| name | lp-math |
| description | AMM liquidity provision mathematics including constant-product, concentrated liquidity, price impact, and LP share calculations |
LP Math — AMM Liquidity Provision Mathematics
Automated Market Makers (AMMs) replace traditional orderbooks with liquidity pools. Instead of matching buyers and sellers, a mathematical formula determines prices based on reserve ratios. Liquidity providers (LPs) deposit both assets into a pool and earn fees from every trade.
Understanding the math behind AMMs is essential for:
- Evaluating whether providing liquidity is profitable after impermanent loss
- Estimating price impact before executing large trades
- Comparing capital efficiency across pool types (constant product vs concentrated)
- Calculating expected fee revenue for a given pool position
Related skills: See impermanent-loss for IL calculations, yield-analysis for LP yield modeling, liquidity-analysis for pool depth assessment.
1. Constant Product AMM (xy = k)
The foundational AMM model used by Raydium V4 and most Solana DEXes.
Core Invariant
x * y = k
Where:
x = reserve amount of token X (e.g., SOL)y = reserve amount of token Y (e.g., USDC)k = constant product (increases over time from fees)
Spot Price
P = x / y (price of Y in terms of X)
P = y / x (price of X in terms of Y)
For a pool with 100 SOL and 10,000 USDC: price of SOL = 10,000 / 100 = 100 USDC.
Trade Execution
When a trader swaps Δx of token X into the pool:
delta_y = y * delta_x / (x + delta_x)
delta_y_after_fee = delta_y * (1 - fee_rate)
x_new = x + delta_x
y_new = y - delta_y_after_fee
The key insight: larger trades get worse prices because each unit moves the ratio further.
Inverse Calculation
To get a specific output amount Δy, the required input is:
delta_x = x * delta_y / (y - delta_y)
Price After Trade
price_new = y_new / x_new
Worked Example
Pool: 100 SOL / 10,000 USDC (k = 1,000,000), fee = 0.3%
Buy 5 SOL worth of USDC:
- Gross output:
10,000 * 5 / (100 + 5) = 476.19 USDC
- Fee:
476.19 * 0.003 = 1.43 USDC
- Net output:
474.76 USDC
- Effective price:
474.76 / 5 = 94.95 USDC/SOL (vs spot 100)
- Price impact:
(100 - 94.95) / 100 = 5.05%
- New reserves: 105 SOL / 9,525.24 USDC
- New k:
105 * 9,525.24 = 1,000,150.2 (k increased from fees)
See references/amm_formulas.md for complete derivations.
2. Concentrated Liquidity (CLMM)
Used by Orca Whirlpool, Raydium CLMM, and Meteora DLMM. Liquidity is only active within a chosen price range [P_lower, P_upper].
Key Concepts
L = sqrt(x * y) # Liquidity within the active range
price_at_tick = 1.0001^tick # Tick-to-price conversion
Capital Efficiency
Concentrating liquidity in a narrow range provides more depth per dollar:
efficiency = sqrt(P_upper / P_lower) / (sqrt(P_upper / P_lower) - 1)
P_lower, P_upper = 95, 105
efficiency = sqrt(105/95) / (sqrt(105/95) - 1)
A ±5% range is ~20x more capital-efficient than full-range, but the position goes 100% into one asset if price moves outside the range.
Position Value
For a CLMM position with liquidity L in range [P_lower, P_upper] at current price P:
if P <= P_lower:
value_x = L * (1/sqrt(P_lower) - 1/sqrt(P_upper))
value_y = 0
elif P >= P_upper:
value_x = 0
value_y = L * (sqrt(P_upper) - sqrt(P_lower))
else:
value_x = L * (1/sqrt(P) - 1/sqrt(P_upper))
value_y = L * (sqrt(P) - sqrt(P_lower))
Range Strategy Comparison
| Range | Efficiency | IL Risk | Fee Capture | Best For |
|---|
| ±2% | ~50x | Very high | High if in range | Stablecoins, tight pegs |
| ±5% | ~20x | High | Good for trending | Active management |
| ±25% | ~4x | Moderate | Consistent | Semi-passive |
| ±100% | ~2x | Low | Lower per $ | Passive, volatile pairs |
| Full range | 1x | Baseline | Always earning | Set and forget |
See references/amm_formulas.md for full CLMM derivations.
3. Price Impact
Constant Product Impact
price_impact = delta_x / (x + delta_x)
pool_fraction = trade_value / pool_tvl
Multi-Hop Impact
For a route through multiple pools, compound the impacts:
def multi_hop_impact(hops: list[dict]) -> float:
"""Calculate total price impact across route legs.
Args:
hops: List of {reserve_in, trade_amount} for each leg.
Returns:
Total price impact as a fraction.
