01.December.2014
Comment of the Day
Cade™

Ontonics Further steps
We developed a new application of a new technology.

Style of Speed Further steps
We thought that it is time to show some doodles, that give an im- pression of the design direction of our muscle car Cade.

© :I, :I, and Style of Speed

Again, there is no need to panic and to copy, as usual, because it is really some kind of a teaser for the coupé only.

In addition, we combined two Active Components.

Furthermore, we developed an older technology further by using a newer technology.

02.December.2014
Ontonics Further steps
Now, we have our next own flexible battery technology with out- standing performances ready and can focus on the production.

04.December.2014
iRaiment Further steps 03:00 UTC +1 CET
Ok, literally spoken it is time to ramp up the time with our next Sm@rtW@tch model series, as promised.
The Sw@tches feature our already protected Accumulator/Battery Wristwatch Band and our common displays, inclusive dual displays based on e.g. LCDs and e-papers, or OLEDDs and ActiveIMODs.




© Swatch and iRaiment

The Sw@tches are also ideally suited as fitness bands and support- ing devices for health care. Now you know why we showed the special model "Vodoo Love" by Swatch as well with the OntoLab concept "Gingy, Vodoo Love and Marvin the Martian" as part of the Original Sketches on the 22nd of January 2008.
The image below shows a special model that is flat for being either a style statement, very low budget model, or throwaway smartwatch, possibly with reduced function as needed.

© Swatch

The watch faces will be replaced with images of computer displays.

We also would like to present our magic in this field, that is our Accumulator/Battery Wristwatch Band, that provides up to more than four times of electric power in comparison to a battery of a common smartwatch depending on the model.
Shown here is a flexible variant, covered by a transparent plastic respectively polymer, and featuring its unique element of a buckle or clasp.

© :(

Style of Speed Further steps
We developed three more variants of our new type of aerial vehicle mentioned in the Ontonics Further steps of the 26th of September 2014 as part of the development of our new dream models, and now we are faced with that annoying selection problem.

Klick - Klick
Klick ...!!!

06.December.2014
Style of Speed Further steps
In the last two days, we developed just for fun our own types of a compound autogyro/gyroplane/gyrocopter, gyrodyne, and com- pound helicopter with outstanding performances. For example, the maximum speed in the case of the compound autogyro should be around 434 kn/500 mph/805 km/h and in the case of the compound helicopter around 348 kn/400 mph/644 km/h and potentially even more in both cases, while all different rotorcrafts would be very fuel efficient, but not more complex than the actual rotorcrafts.

Oh, yes, do not forget to mention: Batteries and stealth always included.

08.December.2014
Ontonics Further steps
We developed a new basic component.

We also applied a different material for a newer technology.

09.December.2014
Ontonics Further steps
We adapted the Stroetmann Cycle in such a way, that we were able to integrate it with another technology advantageously.

Style of Speed Further steps
We developed a new model of a vehicle series.

Also, we continued with the development of the new model Big S or Big C mentioned the first time in the Further steps of the 21st of March 2013.

© :I and :I

The image shows only a potential design direction.

10.December.2014
Ontonics Further steps
We developed a device further.

16.December.2014
Picture of the Year
Somehow, this picture says it all.

© :(

And yes, we think the rat is alive.

17.December.2014
Ontonics Further steps
We developed two new basic components.

We also improved a technology in differant variants, that are based on an older basic component and the two new basic components mentioned before. This has the potential to become the standard in its field due to the many advantages.

18.December.2014
Ontonics Further steps
We have improved the technology mentioned in the Further steps of yesterday by using a basic component with outstanding perform- ances, that was used before to optimize another technology ment- ioned in the Further steps of the 29th of November 2014.

19.December.2014
Ontonics Further steps
We have begun the production phase of the next device.

23.December.2014
Comment of the Day
Active glass™
Active rearscreen™
Active rear window™
Active side window™

Ontonics Further steps
We improved a technology by integrating two existing technologies.

Style of Speed Website update

We have uploaded the new webpage Active Glass, which summerizes our superior display and projection solutions, and the new webpages of our Active Rearscreen and Active Side Window, which are even better than ever now.

24.December.2014
Clarification
We would like to give some informations about the perfomance of our Carbon Quantum Dot Light-Emitting Diode (CQLED™) displays, spec- ifically in relation with the quality of transparency and sharpness, brightness, flexibility, and power consumption.

For comparison of the quality of transparency, sharpness, and also isotropy on the macroscopic scale, the carbon allotrope graphene (graphite is made of layered graphene sheets), Indium Tin Oxide (ITO), and one of the potential alternatives for ITO, an array of silver nanowires covered with graphene have been taken, and for comparison of general features of display technologies Liquid Crystal Displays (LCDs) and Organic Light-Emitting Diode Displays (OLEDDs) were selected.

Graphene has a transparency of around 97,7% per layer, the trans- parency of ITO depends on its conductivity respectively on its thickness and drops rapidly for wavelengths above λ=1000 nm, and the transparency of an array of silver nanowires covered with graphene is around 88% at λ=550 nm.
Besides this, transparent LCDs with backlight and OLEDDs are not truly transparent and offer no sharp see-through view, while LCDs without backlight and other transparent, reflective display techno- logies provide a very poor brightness, which is comparable with projection systems.
Depending on the variant, the transparency of the CQLEDDs devel- oped by our OntoLab is even better than graphene. In addition, the brightness and the color accuracy even surpass OLEDDs.

Moreover, ITO is relatively expensive, brittle, unstable, and inflexible. LCDs are relatively cheap, but inflexible and energy inefficient, while OLEDDs are less expensive, flexible in specific ranges, and relatively energy efficient. In total contrast, the carbon allotropes and carbon based materials, compounds, and composites, and also the individual components made of them, which include QLEDs and Field-Effect Transistors (FETs; comprises Thin-Film Transistors (TFTs)) based on for example silicon carbid and graphene, silver nanowire covered with graphene, silicon nanowire covered with graphene, and carbon nano- tube compound with copper by the way, used for our CQLED displays are relatively cheap, highly flexible, and highly conductive. In fact, some subcomponents have a conductivity that is 100 times better than pure copper.

Accordingly, we do not have to make any compromises between conductivity and transparency, or/and transparency and flexibility in respect to our QLEDs and FETs, that offer the best alternatives de- pending on specific applications and related variants.
As a further impressive result, our CQLEDDs have a much lower pow- er consumption in comparison to an OLEDD, which consumes around 40% of the power of an LCD displaying an image that is primarily black, and around 60 to 80% displaying coloured images.

Further features depending on the specific variants: