Smart phones use which of these storage technologies

Have you wondered how many various types of data storage devices exist? The answer is simpler than you think. Standing in the storage device aisle at your local digital electronic warehouse will leave you feeling overwhelmed. The truth is, data storage devices all break down into two main categories: primary and secondary devices.

Data Storage.

Primary storage devices are comprised of firmware storage, such as ROM and HDD. Secondary devices are primarily USB driven, such as USB memory sticks and flash drives. SD & MicroSD cards are also a popular type of secondary storage, mostly on today’s cell phones and smart phones. The most popular devices for storing data and images usually fall into the secondary category.

Data Storage Failures and Recovery.

Losing all of your files, photos, and stored data is a scary thought, isn’t it? We store so much of our personal and business lives on digital devices that the idea of a corrupted or damaged drive can be as scary and impactful as identify theft. Today, the most common failures that lead to lost data take place on MicroSD cards and USB based flash drives. Coming soon, Solid State Drives (SSD) will be a primary storage device as well.

microSD Drives: Today we have a few sub categories, microSDHC & microSDXC. These handy devices can become damaged out of the blue. They are among the most commonly impaired, as so many cell phones and other devices (such as tablets or smartphones) have adapters where MicroSD cards are inserted to store device data. Constant or improper insertion can lead to damage. More about micro SD card data recovery.

Proud Client

USB Drives: Although external USB drives are popular, they are rather fragile. It’s very common for such devices to be dropped or damaged as a consumer inadvertently drops, breaks, or plugs them in incorrectly, which can lead to data loss.

CompactFlash Drives and SD Cards.

These devices are very common with photographers and consumers with digital cameras. Did you know that SD cards are different from MicroSD cards? SD cards came first. They were most commonly used for PC-to-PC data transfer and in the first digital cameras on the market. They can also be known, as their faster & versions, SDHC and SDXC. As devices became more compact and mobile, so too did additional storage devices. microSD cards came into existence to meet the storage needs of smaller and more compact devices. They are most commonly found in smaller devices that need large amounts of storage space, such as cameras, cell phones, and tablets.

There is also a difference between MicroSD and MicroSDHC, as well as SD and SDHC. The “HC” isn’t just the addition of extra letters. The best way to look at Micro SDHC and SDHC are as higher capacity in comparison to a regular MicroSD and SD cards. Speed is also one of the differences as well, pro photographers need faster speeds such as SDHX & SDXC. For information on digital image recovery, click here.

Tablets for Data Storage.

There is a huge market for tablets, which are quickly replacing the PC market. Many tablets are portable and can easily become damaged. Tablets, like cell phones, have internal and on board NAND flash memory chips, which are sensitive to environmental changes (i.e., temperature, humidity, pressure, etc.) and impact (i.e., being dropped, banged, jostled, etc.).

Gone are the days of stationary computers in clean rooms. Our ever-growing array of compact, mobile devices has granted us a variety of compact data storage devices. Although amazingly convenient, these devices are far more susceptible to damage.

Recovering data from small, compact devices can present a challenge. You should also choose an expert with both experience and positive reviews. The fact is, you may only have one shot at retrieving as much data as possible. Would you leave that shot to chance and an inexperienced data recovery technician who may or may not have firsthand experience working with these intricate storage devices? eProvided can get inside these tablets when they stop functioning and consumers need to recover their data.

Calvin Wankhede / Android Authority

Virtually all modern devices rely on flash memory — an electronic data storage technology that can preserve information for long periods of time. Your smartphone, for instance, uses some form of flash memory for storage, and it’s likely that most laptops and computers around you utilize it as well. However, not all flash memory is created equal — some implementations are far superior to others. So in this article, let’s break down the technology, how it works, and the various terms you may have heard associated with the technology.

See also: The best Android phones with expandable memory

What is flash memory and why is it so popular?

Edgar Cervantes / Android Authority

Flash memory is a non-volatile data storage medium. The non-volatile bit means that data is retained even when the device completely loses power. That’s in stark contrast to RAM, a type of volatile memory that loses all of its data when powered down or reset. Flash memory’s ability to store data without a power source, along with other benefits we’ll discuss, makes it ideal for use as a storage medium, and it’s only growing in popularity.

Hard disks were once the dominant storage medium for electronic devices. The first-generation iPod, for instance, used a 5GB hard drive from Toshiba. Similarly, most laptops and desktop computers until the early 2010s had hard disks as their primary storage device. But much of the consumer electronics industry has now dropped hard disks in favor of flash memory, especially in applications like gaming that require a fast storage medium.

Flash memory offers numerous advantages over hard drives, including speed, durability, and size.

Hard drives have numerous disadvantages. For one, their spinning platters make them largely mechanical devices. In other words, they have several failure-prone moving parts. Secondly, they’re not very fast, since a magnetic needle has to physically reach specific parts of a spinning platter to read and write data.

Flash memory, on the other hand, is entirely electronic. Data is still stored digitally, in the form of 1s and 0s. Instead of using magnetism like in hard drives, however, flash uses so-called memory cells built from transistor gates. The absence of moving parts affords flash memory-based storage devices several benefits. They often have longer lifespans, occupy less space, and operate significantly faster than hard drives. Of course, the technology has a few drawbacks, but besides cost, most don’t really affect the typical user.

Read on: The best USB flash drives

Flash-related terms you should know

Sarah Chaney / Android Authority

SATA: Introduced in the early 2000s, SATA refers to the communication interface between a computer’s motherboard and storage devices like hard disks. The latest most popular revision, SATA III, offers a maximum throughput of 600MB/s — far from the cutting-edge. The standard hasn’t seen any updates since 2009 but remains widely used today.

