The List of Best Camera Apps for Android to Enhance Photographs

Currently, there are lots of Android devices which have been loaded with the advanced camera capability. A few of them are already loaded with the high-resolution 12 MP camera, just like the upcoming HTC Vigor as well as Sony Ericsson Xperia Duo. But still there are many customers who usually do not feel completely preferred with the picture or photograph results. Therefore, they may do a search for the 100% free and best camera apps for Android as a way to change or boost their pictures or photos. The following are the examples of the best camera apps for Android smartphones or PC tablets.

Adobe Photoshop Express

This can be probably the most well-known and the best camera apps for Android because it has long been commonly used by either desktop computer or Android handset users for image/photo improving. Fortunately, it is totally 100 % free and this will provide some good functionalities for the needs of image cropping and editing. The functions range from the fast photograph adjusting by utilizing crop, straighten, rotate, flip, and adjust color function. You may also share the photos to the online communities and backup them to Photoshop.com effortlessly as well. This great app is obtainable to download at Android Market.

Pro Paint Camera

The Pro Paint Camera program offers a better image result because it features white balances, 4 filters, 35 cliparts, text fonts, photograph effects, front-facing camera support, instamatic brightness and contrast, silent mode, focus control, including macro, sharing, draw, paint, ISO control (if supported), EXIF, adding your images from the gallery, scene modes, and macro auto-focus. When you're curious about the program, just go to the Android Market and look for it.

Camera Zoom FX

This is one of the 100% free and best camera apps for Android handsets that will deliver the great amount of impressive effects like mirror, art, distort, as well as frame effects. It also offers fantastic editing tools, for example composite yourself along with a movie star, shutter skins option, buddy, borders, fun Props, set filters, anti-banding, white balance, night shot mode, toggle autofocus, timer mode (with voice activation), stable shot along with burst mode.

Photo Album Organizer

Besides, the consumers will need to edit or enhance their pictures, they will likewise need the best camera apps for Android which has the capacity to arrange the photo albums. The Photo Album organizer is amongst the wise decision considering that it offers the quick albums making to obtain a far better photo viewing using your mobile phone. In addition, it possesses the capability to sort and relocate images and hide the albums as well for your privacy matter.

Rangga Cipta Diputra is a writer of various topics, he currently writes for Paseban Portal. He writes reviews, guide and tips about mobile devices, mobile operating systems, mobile apps and so on.

View the original article here

New material can enhance energy, computer, lighting technologies

ScienceDaily (Nov. 16, 2011) — Arizona State University researchers have created a new compound crystal material that promises to help produce advances in a range of scientific and technological pursuits.

ASU electrical engineering professor Cun-Zheng Ning says the material, called erbium chloride silicate, can be used to develop the next generations of computers, improve the capabilities of the Internet, increase the efficiency of silicon-based photovoltaic cells to convert sunlight into electrical energy, and enhance the quality of solid-state lighting and sensor technology.

Ning's research team of team of students and post-doctoral degree assistants help synthesize the new compound in ASU's Nanophotonics Lab in the School of Electrical, Computer and Energy Engineering, one of the university's Ira A. Fulton Schools of Engineering.

The lab's erbium research is supported by the U.S. Army Research Office and U.S. Air Force Office of Scientific Research. Details about the new compound are reported in the Optical Materials Express on the website of the Optical Society of America.

The breakthrough involves the first-ever synthesis of a new erbium compound in the form of a single-crystal nanowire, which has superior properties compared to erbium compounds in other forms.

Erbium is one of the most important members of the rare earth family in the periodic table of chemical elements. It emits photons in the wavelength range of 1.5 micrometers, which are used in the optical fibers essential to high-quality performance of the Internet and telephones.

Erbium is used in doping optical fibers to amplify the signal of the Internet and telephones in telecommunications systems. Doping is the term used to describe the process of inserting low concentrations of various elements into other substances as a way to alter the electrical or optical properties of the substances to produce desired results. The elements used in such processes are referred to as dopants.

"Since we could not dope as many erbium atoms in a fiber as we wish, fibers had to be very long to be useful for amplifying an Internet signal. This makes integrating Internet communications and computing on a chip very difficult," Ning explains.

"With the new erbium compound, 1,000 times more erbium atoms are contained in the compound. This means many devices can be integrated into a chip-scale system," he says. "Thus the new compound materials containing erbium can be integrated with silicon to combine computing and communication functionalities on the same inexpensive silicon platform to increase the speed of computing and Internet operation at the same time."

Erbium materials can also be used to increase the energy-conversion efficiency of silicon solar cells.

Silicon does not absorb solar radiation with wavelengths longer than 1.1 microns, which results in waste of energy -- making solar cells less efficient.

Erbium materials can remedy the situation by converting two or more photons carrying small amounts of energy into one photon that is carrying a larger amount of energy. The single, more powerful photon can then be absorbed by silicon, thus increasing the efficiency of solar cells.

Erbium materials also help absorb ultraviolet light from the sun and convert it into photons carrying small amounts of energy, which can then be more efficiently converted into electricity by silicon cells. This color-conversion function of turning ultraviolet light into other visible colors of light is also important in generating white light for solid-state lighting devices.

While erbium's importance is well-recognized, producing erbium materials of high quality has been challenging, Ning says.

The standard approach is to introduce erbium as a dopant into various host materials, such as silicon oxide, silicon, and many other crystals and glasses.

