Now suppose that your phone wants to connect with this pCell network. It would simply send out an access request as it normally does. And all of the “dumb” antennas in your vicinity—let’s say there are 10 of them—would pick up those signals and relay them to the data center.

That’s where things get interesting. Say, for example, you play a YouTube video. The pCell data center would request the video from Google’s servers, and then stream it to your phone through those 10 antennas. But here’s the key innovation: No one antenna would send the complete stream or even part of the stream. Instead, the data center would use the positions of the antennas and the channel characteristics of the system, such as multipath and fading, to calculate 10 unique waveforms, each transmitted by a different antenna. Although illegible when they leave the antennas, these waveforms would add up to the desired signal at your phone, exploiting interference rather than trying to avoid it.

And as you move about, and as other devices connect to and drop off the network, the data center would continuously recalculate new waveforms so that each device receives the correct aggregate signal. “There’s no handoffs and one has to take turns,” Perlman says. “You could literally light up a whole city using all the same spectrum.”

If pCell technology does take off in the next few years, it will likely be because it’s compatible with 4G LTE phones. It does this by simulating LTE base stations in software. The data center would use these virtual radios to inform its waveform calculations, essentially tricking an LTE phone into believing it’s connected to a physical base station. “Your phone thinks its the only phone in the cell and is sitting right next to the tower,” Perlman says. The same technique could also work for other wireless standards, such as 3G and Wi-Fi, he says.

So will operators adopt pCell? It’s unlikely that LTE carriers would replace their networks any time soon, even if Artemis’s technology proves to be the “seed change” Perelman believes it is. But its compatibility with LTE changes the game. For instance, operators could deploy pCell antennas in congested hot spots such as airports, sports stadiums, and city centers—places where they’re already investing in new infrastructure. Users could roam seamlessly between the two networks without having to buy new phones or switch service plans.

Artemis says it plans to license pCell to wireless carriers and Internet service providers. The company is now beginning large-scale trials in San Francisco and expects the technology will be ready for commercial rollouts by the end of 2014. It will be fascinating to see how its ambitions pan out.

 

more:

http://spectrum.ieee.org/tech-talk/telecom/wireless/5g-service-on-your-4g-phone

When boats are launched for the first time, it's customary to smash a bottle of champagne across the bow. But for industrial-robot maker Kuka, its new factory in southwestern Shanghai is being celebrated with a battle between man and machine. On March 11th, the company's squaring off one of its Agilus robots against German table tennis player Timo Boll. While Boll has a storied career of victories against human players, he's playing against a model Kuka says is the fastest in the world. Typically those machines are used for product assembly, loading and unloading, and even painting, but in this case it will be trading volleys over a standard ping pong table.

Man vs. machine, to celebrate a robot factory

This isn't the first time the very same robot has been used for something unusual. Late last year Kuka showed off the KR Agilus model replicating 3D artwork made by Israeli industrial designer Yaron Elyasi. The robot's orange color was also the inspiration for a line of stainless steel luxury watches made by Sevenfriday.

more:

http://www.theverge.com/2014/2/17/5420966/german-ping-pong-champion-to-play-against-industrial-robot-next-month

This concept looks very neat. Although it's for Parrot, i think there is a possibility to modify it for bigger multicopter.

With a very simple design you get suspension.

You can download the files for 3d printing here (not my design):

http://www.thingiverse.com/thing:229449

Waiting for your comments!

Thanks!

Hello friends,

I'm not the best person to judge, because i don't have the biggest experience with drones (working on it as hard as i can though :) ), but this could be interesting. I'm not sure if the hardware inside is the best suited for applications delivered by APM or Pixhawk, but the size and weight is definitely an upside of Edison. Same sized IMU, GPS and some other sensors and this could be the next ultimate Autopilot, couldn't it? 

I am really excited about this little guy. It could push forward a lot of new products to market, and i have a little hunch that it could be a good solution for drones.

It has an onboard WiFi and a Bluetooth, so it could improve the communication between drone and ground station (for ex.  substitution for micro usb cable, short range telemetry, or even direct drone to drone communication).

Also, it provides a low-power 22nm 400MHz Intel® Quark processor with two cores (don't know how that stands vs ARM that's on board of Pixhawk, I hope that someone with the knowledge will clear this issue for all of us)

more on the subject:

http://www.intel.com/content/www/us/en/do-it-yourself/edison.html

http://www.engadget.com/2014/01/06/intel-edison/

https://www.youtube.com/watch?v=jlgmO1Keb5w

What do You think?

Best to all of You and a Happy New Year!

Very interesting documentary by BBC. I am currently attending a course about machine learning. When I saw Asimo simultaneously listening to 3 people at one time, i thought it has to have at least 2 microphones. Well, it has 8. Drone/Robot era is coming. I think this ovie is a great insight for our community!