NVMe: NVMe or non-volatile memory express is a communication protocol for storage devices. Unlike SATA, NVMe was designed for higher throughput storage devices like SSDs. Since NVMe SSDs have a direct path to the CPU, they’re often significantly faster than SATA SSDs. NVMe can hit speeds of 3,500MB/s, or 6x faster than SATA III.

PCIe: PCIe stands for peripheral component interconnect express and provides the communication backbone for NVMe devices. The performance of an NVMe drive may vary depending on the CPU’s PCIe capabilities. For example, a PCIe Gen 4 NVMe SSD may exhibit slower speeds in older computers with only Gen 3 capabilities. On the other hand, newer devices like the PlayStation 5 mandate PCIe Gen 4 NVMe SSDs above a certain speed threshold for a consistent user experience.

M.2: M.2 refers to a physical connector used for expansion cards. The slot is typically found on computer and laptop motherboards, but you may also see it on other devices like the PlayStation 5 (the green space pictured above). An M.2 connector can be electrically wired up to function in either SATA or PCIe mode. Laptops often use M.2 for high-bandwidth expansion cards like Wi-Fi cards and SSDs.

How is the technology related to SSDs, UFS, and eMMC?

Storage devices that utilize flash memory come in various shapes and sizes, depending on their intended use case. A computer’s primary boot drive, for example, needs to be faster and more durable than a thumb drive that you’ll only use to store media files. SSDs, eMMC chips, and SD cards all use flash memory, but exact implementations can vary.

Solid State Drives (SSDs) typically contain more than just flash memory — many also house a DRAM cache and memory controller. The former can speed up reads and writes, but budget drives tend not to include it. The controller, meanwhile, helps the system interface with the drive’s stored data. In some cases, it can also help increase the drive’s longevity through techniques such as wear leveling and error correction.

Calvin Wankhede / Android Authority

SSDs (left) enjoy faster read and write speeds than hard drives (right)

SD cards and USB drives are much simpler, by comparison. Both occupy a much smaller footprint than SSDs and, consequently, are also quite a bit slower. Furthermore, SSDs typically house multiple memory packages to increase the total capacity. Smaller SD cards and USB drives cannot do so since they have to squeeze into a smaller form factor.

SD cards typically offer worse durability and speeds than SSDs, even though both share the same underlying technology.

Finally, you may have also heard of eMMC and UFS flash storage chips in the context of smartphones, tablets, and laptops. MMC stands for embedded MultiMediaCard, while UFS is short for Universal Flash Storage. You’ll find these embedded chips soldered directly onto a device’s motherboard.

These days, UFS has started to replace eMMC as the standard for smartphone storage. The former is significantly faster (up to 2,100 MB/s vs 250MB/s) as it supports simultaneous read and write — think of UFS as a two-way multi-lane highway and eMMC as a one-way road. Both are still significantly faster than hard drives, though.

Storage speeds are more important for certain applications than others. High-resolution video recording, for instance, can overwhelm most lower-end SD cards. Similarly, games and other intensive workloads can benefit from faster storage.

How does flash memory work?

Without getting too deep into the specifics of the electronics involved, flash memory stores data in memory cells. These cells contain floating-gate transistors that can trap electrons for a long period of time, but not forever. These cells have three operations: read, write, and erase, depending on where you apply a voltage. To perform a write operation, the floating gate in the memory cell is either charged or discharged — the former denotes a logical 0, while a discharged state indicates 1.

Modern storage devices organize memory cells in pages that allow large amounts of data to be accessed simultaneously instead of cell-by-cell. The most common type of flash storage, called NAND flash, contains blocks of 32 or 64 pages.

A consumer device containing NAND flash, like a USB drive or SSD, has millions of memory cells stacked horizontally, vertically, or in both dimensions — the latter is sometimes called 3D NAND. As you’d expect, a device that requires such precise operations and density is more expensive to manufacture than traditional hard drives.

NAND flash's complexity means that it is expensive to manufacture.

Manufacturers have come up with ways to combat flash memory’s high cost, though, with the most common technique being the use of multi-level cells. Instead of storing a single 0 or 1, triple-level cells (TLC) and multi-level cells (MLC) can store two, three, or more bits. While this strategy improves storage density and reduces manufacturing costs, it also has a negative effect on speed and durability. Still, the cost-benefit means that most consumer-grade storage devices today use TLC or MLC-based flash memory instead of single-level cells (SLC).

See also: The best internal and external SSDs

What are the technology’s limitations?

Calvin Wankhede / Android Authority

Flash storage has become the standard for compact electronic devices these days, but the technology is far from perfect. Besides high prices, which we’ve already discussed, flash memory can suffer data degradation or bit rot over time. If stored in an unpowered state for several years, memory cells can suffer from electron leakage and, eventually, data loss. While hard drives can also suffer from bit rot, they typically last a bit longer when powered down.

A bigger issue with flash storage is write endurance, or program/erase cycles. In a nutshell, it refers to the amount of data you can write before the memory cells eventually wear out. Generally speaking, the more information you squeeze per memory cell (TLC and MLC-type drives), the worse the endurance.

Flash storage suffers from limited endurance — it can only survive a limited number of rewrites.

Storage device manufacturers typically guarantee a drive’s lifespan up to a certain usage point, quoted in TBW or total bytes written. The 1TB variant of Samsung’s 860 Evo SSD, for instance, has a quoted endurance of 600TBW. A drive may still work beyond its rated TBW — just don’t expect any warranty from the manufacturer. Higher endurance drives typically cost more — especially those designed for enterprise use.

Finally, flash storage still can’t beat hard disks in terms of capacity. Most consumer SSDs top out at 2-4TB, while you can easily buy hard disks that exceed 10 or even 15TB at the same price point. This may change at some point in the future, but for now, hard disks reign supreme for archiving large amounts of data.

Continue reading: A beginner’s guide to NAS drives