"""
remaining = 1.0
for hop in hops:
leg_impact = hop["trade_amount"] / (hop["reserve_in"] + hop["trade_amount"])
remaining *= (1 - leg_impact)
return 1 - remaining
Impact Thresholds
| Impact | Assessment | Action |
|---|
| < 0.1% | Negligible | Proceed normally |
| 0.1–0.5% | Low | Acceptable for most trades |
| 0.5–2% | Moderate | Consider splitting across pools |
| 2–5% | High | Split trade, use TWAP |
| > 5% | Severe | Reduce size or find deeper pools |
4. LP Share Calculations
Initial Deposit (Empty Pool)
shares = sqrt(x_deposited * y_deposited)
The first depositor sets the ratio and receives shares equal to the geometric mean.
Subsequent Deposits
shares_minted = min(
x_added / x_reserve,
y_added / y_reserve
) * total_shares
Deposits must be proportional to the current reserve ratio. Any excess of one token is not used (or returned, depending on implementation).
Withdrawal
x_out = (shares_burned / total_shares) * x_reserve
y_out = (shares_burned / total_shares) * y_reserve
You always receive both tokens in the current ratio.
Share Value
share_value = pool_tvl / total_shares
your_value = your_shares * share_value
5. Fee Accrual
Fees accumulate inside the pool, increasing k:
daily_volume = 500_000
fee_rate = 0.003
daily_fees = daily_volume * fee_rate
tvl = 2_000_000
fee_apr = (daily_fees * 365) / tvl
For CLMM positions, fee earnings depend on:
- Whether price stays within your range (out-of-range = no fees)
- Your share of active liquidity in that range
- Total volume routed through the pool
your_liquidity = 50_000
total_liquidity = 1_000_000
your_share = your_liquidity / total_liquidity
your_daily_fees = daily_fees * your_share
6. Solana Pool Types
Raydium V4 (Constant Product)
- Model: Standard xy = k
- Fee: 0.25% (0.22% to LP, 0.03% to RAY buyback)
- Best for: New token launches, volatile pairs
- Note: Integrated with OpenBook for limit order flow
Orca Whirlpool (Concentrated Liquidity)
- Model: Concentrated liquidity with tick spacing
- Fee tiers: 0.01%, 0.05%, 0.3%, 1%
- Position: Represented as NFT (each position is unique)
- Best for: Major pairs (SOL/USDC), stablecoin pairs
Raydium CLMM
- Model: Concentrated liquidity (similar to Uniswap V3)
- Tick spacing: 1, 10, 60, 200
- Fee tiers: 0.01%, 0.05%, 0.25%, 1%
- Best for: Pairs with predictable ranges
Meteora DLMM (Dynamic Liquidity Market Maker)
- Model: Discrete bins instead of continuous ticks
- Strategies: Spot (uniform), Curve (concentrated), Bid-Ask (around current price)
- Fees: Dynamic, adjusting based on volatility
- Best for: Active LPs who rebalance frequently
See references/pool_mechanics.md for detailed mechanics and comparison.
7. Practical Decision Framework
Should You LP?
1. Calculate expected fee APR
2. Estimate impermanent loss for expected price movement
3. Net return = fee APR - IL
4. Compare to simply holding the assets
Which Pool Type?
Stablecoin pair → CLMM with tight range (±0.5%)
Major pair (SOL/USDC) → CLMM with moderate range (±10-25%)
New/volatile token → Constant product (full range)
Active management → Meteora DLMM with dynamic rebalancing
Position Sizing for LP
max_lp_allocation = portfolio_value * 0.20
volatility_adjustment = 1 - (annualized_vol / 2)
adjusted_allocation = max_lp_allocation * max(0.1, volatility_adjustment)
Files
References
references/amm_formulas.md — Complete mathematical derivations for constant product and concentrated liquidity AMMsreferences/pool_mechanics.md — Solana-specific pool mechanics for Raydium, Orca, and Meteora
Scripts
scripts/amm_calculator.py — Constant product AMM calculator with trade simulation, LP shares, and fee accrualscripts/clmm_calculator.py — Concentrated liquidity calculator with position valuation, capital efficiency, and range comparison
Quick Reference
| Formula | Expression |
|---|
| Constant product | x * y = k |
| Spot price | P = y / x |
| Trade output | Δy = y * Δx / (x + Δx) |
| Required input | Δx = x * Δy / (y - Δy) |
| Price impact | Δx / (x + Δx) |
| Initial LP shares | sqrt(x * y) |
| Subsequent shares | min(Δx/x, Δy/y) * total |
| Fee APR | (daily_fees * 365) / TVL |
| CLMM efficiency | sqrt(P_u/P_l) / (sqrt(P_u/P_l) - 1) |
| Tick to price | 1.0001^tick |
