Why Signature Aggregation is the Unsung Hero of Mass Adoption

A single user transaction from a smart account like Safe{Wallet} or Biconomy can require 5-10+ signatures for multi-sig or session keys. Onchain, each ECDSA signature verification costs ~3k gas. At scale, this overhead makes AA economically non-viable.\n- Cost Multiplier: A simple swap could cost 5x more in pure signature overhead.\n- Block Space Bloat: User operations would consume >30% of a block just for signature data.

Aggregation schemes like BLS signatures (used by EigenLayer, zkSync) and Schnorr signatures allow thousands of signatures to be compressed into a single, constant-sized proof. This is the first-principles breakthrough that makes AA at scale possible.\n- Constant Cost: Verify 1,000 users for the cost of verifying 1.\n- Native Rollup Fit: Aggregated proofs align perfectly with ZK-Rollup and Optimistic Rollup batch verification.

Bundlers (like Pimlico, Stackup) must aggregate user operations profitably. Without efficient aggregation, their margins evaporate. This creates a centralization pressure point—the few bundlers who can afford custom hardware (ASICs/FPGAs) for fast BLS aggregation become gatekeepers.\n- Hardware Advantage: Specialized hardware can aggregate signatures ~100x faster than general-purpose servers.\n- Relayer Risk: Echoes the MEV-Boost relay centralization problem, but for user access.

Protocols like UniswapX, CowSwap, and Across solve aggregation at the application layer. They batch user intents off-chain, settling net flows on-chain. This reduces the required on-chain signature count to near zero for matched orders.\n- Off-Chain Matching: >90% of trades can settle without a user's on-chain signature.\n- Cross-Chain Synergy: Becomes the killer app for intents + bridges like LayerZero and Axelar.

Ethereum's stateless future via Verkle Trees depends on witness compression. Aggregated signatures are a precursor, proving that the network can handle cryptographic proofs of massive state changes. This isn't just about AA—it's about scaling the base layer itself.\n- Witness Size: Aggregated proofs keep stateless client witnesses below ~1 MB.\n- Synergy: AA aggregation paves the way for EIP-7702 and native batchable operations.

StarkNet (with its native account abstraction) and zkSync Era have signature aggregation baked into their DNA. They use STARKs and BLS to validate all transactions in a batch with a single proof. This is the canonical model for how L2s will absorb the AA complexity.\n- Native Feature: No extra gas cost for multi-sig or social recovery.\n- VC Lesson: Investors in StarkWare and Matter Labs bet on this cryptographic primitive early.

Every validator signature on a proof-of-stake chain like Ethereum is ~65 bytes. For a 1,000-validator committee, that's 65KB of pure overhead per block, consuming gas and limiting throughput.

• Direct Cost: Signature verification is ~20% of block execution time.
• Network Cost: Larger blocks propagate slower, increasing reorg risk.
• User Cost: High gas fees for simple operations like bridge attestations.

Boneh–Lynn–Shacham (BLS) signatures allow thousands of signatures to be mathematically combined into a single, constant-sized (~48 byte) proof.

• Constant Size: Aggregate of 1 or 1,000 signatures is the same size.
• Native Security: Inherits security from the underlying elliptic curve pairing.
• Foundation Tech: Enables Ethereum's danksharding, Celestia's data availability sampling, and secure light clients.

EigenLayer doesn't just aggregate signatures; it aggregates cryptoeconomic security. Restakers delegate stake to operators who run AVSs like EigenDA.

• Pooled Security: $15B+ TVL secures multiple services simultaneously.
• Cost Efficiency: Data availability at ~$0.10 per MB, vs. Ethereum's ~$1,000.
• Intent-Centric: Enables low-cost, high-throughput infra for rollups like Arbitrum Orbit and Optimism Stack chains.

Signature aggregation is the silent engine for cross-chain interoperability and scalable execution.

• LayerZero: Uses decentralized oracle/relayer sets with aggregated attestations.
• zkSync & Scroll: Leverage BLS aggregation in their proof systems for efficient L1 verification.
• Across & Wormhole: Secure optimistic and generic message passing by aggregating guardian signatures.

Today's rollup sequencers (e.g., Arbitrum, Optimism, Base) are permissioned and centralized. They are the single point of failure for transaction ordering and MEV extraction.

• Censorship Risk: Sequencer can reorder or censor transactions.
• MEV Capture: Value accrues to a single entity, not the protocol or users.
• Liveness Risk: A single sequencer going offline halts the chain.

The endgame is decentralized, shared sequencer networks that aggregate block production across multiple rollups.

• Espresso Systems & Astria: Provide neutral, shared sequencing layers.
• SUAVE: Aims to decentralize MEV supply chain with preference aggregation.
• Result: Cross-rollup atomic composability, fair MEV redistribution, and robust censorship resistance.