whitepaper updates
This commit is contained in:
tim
@@ -1,551 +1,170 @@
|
||||
# LMSR-based Multi-Asset AMM
|
||||
|
||||
Abstract
|
||||
We propose a multi-asset automated market maker (AMM) whose pricing kernel is the Logarithmic Market Scoring Rule (LMSR) (Hanson, 2002.) The AMM maintains a convex potential $C(\mathbf{q}) = b(\mathbf{q}) \log\!\big(\sum_i e^{q_i / b(\mathbf{q})}\big)$ over normalized inventories $\mathbf{q}$ and sets the effective liquidity parameter proportional to pool size, $b(\mathbf{q}) = \kappa \, S(\mathbf{q})$ with $S(\mathbf{q}) = \sum_i q_i$ and fixed $\kappa>0$. This choice preserves scale-invariant responsiveness while retaining LMSR’s softmax pricing structure under a quasi-static-$b$ view. We derive closed-form expressions for asset-to-asset swaps in the induced two-asset subspace, including exact-in, exact-out, limit-hitting (swap-to-limit), and capped-output variants. We discuss numerical stability techniques (e.g., log-sum-exp reformulations, guarded domains) and a balanced two-asset specialization that enables polynomial approximations with provable error bounds. The protocol is parameter-fixed at deployment (no governance over $\kappa$ or fees), yielding reproducible behavior and transparent depth calibration. Analytical and numerical evidence suggest that this LMSR AMM combines desirable theoretical properties (convexity, path-independent cost differences at constant $b$, multi-asset support) with practical robustness (monotonicity preservation and conservative fallbacks). We outline liquidity operations (proportional and single-asset joins/exits), fee accrual to LPs via state appreciation, and risk considerations.
|
||||
|
||||
Keywords
|
||||
AMM; LMSR; cost-function market maker; multi-asset liquidity; bounded loss; convex optimization; fixed-point arithmetic; numerical stability.
|
||||
|
||||
2) Executive Summary
|
||||
|
||||
Motivation and problem
|
||||
- Multi-asset liquidity often faces a trade-off between simplicity (CFMM invariants) and expressivity (risk sharing across many assets). We pursue an AMM that natively supports many assets while delivering predictable depth and strong theoretical guarantees.
|
||||
|
||||
Mechanism overview
|
||||
- The AMM’s kernel is the LMSR cost function
|
||||
$$C(\mathbf{q}) = b(\mathbf{q}) \log\!\left(\sum_i e^{q_i / b(\mathbf{q})}\right),\qquad b(\mathbf{q})=\kappa\,S(\mathbf{q}),\;\; S(\mathbf{q})=\sum_i q_i.$$
|
||||
- Instantaneous marginal price ratios follow the softmax structure under quasi-static $b$:
|
||||
$$P(\text{base}\to\text{quote}\mid \mathbf{q})=\exp\!\left(\frac{q_{\text{quote}}-q_{\text{base}}}{b(\mathbf{q})}\right).$$
|
||||
|
||||
Key properties
|
||||
- Convex potential and softmax gradient (at constant $b$), multi-asset support via a single potential.
|
||||
- Path independence of cost differences under constant $b$; pairwise price ratios preserved under $b=\kappa S$ via a common additive gradient term.
|
||||
- Bounded-loss intuition from LMSR extends proportionally with $b$; scale invariance via $b=\kappa S$.
|
||||
- Closed forms for two-asset reductions enable exact-in/exact-out and limit-hitting swaps with monotonicity.
|
||||
|
||||
Main contributions
|
||||
- Fixed-parameter LMSR AMM: $b=\kappa S$ with immutable $\kappa$ and fees post-deployment.
|
||||
- Stability techniques: log-sum-exp evaluation, domain guards, ratio shortcuts, and conservative fallbacks.
|
||||
- Balanced two-asset optimization: polynomial approximations with error bounds and dispatcher preconditions.
|
||||
- Evaluation plan: analytical depth comparisons, numerical accuracy, monotonicity/no-negative-arbitrage checks, and gas microbenchmarks.
|
||||
|
||||
3) Background and Related Work
|
||||
|
||||
AMM landscape
|
||||
- CFMMs define implicit invariants over reserves. Examples include:
|
||||
- Constant product (e.g., Uniswap): $x y = k$, offering simple two-asset liquidity and predictable slippage profiles.
|
||||
- Constant mean (e.g., Balancer): $\prod_i q_i^{w_i} = \text{const}$, generalizing to many assets with weights.
|
||||
- Stableswap (e.g., Curve): combines constant sum and constant product to target low-slippage near parity.
|
||||
- LMSR differs by specifying a convex cost function $C(\mathbf{q})$; prices are given by its gradient (or ratios thereof), rather than from a multiplicative invariant.
|
||||
|
||||
LMSR primer and adaptation to AMMs
|
||||
- The classical LMSR potential with constant $b$ is
|
||||
$$C(\mathbf{q}) = b \log\!\left(\sum_i e^{q_i/b}\right),\qquad \frac{\partial C}{\partial q_i} = \frac{e^{q_i/b}}{\sum_k e^{q_k/b}}.$$
|
||||
- In our AMM setting, we parameterize $b(\mathbf{q})=\kappa S(\mathbf{q})$ for scale-invariant responsiveness, and use a quasi-static-$b$ view to compute instantaneous price ratios:
|
||||
$$P(\text{base}\to\text{quote})=\frac{e^{q_{\text{quote}}/b}}{e^{q_{\text{base}}/b}}=\exp\!\left(\frac{q_{\text{quote}}-q_{\text{base}}}{b}\right).$$
|
||||
- Two-asset reduction yields closed forms for exact-in and exact-out trades (see Sections 5–6 and Appendix A).
|
||||
|
||||
Related LMSR applications and prior DeFi adaptations
|
||||
- LMSR originates from scoring-rule-based market making in information markets. Subsequent adaptations explored cost-function AMMs and variants that tailor $b$ to achieve targeted responsiveness. We adopt a proportional $b$ tied to total pool size for transparency and predictable scaling across liquidity regimes.
|
||||
|
||||
When LMSR is preferable and limitations
|
||||
- Preferable when:
|
||||
- Multi-asset exposure and cross-asset risk sharing are primary goals.
|
||||
- A convex potential with softmax-driven pricing is desired for analytical tractability and monotonic behavior.
|
||||
- Limitations and design choices:
|
||||
- With $b=\kappa S$, gradient components include a common additive term; we rely on pairwise ratios for pricing.
|
||||
- Extreme imbalances can induce steep price moves; capacity caps and domain guards mitigate numerical and economic edge cases.
|
||||
|
||||
4) System Model and Notation
|
||||
|
||||
4.1 State, assets, and units
|
||||
- Assets and indices: We consider $n \ge 2$ assets indexed by $i \in \{0,\dots,n-1\}$.
|
||||
- State vector: $\mathbf{q} = (q_0,\dots,q_{n-1}) \in \mathbb{R}_{\ge 0}^{\,n}$ denotes normalized internal quantities held by the pool. Each $q_i$ is in common “internal units” so cross-asset operations are comparable. In practice, token amounts are scaled to a common unit (e.g., $10^{-\text{decimals}}$ normalization) and represented with fixed-point arithmetic; equations here are stated over reals for clarity.
|
||||
- Size metric: $S(\mathbf{q}) := \sum_i q_i$. This is the aggregate pool size used both to summarize liquidity and to set the effective liquidity parameter.
