What is Softwar about?

Softwar is a groundbreaking book by Major Jason Lowery that positions Bitcoin as a revolutionary national security technology. It reveals Bitcoin's true purpose: not merely digital currency, but a defense technology that projects physical power into cyberspace through proof-of-work.

Major Jason Paul Lowery is a U.S. Space Force Astronautical Engineer with 28 years of military service. He currently serves as an MIT National Defense Fellow, advising senior U.S. military leaders about Bitcoin's national strategic implications. He holds an MS from MIT and a BS from Baylor University.

Why was Softwar restricted by military authorities?

The book was ordered removed from distribution by military authorities, likely due to its strategic insights about Bitcoin's role in national defense. Despite restriction attempts, it's now available through civilian channels and has sold over 50,000 copies.

What is the electro-cyber dome concept?

The electro-cyber dome is Lowery's concept describing how Bitcoin's proof-of-work creates an unprecedented defensive shield protecting digital infrastructure. It converts electrical energy into unbreakable digital security, similar to how physical walls protect physical territory.

Where can I buy Softwar?

Softwar is available on Amazon in paperback, Kindle digital, and Audible audiobook formats. The book has 365 pages and is ISBN 9798371524188.

How Does Bitcoin Mining Work? Complete Beginner's Guide

Quick Answer

Bitcoin mining is the process of validating transactions and adding them to the blockchain by solving complex mathematical puzzles. Miners compete using specialized hardware to find valid “hashes” through proof-of-work, earning newly created Bitcoin and transaction fees as rewards. This process secures the network without requiring any central authority.

What is Bitcoin Mining?

Bitcoin mining serves three critical functions:

Transaction Validation: Verifying that Bitcoin transactions are legitimate
Blockchain Security: Making it computationally expensive to attack the network
Currency Issuance: Distributing new Bitcoin into circulation on a predictable schedule

Think of mining as a global, decentralized lottery where:

Everyone can participate with computational power
Winners are mathematically determined (no favoritism)
Prizes (block rewards) incentivize honest behavior
Security increases as more participants compete

Unlike traditional mining that extracts physical resources, Bitcoin mining creates digital scarcity through energy expenditure—converting electricity into unforgeable proof-of-work.

The Mining Process Step-by-Step

1. Transaction Collection

Mempool Gathering:

Miners collect unconfirmed transactions from the network’s “mempool” (memory pool)
Transactions include sender, receiver, amount, and digital signatures
Miners prioritize transactions offering higher fees
Typical block contains 2,000-3,000 transactions

Validation Checks:

Verify digital signatures are valid
Confirm sender has sufficient balance
Ensure transaction follows Bitcoin protocol rules
Reject invalid or double-spend attempts

2. Block Construction

Building the Candidate Block:

Block Header: Contains previous block hash, timestamp, difficulty target, nonce
Transaction List: Selected transactions (up to ~4 MB data)
Coinbase Transaction: Miner’s reward (currently 3.125 BTC + fees)
Merkle Root: Cryptographic summary of all transactions

Why Block Structure Matters: The header connects each block to previous blocks, creating an unbreakable chain—hence “blockchain.”

3. Hash Computation (Proof-of-Work)

The Mining Race:

Take block header data
Add random number called “nonce” (number used once)
Calculate SHA-256 hash of combined data
Check if hash meets difficulty target (starts with specific number of zeros)

Example:

Block Data + Nonce = Hash
If hash < target difficulty → Valid block found! ✅
If hash > target difficulty → Try different nonce, repeat ❌

Hash Rate Matters: Modern miners calculate 100+ trillion hashes per second (TH/s) searching for valid solutions.

4. Difficulty Target

Automatic Adjustment:

Bitcoin adjusts difficulty every 2,016 blocks (~2 weeks)
Goal: Maintain average 10-minute block time
More hash rate joins → difficulty increases
Hash rate leaves → difficulty decreases

Current Scale: Global network operates at 500+ exahashes per second (EH/s)—that’s 500 quintillion calculations every second.

5. Block Broadcasting

When Miner Finds Valid Hash:

Broadcast: Send block to all network nodes
Verification: Other nodes validate the block independently
Acceptance: Valid blocks added to blockchain
Reward: Miner receives 3.125 BTC + transaction fees (~$150,000+ at current prices)
Next Round: All miners start working on new block

Orphan Blocks: Occasionally two miners find valid blocks simultaneously. The network follows the longest chain, orphaning the other block.

