Do you need a larger quantity? Call us at 1-888-352-2298 or chat with one of our sales agents for a quantity discount.
order by 5pm ET M-F for next day delivery
always free ground shipping in USA
We have stock in our Minnesota warehouse. Click To Chat for the best price you'll find online.
|Memory Speed||2666 MHz|
|Data Integrity Check||ECC|
ECC, which stands for Error-Correcting Code, refers to a type of memory module that incorporates advanced error-checking and error-correction capabilities. ECC memory goes beyond standard non-ECC memory by providing additional measures to ensure data integrity.
The primary purpose of ECC memory is to detect and correct certain types of data errors that may occur during the operation of a computer system. It achieves this by adding extra bits, known as parity or checksum bits, to each memory word stored in the module.
These extra bits enable the ECC mechanism to identify and automatically correct single-bit errors. If a single bit is flipped or corrupted, the ECC memory can detect the error and rectify it, preventing potential data corruption and maintaining accurate information storage.
ECC memory is particularly prevalent in critical computing systems, such as servers and workstations, as well as in environments where data integrity is paramount, such as scientific or financial applications. By providing an additional layer of error detection and correction, ECC memory significantly reduces the risk of undetected errors that could lead to system crashes, data corruption, or inaccurate calculations.
It's important to note that the utilization of ECC memory requires support from both the motherboard and the memory controller in the system. Not all systems or consumer-grade motherboards offer compatibility with ECC memory, so it's crucial to verify the specifications and requirements before incorporating ECC memory modules into a specific system.
DIMM stands for Dual In-Line Memory Module. It is a type of memory module used in computers to provide random access memory (RAM). DIMMs are rectangular circuit boards that contain multiple memory chips and have electrical contacts on both sides. They are designed to be inserted into a computer's motherboard, connecting to the memory slots.
DIMM memory modules were first released in the late 1980s and gained widespread adoption in the 1990s. They replaced the older SIMM (Single In-Line Memory Module) technology, which had a single row of electrical contacts. DIMMs offered several important advancements over SIMMs:
Overall, the introduction of DIMM technology represented a significant advancement in computer memory. It provided higher capacity, increased speed, improved reliability, and greater compatibility, all of which contributed to enhanced system performance and efficiency. DIMMs have continued to evolve over the years, with various iterations and advancements, such as DDR (Double Data Rate) and its subsequent generations, further improving memory capabilities in modern computer systems.
RAM speed is measured in megahertz (MHz) and refers to the number of cycles per second that the RAM can perform. In the context of "2666 MHz" RAM, it means that the RAM module is capable of performing 2,666 million cycles per second.
This measurement is often associated with DDR4 RAM, which is a type of Double Data Rate (DDR) RAM that was widely used in computers and servers. DDR4 RAM with a speed of 2666 MHz was released around 2014-2015. The release of DDR4 RAM marked an important advancement in technology for several reasons:
Overall, the introduction of DDR4 RAM with higher speeds like 2666 MHz was important for improving overall system performance, energy efficiency, and the ability to handle more demanding tasks. As technology continued to advance, even faster RAM speeds and newer memory technologies have been developed, further pushing the boundaries of computing capabilities.
If memory runs at 1.2V, it means that the memory module operates at a voltage of 1.2 volts. The voltage specification is an important factor in determining the power requirements and compatibility of the memory with the system.
Memory modules running at 1.2V are commonly associated with DDR4 (Double Data Rate 4) memory technology. DDR4 was introduced as the successor to DDR3 and brought significant improvements in performance, energy efficiency, and data transfer rates.
The release of 1.2V memory modules, specifically DDR4 modules, was driven by major memory manufacturers, including Samsung, Micron, SK Hynix, and others. These manufacturers recognized the need for higher memory capacities, increased speed, and improved power efficiency to meet the evolving demands of computing systems.
The shift to 1.2V voltage in DDR4 modules was motivated by the industry's focus on energy efficiency and power savings. By operating at a lower voltage, DDR4 memory modules offered reduced power consumption and heat generation compared to their predecessors.
The lower voltage of 1.2V in DDR4 modules was chosen as a balance between performance and power efficiency. It allowed for improved data transfer rates and higher memory densities while minimizing power requirements and contributing to energy-conscious computing.
DDR4 memory modules running at 1.2V voltage became the standard for mainstream computer systems, including desktops, laptops, servers, and other computing platforms. They provided higher performance, increased memory capacities, and improved power efficiency compared to previous memory technologies.
It's important to note that compatibility with the system's memory controller and motherboard is essential when using 1.2V memory modules. The system's hardware should be designed to support and operate at this voltage to ensure proper functionality.
DDR4 memory, operating at 1.2V, revolutionized the memory landscape by offering improved efficiency and performance for a wide range of computing applications. Its introduction brought significant advancements to memory technology, catering to the growing demands of modern computing systems for faster, more power-efficient memory solutions.
Out of 5.0
of customers that buy from Boost Hardware give them a 4 or 5-Star rating.
Here at Boost we got your back on every single purchase big or small!
YES, YOU CAN CANCEL YOUR ORDER
Did you change your mind and need to cancel your order? ALL Purchase Orders are cancelable until the product is paid for and/or shipped.
Purchasing New and Refurbished IT equipment from Boost Hardware will already put you in front of your competition and help you bottom line as we beat all of our competitors! Take a look for yourself with our Competitive pricing tool Above!!
All of our IT Hardware is tested through an extensive diagnostic process by certified Technicians. We are able to simulate the hardware's capabilities in an accurate environment, allowing us to guarantee that the equipment will be ready for use once it is delivered to you.
Even with our extensive testing procedures, equipment does fail from time to time beyond our control due to shipping or various reasons. Boost Hardware offers a 1 year hardware warranty, replacing any faulty or damaged equipment within the next business day. The RMA process we like to keep VERY simple, so there is no paperwork to fill out! :) We will provide a return label for any parts that you need to ship back on us. That’s it!!
We know that you sometimes cannot wait to get a replacement part or Server up and running, that is why we offer priority overnight delivery next day 10:30AM guaranteed delivery! This way you will receive your order the next morning.