|
||||
- Liquidity parameterization: The effective LMSR liquidity parameter is $b(\mathbf{q}) := \kappa \cdot S(\mathbf{q})$, where $\kappa > 0$ is a fixed, deployment-time constant. Intuitively, $b$ scales linearly with the pool’s total size, preserving responsiveness under proportional rescaling of $\mathbf{q}$.
|
||||
- Fees: Let $f_{\text{swap}} \in [0,1)$ denote the swap fee applied at the token layer (separate from the fee-free pricing kernel). Optionally a protocol fee $f_{\text{proto}}$ can be taken as a fraction of the swap fee. All derivations of kernel prices below are fee-free; fees are applied as multiplicative factors to input/output amounts outside the kernel.
|
||||
|
||||
4.2 Cost function and prices
|
||||
- Cost function: We use the LMSR cost function
|
||||
$$C(\mathbf{q}) \;=\; b(\mathbf{q}) \,\log\!\left(\sum_{i} e^{\,q_i / b(\mathbf{q})}\right).$$
|
||||
For numerical stability we compute it via a log-sum-exp formulation. Define $y_i := q_i / b(\mathbf{q})$ and $M := \max_i y_i$; then
|
||||
$$C(\mathbf{q}) \;=\; b(\mathbf{q}) \left( M + \log \sum_{i} e^{\,y_i - M} \right).$$
|
||||
- Price shares (softmax): Define the unnormalized weights $w_i := e^{q_i / b(\mathbf{q})}$ and $W := \sum_i w_i$. The price share of asset $i$ is
|
||||
$$\pi_i(\mathbf{q}) := \frac{w_i}{W} \;=\; \frac{e^{q_i / b(\mathbf{q})}}{\sum_j e^{q_j / b(\mathbf{q})}}.$$
|
||||
Note: With $b$ constant, the gradient satisfies $\partial C/\partial q_i = \pi_i$. With $b = \kappa \, S(\mathbf{q})$, $\partial C/\partial q_i$ includes an additive term common across $i$; differences in marginal prices still track $\pi_i$ up to an additive constant, and the pairwise ratios below remain unchanged.
|
||||
- Pairwise marginal price ratio: The instantaneous marginal price of “base” in units of “quote” is
|
||||
$$P(\text{base}\to\text{quote}\mid \mathbf{q}) \;=\; \exp\!\left(\frac{q_{\text{quote}} - q_{\text{base}}}{b(\mathbf{q})}\right).$$
|
||||
This equals $w_{\text{quote}}/w_{\text{base}}$ and is invariant to the common softmax denominator, and remains valid under the quasi-static-$b$ swap model (holding $b$ constant over an infinitesimal trade or a single pricing step; see Appendix A).
|
||||
|
||||
4.3 Swap quantities and conventions
|
||||
- Exact-in: Given an input amount $a \ge 0$ of asset $i$, the fee-free kernel determines the output amount $y \ge 0$ of asset $j$ by integrating the marginal price along the $i\to j$ path with $b$ held quasi-static at its pre-trade value (see Appendix A).
|
||||
- Exact-out: Given a desired output $y \ge 0$ of asset $j$, the fee-free kernel solves for the required input $a \ge 0$ of asset $i$ (inverse of exact-in).
|
||||
- Price limits (swap-to-limit): A user can provide a maximum acceptable marginal price ratio $\Lambda > 0$ for $p_i/p_j$. If the marginal price trajectory would exceed $\Lambda$ before consuming the full $a$, the swap truncates at the unique $a_{\text{lim}}$ that reaches $\Lambda$ (see Appendix A).
|
||||
- Capacity caps: Outputs cannot exceed the available balance of the out-asset; if a formula would produce $y > q_j$, we cap to $q_j$ and solve inversely for the corresponding input.
|
||||
|
||||
4.4 Units, scaling, and normalization
|
||||
- Token decimals: For each token $i$ with decimals $d_i$, on-chain amounts are normalized to a common internal unit so that arithmetic over $\mathbf{q}$ is coherent. Let $s_i$ be the scale factor implied by $d_i$; normalized internal balances are proportional to on-chain token balances via $s_i$.
|
||||
- Scale invariance: If $\mathbf{q}$ is scaled by $\lambda > 0$ (all assets multiplied by the same $\lambda$), then $S$ scales by $\lambda$ and $b = \kappa S$ scales by $\lambda$; prices as pairwise ratios, $P(\text{base}\to\text{quote})$, are invariant to this rescaling.
|
||||
|
||||
4.5 Assumptions
|
||||
- Tokens are standard fungible assets with deterministic, non-rebasing balances; no transfer fees are embedded at the kernel level.
|
||||
- Swaps and liquidity operations are atomic; the mechanism is permissionless (subject to access rules at the wrapper layer).
|
||||
- No external price oracles are required by the kernel; price discovery is endogenous via the cost function.
|
||||
- Numerical computations are performed in fixed-point with explicit domain guards (see Appendix B).
|
||||
|
||||
5) AMM Design and LMSR Formulation
|
||||
|
||||
5.1 Convex potential and invariant view
|
||||
- We model the pool by the LMSR potential
|
||||
$$C(\mathbf{q}) \;=\; b(\mathbf{q}) \,\log\!\left(\sum_{i=0}^{n-1} e^{\,q_i / b(\mathbf{q})}\right), \qquad b(\mathbf{q}) = \kappa\,S(\mathbf{q}),\;\; S(\mathbf{q})=\sum_i q_i,$$
|
||||
which induces a softmax over coordinates of $\mathbf{q}$. For pricing, we operate under a quasi-static-$b$ view for an infinitesimal step, recovering the usual LMSR gradient structure (see Section 6 and Appendix A).
|
||||
- Intuition: $C$ is a convex potential in $\mathbf{q}$ when $b$ is treated as a constant parameter; gradient components are softmax probabilities. This convexity underpins path independence of cost differences and no-arbitrage properties in the constant-$b$ setting. With $b=\kappa S(\mathbf{q})$, the gradient picks up a common additive term across coordinates; pairwise price ratios, which drive swaps, remain governed by softmax differences (Appendix A).
|
||||
|
||||
5.2 Kappa parameterization: $b=\kappa \cdot S$
|
||||
- Rationale: Choosing $b$ proportional to pool size preserves responsiveness under proportional rescalings of inventory. If all $q_i$ are multiplied by $\lambda>0$, then $S$ and $b$ scale by $\lambda$, while price ratios
|
||||
$$P(\text{base}\to\text{quote}\mid \mathbf{q}) \;=\; \exp\!\left(\frac{q_{\text{quote}}-q_{\text{base}}}{b(\mathbf{q})}\right)$$
|
||||
remain invariant.
|
||||
- Responsiveness: Smaller $\kappa$ yields smaller $b$ for a given $S$, producing steeper price impact (more responsive market); larger $\kappa$ produces deeper liquidity and gentler impact.
|
||||
- Conformance: The induced prices coincide with the classic LMSR softmax ratios under quasi-static-$b$, ensuring consistency with LMSR’s scoring-rule interpretation for marginal moves.
|
||||
|
||||
5.3 Choice of $S$ and alternatives
|
||||
- Default choice: $S(\mathbf{q})=\sum_i q_i$ (the $\ell_1$ size metric) is transparent, easy to compute, and scale-consistent across assets in normalized units.
|
||||
- Alternatives:
|
||||
- Weighted sum: $S_w(\mathbf{q})=\sum_i w_i q_i$ for exogenous weights $w_i>0$; may bias depth across assets.
