit: Harvard's Wyss Institute. Note: This technology is currently in the research and development phase and is not available commercially. Any suggested or implied claims have not been evaluated by the Food and Drug Administration (FDA). Muscle Activation During Gait animation credit: K. Oberhofer, K. Mithraratne, N. S. Stott, I. A. Anderson (2009). Anatomically-based musculoskeletal modeling: prediction and validation of muscle deformation during walking.
MIT researchers have developed an algorithm for bounding that they've successfully implemented in a robotic cheetah. (Learn more: http://mitsha.re/1uHoltW) The key to the bounding algorithm is in programming each of the robot's legs to exert a certain amount of force in the split second during which it hits the ground, in order to maintain a given speed: In general, the faster the desired speed, the more force must be applied to propel the robot forward.
The Aeryon Scout and Clearpath Husky are used to demonstrate indoor and outdoor flight test results of a decentralized controller for automated docking.
11. This tree-removal device:
12. Sand being controlled by sound:
13. This table:
14. A portable, single-line printer:
15. This camera balancer:
16. This ruler that automatically measures angles, etc.:
17. Invisible glass putty:
18. This man’s juggling prowess:
19. This beer drone:
20. This fan that runs off the heat of your hand:
21. The reaction this liquid has to the man on the right’s chemical-treated clothing:
22. Just keep this in mind. 1994 vs. 2014:
1. Smart glass that obscures the bathroom when you lock it:
2. A wheelchair that can go up stairs:
3. This ice cream app:
4. This garbage can:
5. This clock that writes the time for you:
6. This progression:
7. This drone camera that follows you wherever you go:
8. This Harry Potter-esque ad:
9. An app that translates words in real time:
10. This zipper design that won’t let you down:
If you think today’s drones are interesting, you ain’t seen nothing yet. Drones are in their deceptive phase, about to go disruptive. Check out where they’re going…
What makes today’s “drones” possible?
The billion-fold improvement we’ve seen between 1980 and 2010 is what makes today’s drones possible, specifically in four areas:
- GPS: In 1981, the first commercial GPS receiver weighed 50 pounds and cost over $100K. Today, GPS comes on a 0.3 gram chip for less than $5.
- IMU: An Inertial Measurement Unit (IMU) measures a drone’s velocity, orientation and accelerations. In the 1960s an IMU (think Apollo program) weighed over 50 lbs. and cost millions. Today it’s a couple of chips for $1 on your phone.
- Digital Cameras: In 1976, Kodak’s first digital camera shot at 0.1 megapixels, weighed 3.75 pounds and cost over $10,000. Today’s digital cameras are a billion-fold better (1000x resolution, 1000x smaller and 100x cheaper).
- Computers & Wireless Communication (Wi-Fi, Bluetooth): No question here. Computers and wireless price-performance have gotten a billion times better between 1980 and today.
10 Industries Using Today’s Drones:
- Agriculture: Drones watch for disease and collect real-time data on crop health and yields. This is an estimated $3B annual market size.
- Energy: Energy companies monitor miles of pipeline and oil rigs with autonomous drones.
- Real Estate and Construction: Drones photograph, prospect and advertise real estate from golf courses to skyscrapers; they also monitor construction in progress.
- Rapid Response and Emergency Services: Drones aid in search and rescue operations ranging from forest fire fighting to searching for people buried in rubble or snow using infrared sensors.
- News: It’s faster and safer to deploy drones to cover breaking news/disaster/war zones than news crews.
- Package/Supply Delivery: Companies like Matternet (founded at Singularity University) are building networks of UAVs to deliver food and medical supplies to remote villages around the world.
- Photography/Film: Visual artists use drones to capture beautiful new images and camera angles.
- Scientific Research/Conservation: Drones assist in everything from counting sea lions in Alaska to conducting weather and environmental research to tracking herd movements on the Savannah in Africa.
