Three Reasons to Use a Rackmount Recorder

Since mankind’s discovery of the ability to record history, from monks rewriting scrolls in caves and monasteries to the invention of the tape recorder, we have attempted to record and share our history and our presence on this Earth with the greatest detail. Detailed recording capabilities have never been so great until the dawn of digital recording. 

What are the reasons to use a rackmount recorder over any other type? A rose by any other name smells as sweet, right? To put it simply, rackmount recorders are a better type of digital recording rose. They are designed to meet industry standards, and are compatible with other types of electronic equipment, to be a part of the whole in a sense. They are the missing puzzle piece to complete any professional recording ensemble.

At the same time, this piece of equipment is also extremely easy to use, so that even beginners working on a small project would benefit from having one. If you’re only recording voice audio for example, say for an interview, this machine is easy and straightforward to use, with simple input and output features that will make it a snap.

The next reason is that, in the end, you get a great quality finish. The audio is recorded seamlessly, and comes out clean. And on top of that, performance is consistent. There’s nothing else you need from a digital recording device: quality, simplicity, and guaranteed service. Whether you are recording a simple dialogue audio, or using it as one piece of a set of studio recording equipment, a rackmount recorder is sure to deliver the best finished product, at an affordable price.

Even the most mundane recording is a form of art. It’s a time capsule, sealing in that moment: a moment of one life on Earth in this solar system in this galaxy in this universe. If your recording were all that’s left after humanity is gone, wouldn’t you want it to be the best sounding recording possible? That’s a fourth reason to use a rackmount recorder for you.

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How Does a Chip Scale Atomic Clock Work?

An automatic clock is an integral part to any electronics system. In fact, they are an important part of the equation for many different electronic and scientific endeavors. To better understand what a chip scale atomic clock is (also known as CSAC) we’ll start by describing different types of clocks and how they function.

A regular clock is used to keep track of time by counting a resonator’s “ticks”. For example, in a pendulum clock, the pendulum acts as the resonator, swinging once each second, and the gears of the clock count each swing to get an accurate measure of the passage of time.

A digital clock is more advanced, and instead of counting pendulum swings, it uses oscillations caused by power lines, or in some cases, a quartz crystal as the resonator.

An automatic clock is a clock that is radio-controlled, and synchronized via a radio transmitter to an atomic clock at a distant location. Some use a single transmitter, or they can use many, such as a GPS, or Global Positioning System.

An atomic clock is able to use the resonance frequencies of atoms for its resonator source. The main benefit to this is that the atoms resonate at a very consistent frequency, so it ends up being much more accurate than any other type of clock. The precision of the atomic clock is what makes many technological feats today possible. They keep the Internet working smoothly, and are essential to GPS functions. The marvel of the chip scale atomic clock is that the chip inside that powers it can do so with such efficiency that the clock can be smaller than ever, weighing only 35 grams, and use significantly less power. This means they will last much longer than any other type of clock before, which is crucial in many situations such as military drones that lose their GPS signal or get jammed. The CSAC allows communications to be synchronized quickly in emergency situations.

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Understanding PCIE Interfaces

PCI Express, also known as PCIE, or PCI-E, is essentially an expansion card format, which is capable of operating at very high speeds, that connects a computer to its attached peripherals.  PCI stands for Peripheral Component Interconnect.

There are three interface types: SATA, SAS, and PCIE. SATA stands for Serial Advanced Technology Attachment, it is limited to 32 requests, and is generally less scalable than other interface, but is optimal for light workloads such as those found on desktop PCs and other embedded applications. SAS, or Serial Attached SCSI, is traditionally used for enterprise storage, can handle up to 256 requests, and is highly scalable.

Unlike the other two interfaces, PCIE is specifically designed to be an I/O, or input output interface between peripheral components inside a system, rather than a storage interface it is an expansion interface, and require a driver to function. They are also the fastest of the three, and are located closest to the CPU, which makes them even more ideal for I/O application acceleration or even as a caching solution.

PCIE’s are designed to replace the older model PCI, PCI-X and AGP. There are many improvements that have been made over the old models, including higher maximum system throughput, a lower I/O pin total count number, as well as smaller physically, and better at performance scaling. They also have more detailed detection of errors, and a better reporting mechanism called AER, or Advanced Error Reporting. Most of the more recent PCIE’s are able to support I/O virtualization hardware.

PCIE interfaces are becoming more and more popular, acceleration of performance in servers and workstations are making them high in demand. Manufacturers of PCIE interfaces are making innovative changes and working to improve them in order to meet serviceability and storage requirements for their customers and consumers.

To learn more about PCIE Interfaces, click here!