|
||||
- Quadratic norm: $S_2(\mathbf{q})=(\sum_i q_i^2)^{1/2}$; increases $b$ more when inventory is concentrated, potentially dampening extreme price moves.
|
||||
- Trade-offs: Simplicity, composability, and transparency argue for $S=\sum_i q_i$. Alternatives can tailor depth but complicate interpretation and comparability.
|
||||
|
||||
5.4 Fixed-parameter policy
|
||||
- The proportionality constant $\kappa$ and fee parameters are set at deployment and remain immutable. This yields reproducible behavior, eliminates governance risk, and allows users to evaluate depth and price impact ex-ante for a given $S$.
|
||||
|
||||
5.5 Bounded-loss and capital efficiency implications
|
||||
- Classical LMSR with constant $b$ admits a bounded-loss guarantee of $b\ln n$ in appropriate units. With $b=\kappa S(\mathbf{q})$, scale invariance implies an instantaneous bound per unit of $S$ that is proportional to $\kappa \ln n$; as liquidity scales, so does absolute depth and the notional bound.
|
||||
- Capital efficiency: For fixed $\kappa$, larger $S$ linearly increases price depth while preserving price ratios; for fixed $S$, tuning $\kappa$ linearly trades off depth versus responsiveness. The two-asset closed forms in Section 6 quantify this via $y(a)$ and its slope at the origin $y'(0)=\frac{r_0}{1+r_0}$.
|
||||
|
||||
6) Pricing and Swap Mechanics
|
||||
|
||||
6.1 Instantaneous pricing from the gradient
|
||||
- Define unnormalized weights $w_i = e^{q_i/b}$ and $W=\sum_k w_k$. Under quasi-static $b$,
|
||||
$$\pi_i(\mathbf{q})=\frac{\partial C}{\partial q_i}=\frac{w_i}{W},\qquad
|
||||
\frac{\pi_{\text{quote}}}{\pi_{\text{base}}}=\frac{w_{\text{quote}}}{w_{\text{base}}}=\exp\!\left(\frac{q_{\text{quote}}-q_{\text{base}}}{b}\right).$$
|
||||
We interpret $P(\text{base}\to\text{quote}) := \pi_{\text{quote}}/\pi_{\text{base}}$ as the instantaneous marginal price ratio.
|
||||
|
||||
6.2 Cost differences and asset-to-asset swaps
|
||||
- Conceptually, an asset-to-asset trade from $i$ to $j$ of sizes $(+a,-y)$ satisfies
|
||||
$$\Delta C \;=\; C(\mathbf{q} + a\,\mathbf{e}_i - y\,\mathbf{e}_j) - C(\mathbf{q}),$$
|
||||
and the two-asset reduction with quasi-static $b$ yields a closed-form relation between $a$ and $y$ (Appendix A):
|
||||
$$y(a) \;=\; b \,\ln\!\Big( 1 + r_0 \,\big(1 - e^{-a/b}\big) \Big),\qquad r_0 := \exp\!\left(\frac{q_i - q_j}{b}\right).$$
|
||||
- The inverse exact-out mapping for a target $y$ is
|
||||
$$a(y) \;=\; b \,\ln\!\left(\frac{r_0}{\,r_0 + 1 - e^{\,y/b}\,}\right).$$
|
||||
|
||||
6.3 Limit-hitting swaps and swap-to-limit
|
||||
- For a user-specified price limit $\Lambda > 0$ on $p_i/p_j$, the marginal price trajectory $r(t)=r_0 e^{t/b}$ hits the limit at
|
||||
$$a_{\text{lim}} \;=\; b \,\ln\!\left(\frac{\Lambda}{r_0}\right),\qquad
|
||||
y_{\text{lim}} \;=\; b \,\ln\!\Big( 1 + r_0 \,\big(1 - r_0/\Lambda\big) \Big).$$
|
||||
- Capacity cap: If $y_{\text{lim}} > q_j$, cap to $y=q_j$ and use the inverse mapping to compute the implied input
|
||||
$$a_{\text{cap}} \;=\; b \,\ln\!\left(\frac{r_0}{\,r_0 + 1 - e^{\,q_j/b}\,}\right).$$
|
||||
|
||||
6.4 Properties: monotonicity, uniqueness, and stability
|
||||
- Monotonicity and uniqueness: For feasible states, $y(a)$ is strictly increasing and concave in $a$; the inverse $a(y)$ is strictly increasing and convex in $y$. The limit-hitting $a_{\text{lim}}$ is unique when $\Lambda>r_0$.
|
||||
- Numerical stability: Evaluations use log-sum-exp style reformulations, direct ratio formation for $r_0$, and argument guards for $\exp$ and $\ln$. Domain checks ensure denominators (e.g., $r_0 + 1 - e^{y/b}$) remain positive. See Appendix B for details.
|
||||
|
||||
7) Liquidity Operations
|
||||
|
||||
7.1 Pool initialization and bootstrap
|
||||
- Let the seed inventory be $\mathbf{q}^{(0)} \in \mathbb{R}_{\ge 0}^{\,n}$ with $S^{(0)} := \sum_i q_i^{(0)} > 0$. The effective liquidity is $b^{(0)} = \kappa\,S^{(0)}$.
|
||||
- LP supply: We take LP supply proportional to the size metric, $L := \eta\,S(\mathbf{q})$, with a fixed conversion $\eta>0$. Without loss of generality we set $\eta=1$ so that
|
||||
$$L \;=\; S(\mathbf{q}) \;=\; \sum_i q_i.$$
|
||||
At bootstrap, the seeder mints $L^{(0)} = S^{(0)}$ LP shares against $\mathbf{q}^{(0)}$.
|
||||
- LP price in units of asset $k$: Define the marginal value of one unit of $S$ in asset $k$ as
|
||||
$$P_L^{(k)}(\mathbf{q}) \;=\; \frac{1}{S(\mathbf{q})}\,\sum_{j=0}^{n-1} q_j \,\exp\!\left(\frac{q_j - q_k}{b(\mathbf{q})}\right),$$
|
||||
which aggregates the marginal exchange rates from each asset into $k$ (cf. Section 6).
|
||||
|
||||
7.2 Proportional deposit (mint)
|
||||
- A proportional deposit scales all coordinates by $(1+\alpha)$ for some $\alpha \ge 0$:
|
||||
$$\mathbf{q}' \;=\; (1+\alpha)\,\mathbf{q},\qquad \Delta q_i \;=\; \alpha\,q_i.$$
|
||||
- Minted LP shares are linear in the size-metric increase:
|
||||
$$\Delta L \;=\; L' - L \;=\; S(\mathbf{q}') - S(\mathbf{q}) \;=\; \alpha\,S(\mathbf{q}).$$
|
||||
- The post-deposit liquidity is $b'=\kappa\,S(\mathbf{q}')=(1+\alpha)\,b$.
|
||||
|
||||
7.3 Single-asset deposit (exact-in)
|
||||
- A contributor provides amount $a$ of asset $i$ and receives a proportional growth $\alpha \ge 0$ such that the system state can be rebalanced to $(1+\alpha)\,\mathbf{q}$ by swapping from $i$ into $j\ne i$ along the fee-free kernel. For each $j \ne i$, target out-amount $y_j := \alpha\,q_j$ requires input
|
||||
$$x_j(\alpha) \;=\; b \,\ln\!\left(\frac{r_{0,j}}{\,r_{0,j} + 1 - e^{\,y_j/b}\,}\right),\qquad
|
||||
r_{0,j} \;:=\; \exp\!\left(\frac{q_i - q_j}{b}\right).$$
|
||||
- The total input required to realize proportional growth $\alpha$ is
|
||||
$$a_{\text{req}}(\alpha) \;=\; \alpha\,q_i \;+\; \sum_{j\ne i} x_j(\alpha).$$
|
||||
- The minted shares are
|
||||
$$\Delta L \;=\; \alpha\,S(\mathbf{q}),$$
|
||||
where $\alpha$ is the unique solution to $a_{\text{req}}(\alpha)=a$ on its feasible domain (see Appendix A.5).
