For a suggested retail price of $49, you will be able to ensure every move you make is captured on video. The palm-sized camera MeCam under development at Always Innovating Inc. will follow you around and take videos of you and your friends. You will be able to post these videos to Facebook, Twitter, YouTube, or any other social media site.
Always Innovating calls the MeCam a "self-video minicopter" in the video below. The camera can be operated by voice command, or it can be programmed to hover around you automatically. It has two autopilot algorithms and a Morpho Inc. video stabilizer. You upload video by streaming it to a smartphone or tablet.
The palm-sized MeCam, based on open-source software, will follow you around and shoot video. (Source: Always Innovating)
Details about the hardware are sketchy. Always Innovating says on its website that the MeCam has 14 sensors and three stabilization algorithms, offers "one-click true panorama," and works without a remote. The company did not respond to our requests for interviews or information.
In a press release unveiling the device in January, Always Innovating says the MeCam is run by a Cortex-A9 SoC. This ARM-based, low-power processor comes with up to four cores. The release doesn't says how many cores the device uses, but it does say the SoC module runs at anywhere from 1.0GHz to 1.5GHz, depending on configuration. That's a lot faster than the Parrot AR.Drone 2.0 CPU, a measly 468MHz ARM9. The Cortex-A9 SoC module also includes 1Gbyte of RAM, an SD card, Bluetooth, and both 2.4GHz and 5GHz WiFi.
But that's just the hardware. What really piqued my interest is the fact that the MeCam uses open-source Linux-based software. That seems a lot like the robot operating system we discussed in May. Always Innovating says on its webiste that it's not going to manufacture the MeCam. Instead, it is licensing "the device and its core module." If I were in robotics, I'd like to see what I could do with open-source software (especially a robot operating system) and a tiny quadricopter design platform. Of course, it depends on the licensing cost.
curious_device, it's all speculation at this point, but many of your fellow engineers disagree as shown by their comments below. According to your qualifications for what is and isn't hype, several well-known products that clearly exist from large, reputable companies that also clearly exist are all hype, too.
Be aware - The video shows a quadcopter taking off from a hand. That is all. Don't let hype fill in the blanks. Their price/power/capabilites claims are not backed-up by what information they have published. Its lack of sensors is another glaring issue.
curious_device, there's at least one working device already: it's shown in the video. And suspecting the reality of a new invention or something one hasn't seen before is certainly understandable. But belief is not required to make something true, a principle that new robot designs keep demonstrating.
There have been enough comments from actual product engineers saying that the reality of this product is more than a little suspect. How on earth did this vapourware device end up on the cover of the Design News Automation and Control supplement?!?
I would have waited until they show one working, even slightly working, before hyping their product to the max. Seeing it on the cover is just hard to believe!
William is right about batteries, but there is an alternative. Super caps have the energy to weight ratio needed to support the toy. Fly time, however, will be very limited--perhaps disappointingly so. Cruise time is certain to be under 10 minutes.
Four motor, remotely controlled toy copters exist today, and micro power Cypress PSOCs, like the new PSOC5LP or PSOC4 show that the control, smarts, and communication are available running on a trivial amount of power.
I suspect you're right, William, about there being only one prototype; but then, that's often the case. Regarding batteries, good question, but I have been surprised at how long many of the palm-sized flying quadrotors we've reported on can last.
Right now I wonder if there is actually anything besides one prototype, and how much additional support does that prototype have beyond what we are seeing. There does not seem to be enough space to carry enough battery power to support all of the smarts claimed for this platform. Not that it wouldn't be a fun toy to have, but I would not wish to tie up my smartphone controlling a toy like that. But a flying camera that could also perch and stare could be either quite useful or lots of fun, and if it had it's own controller then it would be really something. Better than X-Ray vision by quite a bit, in fact.
And as for that back and forth string of insults about creation, my suggestion is to do a detailed study and examination of the DNA system, in the light of fundamental thermodynamics, and then look at the tables of values of energy required for various chemical bonds. Once you understand that, it becomes very evident that unless the basic laws of physics and thermodynamics ran backwards long ago, DNA did not just randomly assemble itself. Really, just consider what happened from an engineering point of view and consider what was required to produce the results that we see.
And looking at that little hand held model, where is there enough battery to fly it for more than a very few minutes?
Robots that walk have come a long way from simple barebones walking machines or pairs of legs without an upper body and head. Much of the research these days focuses on making more humanoid robots. But they are not all created equal.
The IEEE Computer Society has named the top 10 trends for 2014. You can expect the convergence of cloud computing and mobile devices, advances in health care data and devices, as well as privacy issues in social media to make the headlines. And 3D printing came out of nowhere to make a big splash.
For industrial control applications, or even a simple assembly line, that machine can go almost 24/7 without a break. But what happens when the task is a little more complex? That’s where the “smart” machine would come in. The smart machine is one that has some simple (or complex in some cases) processing capability to be able to adapt to changing conditions. Such machines are suited for a host of applications, including automotive, aerospace, defense, medical, computers and electronics, telecommunications, consumer goods, and so on. This discussion will examine what’s possible with smart machines, and what tradeoffs need to be made to implement such a solution.