Simple idea! This is how you sell drone era to mass consumer :)

I think I'll have one :)

PowerUp 3.0 turns your self-made paper airplane into a smartphone-controlled flying machine

1. Fold It: Simply fold a piece of copier paper into a paper airplane
2. Attach It: Attach the Smart Module to your paper plane with the patented clips underneath the Smart Module.
3. Connect It: Start the app to connect to the Smart Module with your iPhone.
4. Fly It: Push throttle to full and launch the paper airplane high up into the sky. Tilt your smartphone to the left or to the right to steer your plane, increase or reduce throttle to go up or down.

PowerUp 3.0 - Smartphone Controlled Paper Airplane

Qualcomm Zeroth processor to not only mimic human-like perception but also have the ability to learn how biological brains do.

This might be the powerful new tool for drones development in the next few years. Just imagine what possibilities it gives.

We have a lot of switches on our radio (or tablet). It would be amazing, to use one as a "good drone" button. The speed of learning in a connected network like Mission Planner could be incredible. With this feature the future looks way more futuristic and drone populated.

I would love to order, in few years time, my first 3DR NPU (Neural Processing Unit), wouldn't you? :) 

Look at the video below.

Qualcomm Zeroth processors have three main goals:

1. Biologically Inspired Learning

2. Enable Devices To See and Perceive the World as Humans Do

3. Creation and definition of an Neural Processing Unit—NPU

Qualcomm’s technologies are designed from the ground-up with speed and power efficiency in mind. This way, devices that use our products can run smoothly and maximize battery life driven experiences. As mobile computing becomes increasingly pervasive, so do our expectations of the devices we use and interact with in our everyday lives. We want these devices to be smarter, anticipate our needs, and share our perception of the world so we can interact with them more naturally. The computational complexity of achieving these goals using traditional computing architectures is quite challenging, particularly in a power- and size-constrained environment vs. in the cloud and using supercomputers.

For the past few years our Research and Development teams have been working on a new computer architecture that breaks the traditional mold. We wanted to create a new computer processor that mimics the human brain and nervous system so devices can have embedded cognition driven by brain inspired computing—this is Qualcomm Zeroth processing.

We have three main goals for Qualcomm Zeroth processors:

1. Biologically Inspired Learning

We want Qualcomm Zeroth products to not only mimic human-like perception but also have the ability to learn how biological brains do.  Instead of preprogramming behaviors and outcomes with a lot of code, we’ve developed a suite of software tools that enable devices to learn as they go and get feedback from their environment.

In the video below, we outfitted a robot with a Qualcomm Zeroth processor and placed it in an environment with colored boxes. We were then able to teach it to visit white boxes only. We did this through dopaminergic-based learning, a.k.a. positive reinforcement—not by programming lines of code.

2. Enable Devices To See and Perceive the World as Humans Do

Another major pillar of Zeroth processor function is striving to replicate the efficiency with which our senses and our brain communicate information. Neuroscientists have created mathematical models that accurately characterize biological neuron behavior when they are sending, receiving or processing information. Neurons send precisely timed electrical pulses referred to as “spikes” only when a certain voltage threshold in a biological cell’s membrane is reached. These spiking neural networks (SNN) encode and transmit data very efficiently in both how our senses gather information from the environment and then how our brain processes and fuses all of it together.

3. Creation and definition of an Neural Processing Unit—NPU

The final goal of Qualcomm Zeroth is to create, define and standardize this new processing architecture—we call it a Neural Processing Unit (NPU.) We envision NPU’s in a variety of different devices, but also able to live side-by-side in future system-on-chips. This way you can develop programs using traditional programing languages, or tap into the NPU to train the device for human-like interaction and behavior.  

Read more about this amazing project:

http://www.qualcomm.com/media/blog/2013/10/10/introducing-qualcomm-zeroth-processors-brain-inspired-computing

http://www.slashgear.com/qualcomm-zeroth-processors-official-mimicking-human-brain-computing-14301263/

http://www.engadget.com/2013/10/11/qualcomm-zeroth-brain-like-computer/

Canadian company - Rinnovated Design has created an innovative concept, that is really worth seeing. Their original approach to the matter allows creators to offer a printer for no more tha $100. By the use of blender software, sound card (!) and dripping water (!!) owners will be able to print 3D parts, that are cheap as they possibly can.

more info:

http://www.kickstarter.com/projects/117421627/the-peachy-printer-the-first-100-3d-printer-and-sc

http://www.3ders.org//articles/20130921-the-peachy-printer-the-world-first-100-dollar-3d-printer-scanner.html

I really like the approach of Rinnovated Design, completely out of the box thinking. It's a pitty that they don't develop drones. They could over come some present personal drones development issues :)

See for your self:

Sory if my post isn't top quality. It's my first one and English is not my main language. Anyway, hope you like the finding! :)