- Law Enforcement: Drones can be used during hostage situations, search and rescue operations, bomb threats, when officers need to pursue armed criminals, and to monitor drug trafficking across our borders.
- Entertainment/Toys: Good old fun.
So, Where Next?
What happens in the next 10 years when drones are 1000x better? Or 30 years from now when they are 1,000,000,000x better? What does that even mean, or look like? Here are some directions for your imagination:
- Smart and Autonomous: Drones will have a mind of their own… thinking, doing, navigating, avoiding, seeking, finding, sensing and transmitting.
- Microscopic and Cheap: Think about drones the size of a housefly, sending you full-motion HD video. Think swarms of drones (hundreds) where losing half of your swarm won’t matter because another hundred are there to replace them. How much will they cost? I would be shocked if they price doesn’t plummet to less than $10 each… maybe $1.
Top Future Drone Applications?
- Pollination: Imagine bee-sized drones pollinating flowers (in fact, we’re actually doing this now);
- Personal security: In the future, your children will have a flotilla of micro-drones following them to school and to playgrounds at all times, scanning for danger;
- Action sports photography: Imagine 100 micro-drone-cameras following a downhill skier capturing video from every angle in real time;
- Asteroid prospecting and planetary science: On a cosmic scale, my company Planetary Resources is building the ARKYD 300 — effectively a space drone with 5km per second delta-V. PRI plans to send small flotillas of four to six A300 drones (with onboard sensors) to remote locations like the asteroids or the moons of Mars;
- Medical in-body drones: On the microscopic scale, each of us will have robotic drones traveling through our bodies monitoring and repairing;
- High Altitude “Atmospheric Satellite” Drones: Google recently announced Project Loon to provide a global network of stratospheric balloons, and then acquired Titan Aerospace to provide for solar powered aerial drones, both of which could blanket the entire planet to provide low-cost Internet connectivity, anytime, anywhere; and,
- Ubiquitous surveillance: Combined with facial recognition software and high-resolution cameras, drones will know where everybody and everything is at all times. Kiss privacy goodbye. Are you a retailer? Want to know how many people are wearing your product at any time? Future imaging drones will give you that knowledge.
- Military and Anti-terrorism: Expect a significant increase in defense-related applications of drones in war zones and in your local backyard, sensing and searching for dangers ranging from biological to radiation.
So, What are the Challenges?
Technical challenges aside, we’ll have to address many sociopolitical challenges before drones become disruptive.
There are concerns over privacy and spying, interference with planes/helicopters, drones aiding illegal activities, safety and potential crashes, noise and cluttering the skies, theft and commercial use.
I recommend looking at the FAA Modernization and Reform Act of 2012 to get a glimpse of the legal landscape surrounding drones.
This bill expires in September of 2015.
In other words, pending major legislative changes, expect 2015 to be a big year for drones.
Why are drones going to be disruptive?
Besides all of the use cases outlined above, drones represent an interesting convergence of three exponential technology areas:
- The Internet of Everything: Drones will be a key part of our trillion-sensor future, transporting a variety of sensors (thermal imaging, pressure, audio, radiation, chemical, biologics, and imaging) and will be connected to the Internet. They will communicate with each other and with operators.
- Advanced Battery Technology: Increases in energy density (kilowatt-hours per kilogram) will allow drones to operate for longer periods of time. Additionally, solar battery technology is allowing high-altitude drones to fly for weeks at a time without landing.
- Automation Software and Artificial Intelligence: Hundreds of teams around the world are working on automation systems that a) make drones easier for untrained users to fly, but more importantly, b) allow drones to fly and operate autonomously.
This is just the start.
At my Abundance 360 Executive Summit in January 2015, we’ll discuss this in much more detail and talk about potential investment opportunities in this arena. If you’re interested in joining me, there are only a few slots left. Apply here.