"One big problem has been that we have not been able to introduce enough erbium atoms into crystals and glasses without degrading optical quality, because too many of these kinds of dopants would cluster, which lowers the optical quality," he says.

What is unique about the new erbium material synthesized by Ning's group is that erbium is no longer randomly introduced as a dopant. Instead, erbium is part of a uniform compound and the number of erbium atoms is a factor of 1,000 more than the maximum amount that can be introduced in other erbium-doped materials.

Increasing the number of erbium atoms provides more optical activity to produce stronger lighting. It also enhances the conversion of different colors of light into white light to produce higher-quality solid-state lighting and enables solar cells to more efficiently convert sunlight in electrical energy.

In addition, since erbium atoms are organized in a periodic array, they do not cluster in this new compound. The fact that the material has been produced in a high-quality single-crystal form makes the optical quality superior to the other doped materials, Ning says.

Like many scientific discoveries, the synthesis of this new erbium material was made somewhat by accident.

"Similar to what other researchers are doing, we were originally trying to dope erbium into silicon nanowires. But the characteristics demonstrated by the material surprised us," he says. "We got a new material. We did not know what it was, and there was no published document that described it. It took us more than a year to finally realize we got a new single-crystal material no one else had produced."

Ning and his team are now trying to use the new erbium compound for various applications, such as increasing silicon solar cell efficiency and making miniaturized optical amplifiers for chip-scale photonic systems for computers and high-speed Internet.

"Most importantly," he says, "there are many things we have yet to learn about what can be achieved with use of the material. Our preliminary studies of its characteristics show it has many amazing properties and superior optical quality. More exciting discoveries are waiting to be made."

Recommend this story on Facebook, Twitter,
and Google +1:

Other bookmarking and sharing tools:

Story Source:

The above story is reprinted from materials provided by Arizona State University.

Note: Materials may be edited for content and length. For further information, please contact the source cited above.

Note: If no author is given, the source is cited instead.

Disclaimer: Views expressed in this article do not necessarily reflect those of ScienceDaily or its staff.

View the original article here

Gold nanowires in engineered patches enhance electrical signaling and contraction

ScienceDaily (Sep. 26, 2011) — A team of physicians, engineers and materials scientists at Children's Hospital Boston and the Massachusetts Institute of Technology have used nanotechnology and tiny gold wires to engineer cardiac patches, with cells all beating in time, that could someday help heart attack patients.

As reported online by Nature Nanotechnology on September 25, the addition of gold wires to the engineered heart tissue make it electrically conductive, potentially improving on existing cardiac patches. Such patches are starting to go into clinical trials for heart patients.

"If you don't have the gold nanowires, and you stimulate the cardiac patch with an electrode, the cells will beat only right where you're stimulating," says senior investigator Daniel Kohane, MD, PhD, of the Laboratory for Biomaterials and Drug Delivery at Children's Hospital Boston. "With the nanowires, you see a lot of cells contracting together, even when the stimulation is far away. That shows the tissue is conducting."

After incubation, the patches studded with the gold nanowires were thicker and their heart muscle cells better organized. When stimulated with an electrical current, the cells produced a measurable spike in voltage, and electrical communication between adjacent bundles of cardiac cells was markedly improved. In contrast, only a negligible current passed through patches lacking the wires, and cells beat only in isolated clusters.

Kohane thinks the nanowire technology could be applied to the engineering of any electrically excitable tissue, including tissue in the brain and spinal cord. Gold was chosen as a material because it's a conductive material, easy to fabricate, scientists have a lot of experience with it, and it is tolerated by the body.

The wires average 30 nanometers thick and 2-3 microns long, just barely visible to the naked eye.

Since testing has so far been done only in cell cultures, the team plans to do further experiments to see how well the cardiac patches function in live animal models, and to get a better understanding of how exactly the nanowires are enhancing electrical signaling and contraction.

Kohane believes the gold fibers help because they're long enough to cross the scaffolding material that holds the cells and may act as a barrier to electrical conduction. In addition, the experiments showed enhanced production of troponin I, a protein involved in muscle calcium binding and contraction, and connexin-43, a protein involved in electrical coupling between cells that is believed to play a critical role in the development of the heart's architecture and in the synchronized contraction of the heart.

The study was funded by the National Institutes of Health and the American Heart Association. The paper's co-first authors were Tal Dvir, PhD, and Brian Timko, PhD, both of the Department of Chemical Engineering, Massachusetts Institute of Technology, and the Laboratory for Biomaterials and Drug Delivery at Children's Hospital Boston.

Recommend this story on Facebook, Twitter,
and Google +1:

Other bookmarking and sharing tools:

Story Source:

The above story is reprinted (with editorial adaptations by ScienceDaily staff) from materials provided by Children's Hospital Boston, via EurekAlert!, a service of AAAS.

Journal Reference:

Tal Dvir, Brian P. Timko, Mark D. Brigham, Shreesh R. Naik, Sandeep S. Karajanagi, Oren Levy, Hongwei Jin, Kevin K. Parker, Robert Langer & Daniel S. Kohane. Nanowired three-dimensional cardiac patches. Nature Nanotechnology, 25 September 2011 DOI: 1038/nnano.2011.160

Note: If no author is given, the source is cited instead.

Disclaimer: This article is not intended to provide medical advice, diagnosis or treatment. Views expressed here do not necessarily reflect those of ScienceDaily or its staff.

View the original article here