|
||||
|
||||
7.4 Multi-asset deposit (arbitrary vector)
|
||||
- Given a deposit vector $\mathbf{a} \in \mathbb{R}_{\ge 0}^{\,n}$, decompose it into:
|
||||
- a proportional component $\bar{\alpha} := \min_i \{ a_i / q_i \}$ (with convention $a_i/q_i=+\infty$ if $q_i=0$ and $a_i>0$), which mints $\bar{\alpha}\,S(\mathbf{q})$ shares and updates $\mathbf{q}$ proportionally, and
|
||||
- residuals $\tilde{\mathbf{a}} := \mathbf{a} - \bar{\alpha}\,\mathbf{q}$ that can be contributed via single-asset deposit(s) using 7.3 (sequence or batching).
|
||||
- The total minted shares are additive in the realized proportional growths:
|
||||
$$\Delta L \;=\; \left(\bar{\alpha} + \sum_{m} \alpha_m\right)\,S(\mathbf{q})$$
|
||||
where each $\alpha_m$ solves $a_{\text{req}}(\alpha_m)$ for a residual leg.
|
||||
|
||||
7.5 Proportional withdrawal (burn)
|
||||
- Burning $\Delta L$ LP shares effects a proportional redemption with factor
|
||||
$$\alpha \;=\; \frac{\Delta L}{S(\mathbf{q})} \in (0,1],\qquad \mathbf{q}' \;=\; (1-\alpha)\,\mathbf{q}.$$
|
||||
- The holder receives $\alpha\,q_i$ units of each asset $i$; equivalently, $L' = L - \Delta L = S(\mathbf{q}')$ and $b'=(1-\alpha)\,b$.
|
||||
|
||||
7.6 Single-asset withdrawal (exact-out)
|
||||
- A holder burns $\Delta L$ shares (i.e., $\alpha=\Delta L/S(\mathbf{q})$) and requests payout exclusively in asset $i$. Starting from $\mathbf{q}_\text{local}=(1-\alpha)\,\mathbf{q}$, for each $j\ne i$:
|
||||
- withdraw $\alpha\,q_j$ units of $j$, and
|
||||
- swap $j \to i$ along the fee-free kernel using the two-asset closed form. The candidate out-amount is
|
||||
$$y_{j\to i} \;=\; b \,\ln\!\Big( 1 + r_{0,j}\,\big(1 - e^{-a_j/b}\big) \Big),\quad
|
||||
a_j := \alpha\,q_j,\quad r_{0,j} := \exp\!\left(\frac{q^{\text{local}}_j - q^{\text{local}}_i}{b}\right),$$
|
||||
with $b=\kappa\,S(\mathbf{q})$ evaluated at pre-burn or quasi-static local state.
|
||||
- If the computed $y_{j\to i}$ would exceed $q^{\text{local}}_i$, cap to capacity and invert to solve the implied input (Appendix A.6). The total single-asset payout is
|
||||
$$Y_i \;=\; \alpha\,q_i \;+\; \sum_{j\ne i} y_{j\to i}.$$
|
||||
|
||||
7.7 Share issuance, pricing, and dilution
|
||||
- With $L=S$, share issuance is linear in the size-metric; proportional joins/exits preserve relative ownership. The instantaneous LP price in units of asset $k$ is $P_L^{(k)}(\mathbf{q})$ from 7.1. Under joins, $P_L^{(k)}$ remains unchanged for proportional deposits; under single-asset joins, it adjusts according to the realized rebalancing path.
|
||||
|
||||
7.8 Fee accrual to LPs and value capture
|
||||
- Swap fees are taken at the token layer and retained in the pool balances, increasing $S(\mathbf{q})$ relative to $L$ and thereby raising $P_L^{(k)}$ for all $k$. This constitutes implicit fee accrual to LPs via state appreciation rather than explicit distributions.
|
||||
|
||||
7.9 Edge cases and operational notes
|
||||
- Tiny liquidity: When $S$ is small, $b=\kappa S$ is small and price impact is steep; deployments SHOULD enforce a minimum bootstrap $S^{(0)}$ and/or minimum minted $L^{(0)}$.
|
||||
- Extreme imbalances: As some $q_j \to 0$, price ratios $\exp((q_{\text{quote}}-q_{\text{base}})/b)$ can become large; capacity caps ($y \le q_j$) and positivity checks on logarithm arguments ensure safe evaluation.
|
||||
- Asset additions/removals: Changing the asset set alters $n$ and the pricing manifold. Deployments typically fix the asset universe; adding/removing assets is best handled via new pool instances with fresh initialization.
|
||||
|
||||
8) Fees and Incentives (Static Parameters)
|
||||
|
||||
8.1 Fee model and placement
|
||||
- Let the swap fee rate be $f_{\text{swap}} \in [0,1)$, and let the protocol capture a fraction $\phi \in [0,1]$ of that fee (so LPs receive the remaining $1-\phi$ share via state appreciation).
|
||||
- We apply fees outside the fee-free pricing kernel. For an exact-in trade with submitted input $a$ on asset $i$, the effective kernel input is
|
||||
$$a_{\text{eff}} \;=\; (1 - f_{\text{swap}})\,a.$$
|
||||
The fee amount is $a - a_{\text{eff}}$, of which $\phi\,(a - a_{\text{eff}})$ accrues to the protocol and $(1-\phi)\,(a - a_{\text{eff}})$ to LPs (retained in the pool state).
|
||||
- The fee-free kernel computes the out-amount $y_{\text{ker}}$ using $a_{\text{eff}}$; the user receives $y_{\text{user}} = y_{\text{ker}}$ (or a fee-adjusted variant if fees are taken from output instead). The invariant and closed forms remain unaffected because pricing is computed on $a_{\text{eff}}$.
|
||||
|
||||
8.2 Economic impact
|
||||
- Effective price and slippage: With input-side fees, the user’s effective marginal price scales by $(1 - f_{\text{swap}})^{-1}$ for small trades; total slippage decomposes into kernel slippage (from the LMSR curve) plus a constant offset due to fees.
|
||||
- LP returns: Fees retained in the pool increase $S(\mathbf{q})$ relative to outstanding $L$ and thus raise LP share value. Protocol revenue scales with $\phi$ and trade flow; LP revenue scales with $(1-\phi)$.
|
||||
|
||||
8.3 Static-parameter policy (immutability)
|
||||
- Parameters $\kappa$, $f_{\text{swap}}$, and $\phi$ are set at deployment and are immutable thereafter. Benefits include:
|
||||
- Predictability: depth and fee impact are ex-ante auditable for a given $S$.
|
||||
- Governance minimization: no discretionary levers to be toggled post-deployment.
|
||||
- Composability: integrators can rely on stable behavior across time.