Is that a bird or a drone watching you from the telephone wire? A drone with legs can perch just like a bird – or land and walk on flat surfaces. Bhargav Gajjar of Vishwa Robotics in Brighton, Massachusetts, designed the legs as an add-on for small US air force drones.
Small drones generally lack landing gear. Many rely on a controlled crash-landing, a somewhat crude approach compared with the elegant precision landing of a perching bird. Gajjar studied dozens of bird species and recorded their landings using a high-speed camera. His drone's legs are based on those of the American kestrel.
The drone perches in an upright position with a powerful gripping action from an electric motor. Its claws are extremely sharp so that its grip is difficult to break.
A remote computer uses footage from a camera fitted to the drone to control flight and get the drone into the correct position for landing. Just like a real bird, the drone has to brake sharply just above its landing site and perform a controlled stall in order to touch down. Birds' legs also act as shock absorbers, and the mechanical version mimics this.
Gajjar's perching legs can waddle short distances, so the drone can explore indoor spaces.
Read more at http://bit.ly/1sTk7gj
In 1992, Amanda Boxtel suffered a vicious skiing accident that left her paralyzed from the waist down. Doctors said she would never walk again. This week, she proved them wrong, with the help of the world's first 3D printed exoskeleton that gives her the ability to climb out of her wheelchair and walk once again.
The Ekso-Suit Amanda wears is fully bespoke. 3D Systems used data from a full body scan to print custom-tailored pieces that fit exactly to Amanda's body. Mechanical components from EksoBionics provide the automation, allowing Amanda to safely use her legs and a pair of canes to walk around.
3D scanning and printing technologies were crucial to making Amanda's exoskeleton, which took roughly 3 months to complete. As Scott Summit, senior director for functional design at 3D Systems, told Cnet, "we had to be very specific with the design so we never had 3D-printed parts bumping into bony prominences, which can lead to abrasions." Since Amanda has no sensation in her legs, even tiny skin injuries can become dangerously infected before they're found. A comfortable fit isn't just a nicety, it's a safety necessity.
This exoskeleton is the first to use 3D printing for an individualized fit, but it's not Amanda's first time using such technology: in 2010, she helped test an earlier exoskeleton design to help paralyzed patients walk again. Since then, she's been active as one of ten EksoBionics test pilots involved in the design process. Keep reading at http://bit.ly/1gwvSTl
At Daewoo’s South Korean shipyard, lifting and moving massive slabs of metal as if they’re made of foam could soon be a basic job requirement for workers. Of course, they’ll have some help: robotic exoskeletons, which made their debut last year at the company’s manufacturing facility, are on the rise.
After successfully testing the exoskeletons last year, the shipbuilding giant hopes to soon outfit some of their employees with the technology, giving them the superhuman strength to take production to new heights, New Scientist reports. The prototypes tested allowed workers to pick up 65-pound objects and manipulate them with ease, but Daewoo plans to increase the exoskeletons’ carrying capacity to roughly 220 pounds with design improvements.
The exoskeletons themselves weigh in at 60 pounds, but workers don’t feel the load because an aluminum alloy and steel frame supports its own weight. Workers simply lock their boots into the footpads of the suit, and fasten straps from the thighs to the chest.
Hydraulic joints and battery-powered motors give the workers Iron Man-like strength for lifting, but also allow them to walk normally. In addition to raw lifting ability, workers can also handle heavy objects precisely, since they feel much lighter.
The Age of Exoskeletons
After years of research into robotic exoskeletons, it seems 2014 is shaping up to be the year the technology enters the “real world.” In July, the U.S. Food and Drug Administration approved the first robotic exoskeleton for paralyzed individuals. During the opening ceremony of the 2014 FIFA World Cup, a teenage Brazilian paraplegic delivered the opening kick with a mind-controlled exoskeleton.
According to a 2014 Wintergreen Research report, the market for rehabilitative robotics — which includes exoskeletons — is expected to grow from its current $43.8 million to $1.8 billion by 2020.