In turn, it aims to reduce technical headaches and transcoding costs. Content publishers can generate a single set of files for encoding and streaming that should be compatible with as many devices as possible, from mobile to OTT, as well as to the desktop via plug-ins or HTML5.
Consumers will not have to worry about whether their devices will be able to play the content they want to watch. As mentioned previously, there are several major backers of the standard; some of which include Adobe, Samsung, Microsoft, Dolby, Netflix and Cisco.
Google also supports it on higher res video on YouTube and Chrome as well. The OTT space has been the major driver in adaption. For more information on the latest in DASH deployment click here. JavaScript acts as the intermediary for the streams which can be either live or on-demand.
Because of this, video players can operate without the use of a plug-in, and enables leading streaming standards like HTTP-Live-Streaming, time shifting, and alternate audio tracks. MSE is not specific to any codec, container, or DRM scheme, so it can work with any format the browsers supports, creating the opportunity for seamless cross-platform playback. This was a requirement from the media and entertainment industry since the browser is viewed as insecure and untrusted.
The CDM is the trusted component that content owners rely on for copyright protection. The CDM can accommodate whatever scheme the content distributor prefers. This encourages both cross-platform compatibility and improved playback experience. Whether decrypting and serving, encrypting and decrypting, or bypass the CPU by using the GPU, the more the CDM handles the more secure the content remains in the end-to-end workflow.
For example, the dense cores left behind after stars explode - known as neutron stars - can rotate at remarkable rates. The neutron star at the center of the Crab Nebula is moving at 30 Hertz, in other words making 30 rotations in just one second. That's almost as fast as Olympic ice skaters, which is amazing especially when you consider that the neutron star is over 10 miles or 16 kilometers across!
Perhaps the next time you watch a gymnast tumble or a skier do a flip, think of the other examples in our lives and across space where rotation is taking place. Quicktime High Res They run faster, jump higher, and spin quicker than most of us ever will. Many of us are also in awe of what the Universe has to offer. Astronomers have explored the heavens with their telescopes and come up with findings that are so fantastic it can be hard to believe they're real. What do Olympic athletes and objects in space have in common?
The answer is matter in motion, often in extreme examples. Whether it is a human body moving at the fastest speeds possible or the debris from an exploded star blasting through space, the physics of that motion is, in many ways, the same. The AstrOlympics project explores the spectacular range of science that we can find both in the impressive feats of the Olympic Games as well as in cosmic phenomena throughout the Universe.
By measuring the range of values for such things as speed, mass, time, pressure, rotation, distance, and more, we can learn not only about the world around us, but also about the Universe we all live in. The Olympics are an opportunity to behold the limits of human abilities in athletics. After all, the Olympic motto is Latin for "faster, higher, stronger.
Let's find out just how far we've learned science can go. We see bubbles blown out of soapy wands and others that float from the bottom of a fizzy drink to the top. But bubbles also represent important physical phenomena that can be found across many scales and in many different types of objects. Let's look first at the soap bubble. Soap bubbles are formed when someone injects breath or air into a film of soapy water.
This fits in with the definition of a bubble being a sphere enclosing liquid or gas. We can also find bubbles in space, where they are not made of soap like those here on Earth. Rather cosmic bubbles are blown out of the material we find in between stars and galaxies.
Take, for example, this object. The bubble in the Bubble Nebula is being blown up by a massive star that sits in its center. This star has powerful winds that are driven off of its surface, pushing the gas and dust that surround the star outward. The Bubble Nebula is much bigger than any soap bubble you will find on Earth. It stretches across over 63 trillion miles in diameter. Even bigger still are the bubbles that astronomers find carved out in galaxy clusters.
Galaxy clusters are the largest structures in the Universe held together by gravity. In addition to the hundreds or even thousands of individual galaxies that make up these gigantic objects, enormous amounts of hot gas envelope galaxy clusters. By using X-ray telescopes like Chandra, astronomers can examine this superheated gas.
In objects like the galaxy cluster called MS What could blow up such an enormous bubble? The answer is a supermassive black hole, weighing nearly a billion times the mass of the Sun, that lies at the center of the cluster.
This black hole is shooting out powerful jets that push the million-degree hot gas outward and create these incredible bubbles. So the next time you pick up a bottle of bubbles, you may want to take a moment to realize how far-reaching bubbles truly are. You might only be able to inflate a bubble the size of a few inches, but elsewhere in the Universe, bubbles are forming in places and in sizes that are almost impossible to imagine.
This happens when light is moving through one medium like air, and then enters another medium like glass or water. We experience this all of the time here on Earth. Whenever we put eyeglasses on or insert contact lenses, we are taking advantage of the fact that we can bend the path of light so it can properly focus onto the retinas of our eyes. We also see examples of bent light in the slightly oval appearance of the setting Sun or when we think we see water on in the distance on a hot highway.
Light being bent is also very important when we want to learn about things in space. In fact, some of the most exciting discoveries made by the Chandra X-ray Observatory and other telescopes involve light that has been bent. Take, for example, the Bullet Cluster. This system contains two galaxy clusters that have rammed into one another at tremendous speeds. The collision was so violent that normal matter has been wrenched away from dark matter.
While we can't see the dark matter directly, we can learn where it is by light being lensed. How does this work? When the light from very distant galaxies passes through a massive cluster of galaxies, like in the Bullet Cluster, the cluster can bend the path of the galaxy's light, in essence acting like a lens. From the vantage point of our telescopes, the distant galaxies appear distorted or elongated.
Astronomers can use this information to build maps about where the dark matter is, which tells them more about this mysterious substance. The ultimate light benders in the Universe are black holes, which can bend light rays into a closed loop so they never escape the black hole.
Chandra has observed many black holes and their environments over the course of the mission. Nowadays, various video games on Olympics especially on London Olympics are available in the market.
To help people enjoy those video games better, the Olympic video games are designed for various game consoles. Therefore this post will display four different versions of Olympic video games that will help you to spend an impressive London Olympics In this 8-bit Olympic video game, players need to heavily rely on button mashing. Moreover, there are eight Olympic sports events provided for selection. Also two players can choose to compete with each other or with the CPU.
In this Olympic video game , player can act as an athlete who strives for the golden medal. Over thirsty sports event are provided to help players fully experienced the atmosphere of London Olympics One advantage of this Olympic video game lies in its vivid video quality and lifelike operations.
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