|
||||
|
||||
9) Risk Analysis and Theoretical Properties
|
||||
|
||||
9.1 Convexity and path independence
|
||||
- With constant $b$, $C(\mathbf{q}) = b\log\!\big(\sum_i e^{q_i/b}\big)$ is convex and cost differences are path independent:
|
||||
$$\Delta C \;=\; C(\mathbf{q}+\Delta\mathbf{q}) - C(\mathbf{q}) \quad \text{depends only on the endpoints}.$$
|
||||
- With $b=\kappa S(\mathbf{q})$, $\partial C/\partial q_i$ includes a common additive term (Section 4); pairwise ratios
|
||||
$$P(\text{base}\to\text{quote}\mid \mathbf{q}) \;=\; \exp\!\left(\frac{q_{\text{quote}}-q_{\text{base}}}{b(\mathbf{q})}\right)$$
|
||||
remain valid under a quasi-static-$b$ view, which is the pricing lens used for infinitesimal (or discretized) steps.
|
||||
|
||||
9.2 Bounded loss (intuition) and capital efficiency
|
||||
- For constant $b$, the classic LMSR worst-case loss is $b\ln n$ in the payout numéraire. Under $b=\kappa S$, this scales proportionally with $S$, giving an instantaneous per-unit-$S$ bound proportional to $\kappa \ln n$.
|
||||
- Capital efficiency follows from linear scaling: increasing $S$ (or $\kappa$) linearly deepens liquidity. The two-asset exact-in form
|
||||
$$y(a) \;=\; b\,\ln\!\Big(1 + r_0(1 - e^{-a/b})\Big)$$
|
||||
exhibits $y'(0)=\frac{r_0}{1+r_0}$ and curvature $\frac{\mathrm{d}^2 y}{\mathrm{d}a^2}<0$, quantifying the marginal depth and diminishing returns for larger $a$.
|
||||
|
||||
9.3 Sensitivity to $b$ and reserve scales
|
||||
- Scale invariance: If $\mathbf{q}\mapsto \lambda \mathbf{q}$, then $S\mapsto \lambda S$, $b\mapsto \lambda b$, and $P(\text{base}\to\text{quote})$ is unchanged. Thus depth in notional terms scales linearly with $\lambda$.
|
||||
- As $b$ increases (via larger $S$ or $\kappa$), the function $y(a)$ becomes less curved (greater depth), reducing slippage for a given input size $a$.
|
||||
|
||||
9.4 Failure modes and mitigations
|
||||
- Thin liquidity: Small $S$ implies small $b$, steep impact, and sensitivity to large orders. Mitigations: enforce minimum bootstrap $S^{(0)}$, external routing safeguards, and user-specified price limits $\Lambda$.
|
||||
- Extreme concentration: As some $q_j \to 0$, prices can become very large; capacity caps ($y\le q_j$) and limit-hitting logic prevent pathological outputs.
|
||||
- Numerical edge cases: Guard $\exp$/$\ln$ domains, ensure denominators like $r_0 + 1 - e^{y/b} > 0$, and prefer ratio-based computations (Appendix B).
|
||||
- No-arbitrage hygiene: Maintain monotonicity of $y(a)$ and its inverse $a(y)$; avoid rounding that could create free lunches (see Section 12).
|
||||
|
||||
10) Numerical Methods and Implementation Considerations
|
||||
|
||||
10.1 Fixed-point arithmetic and precision policy
|
||||
- Representation: Quantities are computed in fixed-point; equations are presented over reals for clarity. Let $F$ denote the fractional precision (bits or decimal places).
|
||||
- Range limits: For stability of exponentials and logarithms, enforce
|
||||
$$|x| \le X_{\max} \quad \text{when evaluating } \exp(x),\qquad u > 0 \quad \text{when evaluating } \ln(u).$$
|
||||
Practical choices take $X_{\max}$ large enough to cover the operating envelope while preventing overflow.
|
||||
- Rounding: Use round-toward-zero or round-to-nearest consistently, prioritizing order-preservation (see 10.6). Avoid mixed rounding modes within a single expression.
|
||||
|
||||
10.2 Stable exp/log evaluation (log-sum-exp)
|
||||
- Cost and shares are evaluated via a log-sum-exp recentering. Define $y_i := q_i/b$, $M := \max_i y_i$, then
|
||||
$$C(\mathbf{q}) \;=\; b\left(M + \log \sum_i e^{\,y_i - M}\right),\qquad
|
||||
\pi_i \;=\; \frac{e^{\,y_i - M}}{\sum_k e^{\,y_k - M}}.$$
|
||||
Centering at $M$ prevents overflow/underflow when $y_i$ are far apart.
|
||||
- Ratio formation: Compute ratios directly to avoid extra $\exp$/$\ln$ where possible, e.g.
|
||||
$$r_0 \;=\; \exp\!\left(\frac{q_i - q_j}{b}\right)$$
|
||||
rather than $e^{q_i/b}/e^{q_j/b}$.
|
||||
|
||||
10.3 Reformulations for numerical stability
|
||||
- Use $\ln(1+u)$ and $e^x-1$ style identities for small arguments:
|
||||
$$\ln(1+u) \approx u - \frac{u^2}{2} \quad (|u|\ll 1),\qquad e^{x}-1 \approx x + \frac{x^2}{2} \quad (|x|\ll 1),$$
|
||||
switching to series forms when $|u|$ or $|x|$ are below thresholds to reduce cancellation.
|
||||
- Inverse mapping stability: For exact-out inversion
|
||||
$$a(y) \;=\; b \,\ln\!\left(\frac{r_0}{\,r_0 + 1 - e^{\,y/b}\,}\right),$$
|
||||
compute $E:=e^{y/b}$ once; if $E\approx 1$, use series for $E-1$ to avoid subtractive cancellation.
|
||||
- Precompute reciprocals: Cache $b^{-1}$ to replace divisions by multiplications and reduce dispersion.
|
||||
|
||||
10.4 Algorithm selection, termination, and convergence
|
||||
- Closed forms: Prefer the exact two-asset formulas for exact-in and exact-out when applicable (Sections 6 and A.2–A.3).
|
||||
- Root-finding for proportional joins: Solve $a_{\text{req}}(\alpha)=a$ via bracketing and bisection on a monotone map:
|
||||
$$a_{\text{req}}(\alpha) \;=\; \alpha q_i + \sum_{j\ne i} b \ln\!\left(\frac{r_{0,j}}{\,r_{0,j} + 1 - e^{\,\alpha q_j/b}\,}\right).$$
|
||||
Terminate when the interval width is below $\varepsilon$ or the function gap is within tolerance. Monotonicity guarantees uniqueness.
|
||||
- Limit-hitting: Compute $a_{\text{lim}}=b\ln(\Lambda/r_0)$ directly; validate $\Lambda>r_0$ and that intermediate expressions stay in-range.
|
||||
|
||||
10.5 Performance vs precision trade-offs
|
||||
- Caching: Reuse common subexpressions (e.g., $b$, $b^{-1}$, $r_{0,j}$) across loops and iterative steps.
|
||||
- Operation count: Prefer fused operations and single-pass accumulations (e.g., recentered $\sum e^{\cdot}$ with on-the-fly rescaling).
|
||||
- Approximation regions: In designated near-balanced regimes (Section 11), switch to polynomial approximations to avoid transcendental calls, respecting global error budgets.
|
||||
|
||||
10.6 Error analysis, monotonicity, and arbitrage-safety
|
||||
- Error budgeting: Allocate a maximum relative error $\epsilon_{\text{rel}}$ to each primitive ($\exp$, $\ln$, polynomials), ensuring the composed map (e.g., $y(a)$) meets end-to-end bounds.
