USB Flash Drives: Components, Uses, and Myths Dispelled The USB flash drive—also known as a jump drive, data stick, or thumb drive—continues to be the most popular portable storage device, with sales estimated to exceed 500 million annually by 2020. Although cloud storage is making headway in the same market spaces, USB drives offer capacity, speed, and size that make them ideal for many uses beyond just storage, including some perhaps unexpected uses as well. This article explores what’s inside a USB flash drive, explores various uses, and dispels common myths. A Look Inside A typical USB flash drive includes a USB connector, a mass storage controller, one or more flash memory chips, and a crystal oscillator, as well as additional features such as jumpers, LEDs, switches, and unpopulated space. The memory capacity and speed of USB drives continue to increase. As of the time of this writing, 512GB USB drives are becoming common, with 1TB capacity also available. The average speed for a highly-ranked 64GB USB 3.0 device is 104MB/s for a write operation and 171MB/s for a read operation. Recently, USB drives incorporated the Type-C connector, which provides a yet even smaller and thinner connector compared to the Type-A connector. The Type-C connector has a rounded, symmetric shape that fits into ports easily yet securely, and works either way up (solving the problem that everyone has faced where they have to stick a USB plug in three times before it eventually goes in). Figure 2 shows a USB drive that accommodates both the old and the new sockets. How to plug a thin promo USB Drive into a computer? Technological advances have allowed a regular USB to become increasingly compact. While the more modern, state-of-the-art USBs are thinner, sleeker and sexier, they have a bit of a learning curve associated with using them. In particular, first time users often are not sure which direction the USB should be facing when plugged in to a USB port. Among other types of promo flash drives, these include our famous promotional Wafer USB Cards, and custom USB Clip. Tired of losing your precious pen drives? Tired of spending hours searching for them, only to find them tucked away in some dingy corner? Or tired of having to finally give up and go run to the nearest store for another one? It seems like product designers Claire Pondard and Léa Pereyre have gone through the same dilemma innumerable times because they’ve decided to answer all our USB-related prayers! Their key-shaped intriguing product ‘Saint Antoine’ goes beyond any ordinary USB key. Deemed as common everyday products, due to their nimble size and consistent usage, pen drives are easily misplaced. However, Saint Antoine has been equipped with a crisp UDP chip. Now, what’s so special about this chip? After thorough calculations and necessary trial runs, the chip was customized to fit perfectly between the keys of a laptop/computer keyboard, ensuring it will be tightly fixed to it at all times. The grooved edges and branch-like structure of the pen drive allow it to sneakily merge into the crevices of the keyboard, without destroying the screen once the laptop is shut. A Look at the MicroSD Card of the Future: Speed and Capacity meet Reliability Manufacturers recently released the largest capacity and fastest microSD cards ever made. The 128 GB cards demonstrate more than a 1,000-fold increase in storage density over the last decade, and the fastest speeds of these microSD cards now rival other high-speed options for wireless computing. The SD Association is made up of application developers and micro SD and component manufacturers. The organization determines microSD technology specifications and sets standards and roadmaps for the industry. SD Association President Brian Kumagai explained some of the new features and recent technology trends that help ensure microSD cards remain relevant and offer viable storage for many products and markets in the future. Markets driving standardization MicroSD cards are predominantly used in smartphones and other mobile devices that have limited space. When microSD cards first arrived on the scene, they quickly became the most popular form factor for mobile devices, and according to Kumagai, that is what drove their success. The microSD market is rapidly growing as more smartphones ship with microSD card slots. Even though the newest phones made by industry giant Apple do not currently accommodate microSD cards, those made by Samsung and many others do. Over time, smartphone manufacturers have reduced the amount of on-board memory that ships with smartphones, thus lowering their hardware costs. Consumers have compensated by adding additional storage, often using 8 GB microSD cards. In fact, the bulk of microSD cards sold is used in smartphones, but sales of larger cards (16 and 32 GB) continue to grow. MicroSD card use is also growing in other devices that need small form factors, such as consumer digital imaging and video cameras like the GoPro action camera, night-vision IP security cameras, nanny cameras, automotive in-dash cameras and tablets. MicroSD is still the storage space of