Mining Hardware Evolution

CPU Mining (2009-2010)

Early Days:

Bitcoin founder Satoshi Nakamoto mined using regular computers
Hash rate: ~5-10 megahashes per second (MH/s)
Energy consumption: Minimal
Status: Completely obsolete for Bitcoin

GPU Mining (2010-2013)

Graphics Card Era:

Gamers discovered GPUs were faster than CPUs
Hash rate: ~500-1,000 MH/s
Energy efficiency: 10x better than CPUs
Status: Moved to other cryptocurrencies (Ethereum before proof-of-stake)

ASIC Mining (2013-Present)

Application-Specific Integrated Circuits:

Purpose-built chips only for Bitcoin mining
Hash rate: 100-150 terahashes per second (TH/s)
100,000x faster than GPUs
Energy efficiency: Measured in joules per terahash (J/TH)
Status: Only competitive option for Bitcoin mining

Modern Flagship Models (2025):

Bitmain Antminer S21: 200 TH/s, 3,500W power consumption
MicroBT WhatsMiner M60: 180 TH/s, 3,300W
Canaan Avalon A1466: 150 TH/s, 3,400W

Mining Economics

Revenue Calculation

Mining Income Formula:

Daily Revenue = (Your Hash Rate / Global Hash Rate) × Daily Bitcoin Issued × Bitcoin Price

Example (2025):

Your hash rate: 200 TH/s (1 Antminer S21)
Global hash rate: 500 EH/s (500,000,000 TH/s)
Your share: 0.00004% of network
Daily Bitcoin issued: ~900 BTC
Your expected daily BTC: ~~0.00036 BTC (~~$18-25)

Cost Calculation

Operating Expenses:

Electricity: Largest ongoing cost (70-80% of total)
Hardware: Upfront capital ($2,000-5,000 per ASIC)
Cooling: Required for industrial operations
Maintenance: Replacement parts, labor

Profitability:

Profit = Revenue - (Electricity + Hardware Depreciation + Operational Costs)

Key Variable: Electricity price

Profitable: <$0.05/kWh
Marginal: $0.05-0.08/kWh
Unprofitable: >$0.10/kWh

Learn more about mining economics and energy costs.

Mining Pools vs. Solo Mining

Solo Mining

Independent Operation:

Keep 100% of block rewards (if you win)
Problem: With 200 TH/s, you’d mine 1 block every ~6-8 years on average
High variance, unpredictable income
Only viable for large operations (>1% network share)

Mining Pools

Collaborative Mining:

Combine hash rate with thousands of miners
Share rewards proportionally to contributed hash rate
Receive small, predictable payments daily/weekly
Pool operator takes 1-3% fee

Major Pools (2025):

Foundry USA: ~35% of global hash rate
AntPool: ~15%
F2Pool: ~12%
ViaBTC: ~8%

Source: Blockchain.com Mining Pool Stats

Why Mining Matters for Bitcoin Security

Economic Defense Mechanism

51% Attack Prevention:

Attacker needs >50% of global hash rate to manipulate blockchain
At 500 EH/s network strength:
- Hardware cost: $20-30 billion
- Daily electricity: $40+ million
- Result: Economically impossible to attack

Decentralization Through Competition

No Single Point of Failure:

Thousands of independent miners globally
Geographic distribution across 100+ countries
No central authority controls mining
Proof-of-work ensures democratic consensus

Environmental Considerations

Energy Consumption Reality

Bitcoin’s Energy Use:

Estimated: 150-200 TWh annually (~0.5% of global electricity)
Comparable to: Argentina or Netherlands
Growing share from renewables: 50-60%

Counter-Narrative: Bitcoin mining actually incentivizes renewable energy development by monetizing stranded energy sources and providing grid stabilization services.

Learn more: Is Bitcoin Proof-of-Work Wasteful?

Getting Started with Mining

Individual Mining (2025 Reality)

Not Recommended Unless:

Access to electricity <$0.05/kWh
Capital for equipment ($10,000+ minimum viable operation)
Technical expertise for setup and maintenance
Long-term investment horizon (12-24 months ROI)

Alternative: Buy Bitcoin directly instead of mining (usually more cost-effective)

Industrial Mining

Requirements:

Megawatts of power capacity
Industrial facility with cooling infrastructure
Thousands of ASIC miners
Dedicated team for operations
Strategic location with cheap energy

See: Mining Infrastructure and National Power

Conclusion

Bitcoin mining is the decentralized consensus mechanism that secures the world’s first truly digital money without requiring trust in any central authority. By converting energy into unforgeable mathematical proof, miners create cyber-physical security that makes Bitcoin uniquely resistant to attack.

The mining process—validating transactions, computing proof-of-work hashes, and broadcasting blocks—forms the foundation of Bitcoin’s $1+ trillion security model. As hash rate continues growing, the network becomes progressively more secure, demonstrating the power of thermodynamic consensus in digital space.

For deeper understanding of Bitcoin’s security model, explore Understanding Bitcoin’s Proof-of-Work Defense Mechanism.

References

Technical Resources

Nakamoto, S. (2008). Bitcoin: A Peer-to-Peer Electronic Cash System. Bitcoin.org.
Antonopoulos, A. M. (2017). Mastering Bitcoin: Programming the Open Blockchain. O’Reilly Media.

Data Sources

Blockchain.com. (2025). Bitcoin Mining Pool Distribution.
Cambridge Centre for Alternative Finance. (2024). Bitcoin Mining Map. University of Cambridge.

Knowledge Graph Entities

Bitcoin mining | Proof-of-work | Hash function | Blockchain | Cryptocurrency