|
||||
- Monotonicity preservation: Ensure numerical implementations of $y(a)$ are strictly increasing and of $a(y)$ are strictly increasing by:
|
||||
- enforcing positive denominators (e.g., $r_0 + 1 - e^{y/b} > 0$),
|
||||
- clamping intermediate “inner” terms to $(0,\infty)$,
|
||||
- preferring formulations without subtractive cancellation near boundaries.
|
||||
- Arbitrage hygiene: Use conservative branches (cap-and-invert) when near capacity or domain boundaries to avoid nonphysical outputs (negative or exceeding balances).
|
||||
|
||||
11) BalancedPair Optimization (Dedicated Section)
|
||||
|
||||
11.1 Applicability conditions
|
||||
- Define $\delta := (q_i - q_j)/b$ and $\tau := a/b$. The balanced regime is characterized by
|
||||
$$|\delta| \le \delta_\star,\qquad |\tau| \le \tau_\star,$$
|
||||
with design thresholds $(\delta_\star,\tau_\star)$ chosen so that polynomial approximations meet the global error budget while preserving monotonicity.
|
||||
|
||||
11.2 Balanced 2-asset closed form and small-argument expansions
|
||||
- The exact two-asset mapping is
|
||||
$$y(a) \;=\; b \,\ln\!\Big(1 + r_0 (1 - e^{-a/b})\Big),\qquad r_0=e^{\delta}.$$
|
||||
- For $|\delta|\ll 1$ and $|\tau|\ll 1$, use expansions
|
||||
$$e^{\pm x} \approx 1 \pm x + \frac{x^2}{2},\qquad \ln(1+u) \approx u - \frac{u^2}{2},$$
|
||||
yielding
|
||||
$$y(a) \;\approx\; b \left[ r_0 \tau - \frac{1}{2} r_0 \tau^2 \right] + \mathcal{O}\!\left(\tau^3,\, |\delta|\,\tau^2\right),\quad r_0 \approx 1 + \delta + \frac{\delta^2}{2}.$$
|
||||
- Symmetry: At $\delta=0$, the mapping satisfies $y(a)\approx \tfrac{a}{2} - \tfrac{a^2}{4b} + \cdots$, reflecting equal liquidity on both sides.
|
||||
|
||||
11.3 Polynomial approximations without $\exp/\ln$
|
||||
- Construct minimax polynomials $P_d(x)\approx e^{x}$ on $[-\tau_\star,0]$ and $Q_d(u)\approx \ln(1+u)$ on $[0,u_\star]$, where $u_\star$ is induced by the range of $r_0(1-e^{-\tau})$ in the regime.
|
||||
- Compose
|
||||
$$\tilde{y}(a) \;=\; b \, Q_d\!\Big( r_0 \,\big(1 - P_d(-\tau)\big) \Big),\qquad \tau=\frac{a}{b},$$
|
||||
with $r_0$ optionally approximated by a low-degree polynomial in $\delta$ when $|\delta|\le \delta_\star$.
|
||||
- Error bounds:
|
||||
$$\big|e^{x}-P_d(x)\big| \le e^{\tau_\star}\,\frac{\tau_\star^{\,d+1}}{(d+1)!},\qquad
|
||||
\big|\ln(1+u)-Q_d(u)\big| \le \frac{u^{\,d+1}}{(d+1)\,(1-u)^{\,d+1}},$$
|
||||
ensuring $\big|y(a)-\tilde{y}(a)\big| \le \epsilon$ for a target $\epsilon$ via appropriate $d$, $\delta_\star$, $\tau_\star$, $u_\star$.
|
||||
|
||||
11.4 Dispatcher logic and safe fallback
|
||||
- Preconditions:
|
||||
- check $|\delta|\le \delta_\star$, $|a|/b \le \tau_\star$, and positivity of intermediate “inner” terms,
|
||||
- ensure capacity is respected ($\tilde{y}(a)\le q_j$) or switch to cap-and-invert branch.
|
||||
- If any precondition fails, fall back to the general closed-form path with full transcendental evaluations.
|
||||
- Price-limit compatibility: When a price limit $\Lambda$ is set, verify that the approximated trajectory respects $r(t)\le \Lambda$; otherwise, revert to exact limit-hitting computation $a_{\text{lim}}=b\ln(\Lambda/r_0)$.
|
||||
|
||||
11.5 Invariant preservation and monotonicity guarantees
|
||||
- Enforce $\tilde{y}'(a) > 0$ on the approximation domain by design (choose $P_d$, $Q_d$ that are monotonically increasing on their intervals and validate numerically).
|
||||
- Guard inner arguments to keep them in $(0,\infty)$, preventing nonphysical outputs or $\ln$ domain violations.
|
||||
- Capacity and nonnegativity: Clamp to $[0, q_j]$ and use inverse mapping to reconcile inputs in cap branches.
|
||||
|
||||
11.6 Gas and performance analysis
|
||||
- Eliminating transcendental calls in the balanced regime reduces cost to a small fixed number of polynomial evaluations and multiplications.
|
||||
- Dispatcher overhead is minimal (few comparisons and a couple of scaled differences). Overall, the optimization provides substantial speedups in near-parity trades while maintaining accuracy guarantees.
|
||||
- The fallback ensures worst-case performance is bounded by the general path.
|
||||
|
||||
12) Protocol Safety: Numerical and Invariant Guarantees
|
||||
|
||||
12.1 Invariant checks and fail-fast conditions
|
||||
- Domain guards:
|
||||
- Size metric: $S(\mathbf{q}) = \sum_i q_i > 0$, hence $b=\kappa S > 0$.
|
||||
- Valid indices and nonnegative inputs/outputs for user-facing operations.
|
||||
- Exponential and logarithm arguments within bounded, valid domains; prefer log-sum-exp recentering.
|
||||
- Capacity and limit checks:
|
||||
- Out-amounts are capped by available balances ($y \le q_j$).
|
||||
- Price-limit trades enforce $\Lambda > r_0$ and truncate at $a_{\text{lim}}=b\ln(\Lambda/r_0)$.
|
||||
- Consistency guards:
|
||||
- Denominators (e.g., $r_0 + 1 - e^{y/b}$) must be positive.
|
||||
- Reciprocal quantities (e.g., $1/b$) are computed once and reused to avoid drift.
|
||||
|
||||
12.2 Precision-induced error handling and rounding
|
||||
- Monotonicity-first policy: Prefer formulations that preserve order (e.g., log-sum-exp, ratio formation for $r_0$).
|
||||
- Conservative rounding: When a decision boundary is approached (e.g., inner argument of $\ln$ near zero), choose the conservative branch (cap-and-invert) rather than extrapolating.
|
||||
- Bounded evaluations: Enforce $|x| \le X_{\max}$ for $\exp(x)$ to prevent overflow; clamp inputs that would violate this bound and surface clear errors to callers.
|
||||
|
||||
12.3 Verification targets
|
||||
- Structural properties:
|
||||
- Convexity under constant $b$; gradient softmax identities.
|
||||
- Pairwise price ratios consistent with $P(\text{base}\to\text{quote})$ under quasi-static $b$.
|
||||
- Numerical properties:
|
||||
- Monotonicity of $y(a)$ and $a(y)$, uniqueness of $a_{\text{lim}}$ when $\Lambda>r_0$.
|
||||
- Path-independence of $\Delta C$ in constant-$b$ tests; bounded relative error within predefined budgets.
|
||||
|
||||
12.4 Testing approach
|
||||
- Property-based tests across randomized states $\mathbf{q}$, input sizes, and asset pairs, including adversarial edge cases (tiny $S$, extreme $r_0$, near-capacity).