choice as devices become smaller and cards gain higher capacity, become faster and exhibit better performance. Capacity: It’s all in the flash memory technology The fundamental technology in all SD cards and any type of solid-state storage device today is NAND flash memory. Current NAND flash memory chips use floating-gate processes that all manufacturers support. Over the years, decreasing the horizontal line width of the lithography technology used in NAND memory production has created higher density storage capacities. The industry roadmap shrank design-rule dimensions for memory features from 110 nm down to the current size of 19 nm, making smaller NAND chips and allowing microSD cards to use more of them to hold more data. At these thin-line widths, there are only a few electrons of charge inside a single level cell. NAND chips using 16 nm line widths will be coming soon, but Kumagai says the industry is starting to see the limitations of scaling to smaller lithography. Within the next year, NAND suppliers are expected to roll out the next generation technology that will go vertical and offer much higher densities than the current technology. The 3-D concept involves grinding individual cells so they are much thinner and stacking more of them so there is more than one cell in the same horizontal plane. “This technology is more difficult to produce. The thinner it is, the more difficult it is to read all the different levels, and error correction becomes needed,” says Kumagai. All major NAND suppliers have 3-D technologies in development now. “The microSD card will look the same on the outside and at the interface, but the new 3-D NAND processes may help reliability and have other impacts on the industry if the technology is cheaper,” Kumagai says. One way higher reliability processes will change the industry is that it will create new uses for microSD cards. They will be used in high-end automotive or industrial applications such as bar-code readers and scanners that need to store important data. Strategies for higher speeds While memory manufacturers are increasing the storage capacity by improving NAND technologies, they are also increasing microSD card speed with a combination of hardware and software strategies. One way is through the interface. A new high-speed serial interface (UH-II) handles the speed by having a second row of pins connect to the outside world and a new file system that supports much larger micro XSDHC or SDXC cards that are 32 GB to 2 TB. The newest second-generation ultra-high-speed (UHS2) cards using this interface have much faster read and write times at up to 312 mbps, up from 104 mbps on older generation cards. Another area where speed can be gained is in the flash-memory controllers. This component manages the NANDs and does a handshake to the outside world. The controllers in the fastest-speed-class microSD cards use strategies to help both functions, such as using multiple channels and interleaving data. What is an SSD? A solid state drive (SSD) is an external storage device for your computer that works like a USB flash drive. An SSD has no moving parts and is more reliable than the traditional hard drives it's replacing. Visit Business Insider's Tech Reference library for more stories. How an SSD works Like a hard drive, an SSD is used to store large volumes of data whether the system is on or off, for extended periods of time. But unlike hard drives, an SSD has no moving parts, and is more akin to a flash drive. Instead of reading and writing data to a spinning platter, an SSD stores data on flash memory chips (sometimes referred to as NAND flash memory). In this way, an SSD is essentially no different than a USB flash drive, or the memory you'd find in a smartphone or tablet. In addition to memory chips, an SSD also has a controller chip. The controller is responsible for knowing where data is stored on the device and can find requested data in nanoseconds — almost instantly — which makes SSDs very fast storage devices. Difference Between Flash Drive and Pen Drive Flash drives and pen drives are two terms that we use interchangeably today. However, that was not the case 15 years ago. Flash drives were devices that ran on flash memory. Their sole purpose was to store information and transfer it between the connected computers. The connection takes place through the USB port that is on the hardware. Pen USB flash drive, on the other hand, were bulkier than flash drives and had more length to it. Due to their elongated size, they were given the name Pen Drives. They also ran on flash memory and had a USB interface to communicate with the computer。 Nowadays, the difference in size is no more. All the flash drives and pen drives of today have the same function, the same internals, and the compact form factor. So there is no real distinction you can draw from them. Hence, the pen drives and flash drives of today are essentially the same. Next, we will go over the different types of USB flash drives. Please note that they can be categorized according to their uses, or physical characteristics. We attempt to find a balance between the two.