Bragin Igor

Trade with confidence, across mainstream liquidity of Binance, OKB, Kucoin & HitBTC. Licensed Cryptocurrency Exchange that aims to list more than 500 coins & tokens.

The BITToken is designed to reward token holders in fun and interesting ways. The crypto niche is always expanding and BITT will be a bridge that brings supporters of different projects together.

It will be the native currency for any community that adopts it and there will be big incentives to hold, stake, and spend with BITT.

Club members will receive discounts for holding BITT, airdrops for participating in social groups and engaging with BITT platforms, NFTs with unique utility, and even utility in the SANDBOX game.

BITT brings value to the crypto populous as a whole by creating a fun and rewarding environment for everyone who participates. It closes the gap between hardcore crypto-heads and new disciples. Crypto is full of FUD and deceit, but BITT is a giving token that seeks to level the playing field and reward active community members.

DONASWAP is aiming to be the world’s first, and biggest “Decentralized Donation Ecosystem” (DEDECO).

Our mission is to function as the funding seed for charitable organizations. Our blockchain (FireChain) will be designed to do just that.

STAKE, FARM, and SWAP various cryptocurrencies and provide help to charities, without it costing you an extra penny! A huge part of transaction fees of our future ECOSYSTEM will be used to fund foundations across the world.

DONASWAP will be the official DEX on our own blockchain called the “Financial Relief Chain” (FIRECHAIN)

Aspire embeds data into regular gAsp blockchain transactions. To a regular gAsp client, these transactions look like normal gAsp transactions, with one party sending another party a very small amount of gAsp. An Aspire node (which runs the gAsp client along with the Aspire client software will recognize and interpret the data in these gAsp transactions based on specific rules. From this, it constructs its own ledger of Aspire transactions that it has seen on the gAsp network.

Aspire is revolutionary asset solution platform designed to allow users to easily create their own digital assets under a secure environment that is extremely affordable and quick.

Aspire was created to offer an efficient and alternative solution to the current asset platforms like Counterparty, RavenCoin, and Ethereum. These other platforms have proven to be expensive and in many ways deficient for asset deployment.

Aspire was built to run on it's own dedicated core blockchain with gas coin known as "GASP". By allowing Aspire to run on the gAsp blockchain, Aspire has improved three major components, speed, security, and cost efficiency when creating and sending digital assets. Every action or transaction performed on Aspire will require a small amount of "GASP".

Tanks! For Playing is pioneering Social Crypto Gaming in a Turn-Based Multiplayer Online Blockchain Game involving cooperation and strategy.

Dual In-line Memory Module (DIMM) is a form factor of DRAM memory modules. This form factor has come to replace the SIMM form factor. The main difference of DIMM from its predecessor is that the contacts located on different sides of the module, are independent, in contrast to SIMM, where the symmetric contacts located on different sides of the module, closed to each other and transmit the same signals. In addition, DIMM implements the function of the detection and correction of errors in 64 (no parity) or 72 (with parity or ECC) data lines, in contrast to SIMM c 32 lines.

Structurally is a memory module in the form of a long rectangular board with a row of pads on both sides along its long side, installed in the connector and fixed at both ends of her snaps. The memory chips can be placed either on one or both sides of the board.

Unlike the SIMM form factor used for asynchronous FPM and EDO memory, the DIMM form factor is designed for SDRAM type memory. Modules designed for 3.3V and (less frequently) 5V supply voltages were produced. However, for the first time in the form factor DIMM appeared modules with memory type FPM, and then and EDO. They were equipped with servers and branded computers.

SO-DIMM module is designed for use in notebooks or as on-board memory expansion, so it has a smaller size.

Later in the DIMM modules was packed memory type DDR, DDR2, DDR3 and DDR4, distinguished by its high-speed performance.

Appearance of DIMM form factor was promoted by the appearance of Pentium processor, which had a 64-bit data bus. In professional workstations, such as SPARCstation, this type of memory has been used since the early 1990s. In general purpose computers, a widespread switch to this type of memory occurred in the late 1990s, around the time of the Pentium II processor.

In the DIMM form factor, memory arrays that implement non-volatile storage, called NVDIMM, can be made. They can be implemented by adding a self-contained power supply and auto-updating functions to DRAM memory (NVDIMM-N) or based on NAND flash memory (NVDIMM-F). Implementations of NVDIMM based on other types of memory (NVDIMM-P) are investigated

There are the following types of DIMM, structurally and electrically incompatible with each other, including SO-DIMM (from small outline, compact modules, used in particular in laptops):

72-pin SO-DIMM (not compatible with 72-pin SIMM) - used for FPM DRAM and EDO DRAM

100-pin DIMM - used for SDRAM

144-pin SO-DIMM - used for SDR SDRAM (sometimes also for EDO RAM) in laptop computers

168-pin DIMM - used for SDR SDRAM (less often for FPM/EDO DRAM in workstations/servers)

172-pin MicroDIMM - used for DDR SDRAM

184-pin DIMM - used for DDR SDRAM

200-pin SO-DIMM - used for DDR SDRAM and DDR2 SDRAM

204-pin SO-DIMM - used for DDR3 SDRAM

214-pin MicroDIMM - used for DDR2 SDRAM and DDR3 SDRAM

240-pin DIMM - used for DDR2 SDRAM, DDR3 SDRAM and FB-DIMM DRAM

260-pin SO-DIMM - used for DDR4 SDRAM

288-pin DIMM - used for DDR4 SDRAM

SIMM (Single in-line memory module) - the name of memory modules with a single row of contacts, widely used in computer systems in the 1990s. SIMM standards are described in JEDEC JESD-21C. They had several modifications.

Most early IBM PC-compatible computer motherboards used DRAM chips packaged in DIP cases and mounted in sockets. However, systems with 80286 processors used more memory, and to save motherboard space and simplify the upgrade process, individual chips were combined into modules. Some systems used SIPP modules, but they proved too easy to break during installation.

SIMM modules were developed and patented in 1983 by Wang Laboratories. Originally the modules were ceramic and had pins.

Early SIMMs were installed in slots that had no locking mechanisms, but fairly quickly ZIF slots with latches became common.

The first to appear were 30-pin modules with a capacity of 64kbytes to 16Mbytes and an eight-bit data bus, supplemented (sometimes) by a ninth memory parity line. They were used in computers with Intel 8088, 286, 386 CPUs. Modules were used on motherboards with 8088 processors one by one, on 286 and 386SX ones in pairs, on 386DX four modules of equal capacity.

With the spread of mass-produced computers in the Intel 80486 processors and similar, for which 30-pin modules had to be put at least four, 30-pin SIMM modules were superseded by 72-pin SIMM modules. 72-pin modules consisted essentially of four 30-pin modules with common address lines and separate data lines, were 32-bit, had a capacity of 1 Mbyte to 64 Mbytes. In the era of 486 processors, 72-pin modules were used on brand-name PCs (Compaq, HP, Acer and others), and with the transition to Pentium processors - on almost all motherboards from all manufacturers.

Since motherboards for Pentium processors with a 64-bit data bus needed to put 72-pin modules in pairs, gradually the modules were physically paired "together": they began to place the chips on both sides of the printed circuit board memory module. As a result, the first DIMM modules appeared.

There were also 64-pin modules (used, for example, in Macintosh IIfx computers) and 68-pin modules (for example, VRAM in Macintosh LC).