|
||||
- Boundary tests for domain guards (e.g., $S\downarrow 0$, $\Lambda \downarrow r_0$, inner argument of $\ln$ near zero).
|
||||
- Differential tests against high-precision reference implementations for $y(a)$, $a(y)$, and price ratios.
|
||||
- No-negative-arbitrage checks under rounding: ensure discrete effects cannot be exploited for profit with zero risk.
|
||||
|
||||
13) Deployment Model and Parameter Fixity
|
||||
|
||||
13.1 Immutable parameters and non-upgradability
|
||||
- The pool is deployed with a fixed asset set and immutable parameters $(\kappa, f_{\text{swap}}, \phi)$, where $\kappa>0$ determines $b(\mathbf{q})=\kappa S(\mathbf{q})$, $f_{\text{swap}}$ is the swap fee rate, and $\phi$ is the protocol share of fees.
|
||||
- Contracts are deployed in a non-upgradable, ownerless configuration. No governance can modify $\kappa$, fees, or the asset universe after deployment.
|
||||
|
||||
13.2 Deployment inputs and initialization
|
||||
- Deployment specifies: the asset list, normalization conventions, and parameter tuple $(\kappa, f_{\text{swap}}, \phi)$. Initialization requires a seed inventory $\mathbf{q}^{(0)}$ with $S^{(0)}=\sum_i q_i^{(0)}>0$, yielding initial liquidity
|
||||
$$b^{(0)} \;=\; \kappa \, S^{(0)}.$$
|
||||
- A minimum bootstrap size $S^{(0)}$ SHOULD be enforced to avoid thin-liquidity regimes at genesis.
|
||||
|
||||
13.3 Reproducibility and transparency
|
||||
- Given $(\kappa, f_{\text{swap}}, \phi)$ and the initial state $\mathbf{q}^{(0)}$, the AMM’s pricing map is fully determined for all subsequent states via
|
||||
$$C(\mathbf{q}) \;=\; b(\mathbf{q}) \,\log\!\left(\sum_i e^{q_i / b(\mathbf{q})}\right),\qquad b(\mathbf{q})=\kappa\,S(\mathbf{q}).$$
|
||||
- Observability: Public views expose instantaneous price ratios $P(\text{base}\to\text{quote})$, price shares $\pi_i$, LP price $P_L^{(k)}$, and size metric $S(\mathbf{q})$.
|
||||
|
||||
13.4 Operational implications
|
||||
- Asset changes: To add or remove assets, deploy a new pool instance and migrate liquidity; existing pools remain immutable.
|
||||
- Ecosystem integration: The fixed-parameter model simplifies routing and valuation, enabling integrators to precompute depth profiles for anticipated $S$ regimes.
|
||||
- Risk discipline: The absence of admin levers eliminates governance risk but requires careful parameter selection at deployment.
|
||||
|
||||
15) Limitations and Future Work
|
||||
|
||||
15.1 Limitations
|
||||
- Quasi-static $b$ assumption: Pricing steps treat $b$ as locally constant. While pairwise ratios are exact for infinitesimal moves, finite trades are evaluated with closed forms derived from the two-asset reduction; model fidelity remains high but is not a full global-gradient integration under state-dependent $b$.
|
||||
- Thin-liquidity vulnerability: For small $S$, $b=\kappa S$ is small and price impact is steep; users should rely on price limits $\Lambda$ and integrators should enforce minimum bootstrap sizes.
|
||||
- Extreme concentration and domain edges: As some $q_j \to 0$, ratios $\exp((q_{\text{quote}}-q_{\text{base}})/b)$ become large; capacity caps and domain guards prevent nonphysical outcomes but can truncate trades.
|
||||
- Expressivity: The mechanism is not tuned for pegged pairs like stableswap, nor does it encode cross-asset correlations by default.
|
||||
- Numerical constraints: Fixed-point range/precision, exponential/log bounds, and approximation regimes impose domain restrictions for safe operation.
|
||||
- Static parameters: Immutability removes governance agility; mis-specified $\kappa$ or fees require new deployments.
|
||||
|
||||
15.2 Future work
|
||||
- Adaptive proportionality: Explore principled adaptive $\kappa$ while preserving LMSR properties (e.g., bounded-loss analogues) and avoiding governance risk (e.g., rule-based or oracle-free triggers).
|
||||
- Correlated or basket-targeted variants: Incorporate weighted size metrics $S_w(\mathbf{q})$ or correlation-aware formulations, with rigorous analysis of price and risk implications.
|
||||
- Enhanced approximations: Extend polynomial or rational approximations with verified remainder bounds, larger safe domains, and automatic dispatchers with certified monotonicity.
|
||||
- Off-chain assists and proofs: Use off-chain computation for heavy numerical routines with on-chain verification (e.g., succinct proofs) while maintaining transparency.
|
||||
- MEV-aware design: Integrate user-settled price limits, batch auctions, or commit-reveal to mitigate adverse selection and sandwich risk.
|
||||
- Layer-2 deployment: Leverage lower fees and faster settlement to widen the safe domain for numerical precision and to support more assets.
|
||||
|
||||
16) Conclusion
|
||||
|
||||
- We presented a multi-asset AMM whose pricing kernel is the LMSR cost function with an effective liquidity parameter proportional to pool size, $b(\mathbf{q})=\kappa S(\mathbf{q})$. This delivers scale-invariant responsiveness, preserves softmax-derived pairwise price ratios, and supports any-to-any swaps via a single convex potential.
|
||||
- Closed-form two-asset reductions provide exact-in, exact-out, and limit-hitting formulas with strong monotonicity and uniqueness properties, while capacity caps and conservative inverses ensure safety at domain boundaries. Liquidity operations (proportional and single-asset joins/exits) follow directly from the same potential framework.
|
||||
- A fixed-parameter policy eliminates governance risk and makes depth calibration transparent. Numerical stability is achieved through log-sum-exp reformulations, guarded transcendental domains, and optional balanced-regime polynomial approximations with error bounds.
|
||||
- Outlook: This LMSR AMM complements CFMMs by offering multi-asset price discovery under a convex potential with predictable scaling. Future work includes adaptive yet governance-minimized responsiveness, correlation-aware variants, and verifiable off-chain assists—aimed at retaining theoretical guarantees while broadening applicability.
|
||||
|
||||
|
||||
|
||||
|
||||
|
||||
|
||||
|
||||
|
||||
|
||||
17) Appendices
|
||||
|
||||
A. Full derivations and proofs
|
||||
|
||||
A.1 Gradient, price shares, and pairwise prices
|
||||
- With $b$ treated as a constant parameter, the LMSR cost $C(\mathbf{q}) = b \log\!\big(\sum_k e^{q_k/b}\big)$ yields
|
||||
$$\frac{\partial C}{\partial q_i} \;=\; \frac{e^{q_i/b}}{\sum_k e^{q_k/b}} \;=\; \pi_i(\mathbf{q}).$$
|
||||
- With $b = \kappa \, S(\mathbf{q})$, the total derivative becomes
|
||||
$$\frac{\partial C}{\partial q_i} \;=\; A(\mathbf{q}) \;+\; \frac{e^{q_i/b}}{\sum_k e^{q_k/b}},$$
|
||||
where $A(\mathbf{q})$ is an additive term common to all $i$ that arises from $\partial b/\partial q_i$. Consequently, differences between marginal prices are preserved, and the pairwise marginal price ratio reduces to
|
||||
$$P(\text{base}\to\text{quote}\mid \mathbf{q}) \;=\; \exp\!\left(\frac{q_{\text{quote}} - q_{\text{base}}}{b(\mathbf{q})}\right).$$
|
||||
This is the exchange rate used by the kernel, under the quasi-static-$b$ assumption.
