Time required to perform one SH256: Ethereum Scaling
Ethereum, as one of the most widely accepted blockchain platforms, has become an essential component of the global digital economy. However, its scaling and productivity were discussions between creators and researchers. One aspect that causes curiosity is how long it takes to perform one bag of SHA256 on high -minded computers.
In this article, we will delve into the world of encryption and investigate who is involved in the Mags Sha256, today the most advanced computing hardware: integrated program integrated circuits (ASICS).
What is Sha256?
SHA256 is a cryptographic bag feature designed to obtain any size input data and create a fixed size output. It is usually used for a variety of purposes such as digital signatures, messaging and data integrity. In the context of Ethereum, bags are used to verify the authenticity and uniqueness of the transactions, intellectual contracts and other intellectual actions.
How long does it take to run Sha256?
The time required to perform one Sha256 depends on several factors:
- bag size : The higher the input data, the greater the bag operation.
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- GPU performance : The upper graphic processing devices (GPU) are designed for parallel processing and certain scenarios can significantly exceed the processor.
Ethereum’s minimum block time is 15 seconds, which means that the entire proof process (POW) takes about 14 minutes on average. However, this time may vary depending on the network overload and the calculation energy available.
Asics faster: closer to gaze
Let’s look at some of the fastest Asic today in production:
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- Bitmain B3 : The European main car supports up to 32,000 MHP/s in the European company and has an impressive 1.5 GHz clock speed.
- Anthemos A10 : This ASIC, built in Chinese, is for high -performance mining operations and resources up to 25,000 mH/s.
Comparison Time: Sha256 in this ASICS
To provide an approximate idea of the processing power, let’s compare execution time with one bag of SHA256:
| Asic | Clock speed (GHz) |
| — | — |
| Sapphire Cryptominer S19 Pro | 1.5 GHz |
| Bitmain B3 | 1.0 GHz |
| Anthema A10 | 2.8 GHz |
Using the following values, we can calculate the estimated time of one bag sha256:
| Asic | Clock speed (GHz) | Estimated time (seconds)
| — | — | — |
| Sapphire Cryptominer S19 Pro | 1.5 GHz | 300 seconds (~ 4 minutes 30 seconds) |
| Bitmain B3 | 1.0 GHz | 150 seconds (~ 2 minutes 30 seconds) |
| Anthemos A10 | 2.8 GHz | 50 seconds (~ 45 seconds)
Conclusion
As you can see, the time you need to make one bag of SHA256 fast ASIC, such as the Sapphire Cryptominer S19 Pro and Bitmain B3, is significantly shorter than the average block time required for Ethereum extraction.
Although these results show an impressive processing power available in modern calculation hardware, there are still opportunities to improve. Researchers continue to develop new architecture and refine existing ones, and we can expect an even faster execution of Hash Sha256 operations.
Future prospects
The integration of more powerful asic into the Ethereum network will undoubtedly speed up the Blockchain platform. This can be achieved by various means such as:
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