|
||||
|
||||
A.2 Two-asset closed form: exact-in
|
||||
- Consider a swap from $i$ (in) to $j$ (out) with quasi-static $b$. Let $r_0 := \exp\!\big((q_i - q_j)/b\big)$. Along the trade path, the instantaneous marginal price ratio evolves as $r(t) = r_0 \, e^{t/b}$, where $t$ is the cumulative input of asset $i$.
|
||||
- The infinitesimal output satisfies
|
||||
$$\mathrm{d}y \;=\; \frac{r(t)}{1 + r(t)} \,\mathrm{d}t,$$
|
||||
in the two-asset reduction induced by the LMSR gradient. Integrating from $0$ to $a$ yields the closed form
|
||||
$$y(a) \;=\; b \,\ln\!\Big( 1 + r_0 \,\big(1 - e^{-a/b}\big) \Big).$$
|
||||
- Properties: $y(0) = 0$, $y'(0) = \frac{r_0}{1 + r_0}$, $y$ is increasing and concave in $a$, and $\lim_{a\to\infty} y = b \,\ln(1 + r_0)$.
|
||||
|
||||
A.3 Two-asset closed form: exact-out (inverse)
|
||||
- Given $y \ge 0$, invert the relation in A.2. Let $E := e^{y/b}$. Then
|
||||
$$1 + r_0 \,\big(1 - e^{-a/b}\big) \;=\; E
|
||||
\;\Rightarrow\; e^{-a/b} \;=\; 1 - \frac{E - 1}{r_0} \;=\; \frac{r_0 + 1 - E}{r_0}$$
|
||||
$$\Rightarrow\quad a(y) \;=\; -\,b \,\ln\!\left(\frac{r_0 + 1 - E}{r_0}\right) \;=\; b \,\ln\!\left(\frac{r_0}{\,r_0 + 1 - E\,}\right).$$
|
||||
- This inverse exists and is unique for $y \in \big[0,\, b \ln(1 + r_0)\big]$.
|
||||
|
||||
A.4 Limit-hitting and swap-to-limit
|
||||
- Let $\Lambda > 0$ be a maximum acceptable marginal price ratio for $p_i/p_j$. With $r(t) = r_0 \, e^{t/b}$, the limit is reached when $r(t) = \Lambda$, giving the unique truncated input
|
||||
$$a_{\text{lim}} \;=\; b \,\ln\!\left(\frac{\Lambda}{r_0}\right).$$
|
||||
- The corresponding output at the limit is
|
||||
$$y_{\text{lim}} \;=\; b \,\ln\!\Big( 1 + r_0 \,\big(1 - e^{-a_{\text{lim}}/b}\big) \Big)
|
||||
\;=\; b \,\ln\!\Big( 1 + r_0 \,\big(1 - r_0/\Lambda\big) \Big).$$
|
||||
- If $y_{\text{lim}}$ exceeds the available out-asset balance $q_j$, cap output to $q_j$ and solve for the input required to realize $y = q_j$ using the inverse formula of A.3:
|
||||
$$a_{\text{cap}} \;=\; b \,\ln\!\left(\frac{r_0}{\,r_0 + 1 - e^{\,q_j / b}\,}\right).$$
|
||||
|
||||
A.5 Single-asset mint via proportional growth (exact-in to many)
|
||||
- Suppose a user contributes amount $a$ of asset $i$ and wishes to increase the pool proportionally by factor $1 + \alpha$ (with $\alpha \ge 0$). For each $j \ne i$, let $y_j := \alpha \, q_j$ be the target out-amount in $j$ when swapping from $i$. Define $r_{0,j} := \exp\!\big((q_i - q_j)/b\big)$. From A.3, the input required to realize $y_j$ is
|
||||
$$x_j(\alpha) \;=\; b \,\ln\!\left(\frac{r_{0,j}}{\,r_{0,j} + 1 - e^{\,y_j / b}\,}\right).$$
|
||||
- The self-asset contribution is $\alpha \, q_i$. The total input required is
|
||||
$$a_{\text{req}}(\alpha) \;=\; \alpha \, q_i \;+\; \sum_{j \ne i} x_j(\alpha).$$
|
||||
- Solve for $\alpha$ via a monotone root-find on $a_{\text{req}}(\alpha) = a$. The function is increasing in $\alpha$ on its domain, with unique solution when feasible.
|
||||
|
||||
A.6 Single-asset burn via proportional redemption
|
||||
- Burning a proportional share $\alpha \in (0, 1]$ reduces the pool balances to $(1 - \alpha)\,\mathbf{q}$. A single-asset payout in asset $i$ aggregates (i) the direct $\alpha \, q_i$ redemption and (ii) the swaps from each asset $j \ne i$ of their redeemed $\alpha \, q_j$ portions into $i$ using A.2 with the local (post-burn) state. If a computed out-amount would exceed the local $q_i$, cap to capacity and solve the inverse for the input used.
|
||||
|
||||
A.7 Balanced 2-asset special case and polynomial approximations
|
||||
- Near balance, define $\delta := (q_i - q_j)/b$ with $|\delta| \ll 1$ and let $a/b$ be small. Using second-order expansions:
|
||||
$$e^{\pm x} \approx 1 \pm x + \frac{x^2}{2},\qquad \ln(1 + u) \approx u - \frac{u^2}{2},$$
|
||||
we obtain for small $a/b$ and $\delta$:
|
||||
$$r_0 = e^{\delta} \approx 1 + \delta + \frac{\delta^2}{2},$$
|
||||
$$y(a) = b \,\ln\!\big(1 + r_0(1 - e^{-a/b})\big)
|
||||
\approx b \left[ r_0 \left(\frac{a}{b}\right) - \frac{1}{2} r_0 \left(\frac{a}{b}\right)^2 \right]
|
||||
+ \mathcal{O}\!\left(\left(\frac{a}{b}\right)^3,\, \delta \left(\frac{a}{b}\right)^2\right).$$
|
||||
- In particular, when $\delta \approx 0$,
|
||||
$$y(a) \approx \frac{a}{2} - \frac{a^2}{4b} + \cdots,$$
|
||||
which admits efficient evaluation via fixed low-degree polynomials. This motivates a “balanced pair” dispatcher that, under explicit near-balance preconditions ($|\delta| \le \delta_\star$ and $a/b \le \tau_\star$), uses minimax Chebyshev polynomials for $\exp$ and $\ln$ on compact intervals to meet a specified error budget, and otherwise falls back to the general path.
|
||||
|
||||
B. Error bounds and approximation details
|
||||
|
||||
B.1 Fixed-point arithmetic and stability policy
|
||||
- Representation: All quantities are computed in fixed-point with a wide fractional field; equations are written over reals for exposition. Overflow/underflow and domain errors are prevented with explicit guards.
|
||||
- Log-sum-exp: The cost is evaluated as $C = b \left(M + \log \sum_i e^{\,y_i - M}\right)$ with $y_i := q_i/b$ and $M := \max_i y_i$. This ensures stable accumulation even when some $y_i$ are far apart.
|
||||
- Exponential guard: The arguments to $\exp(\cdot)$ are restricted to a bounded interval to ensure finite, monotone outputs. A practical bound is $|x| \le 32$ (in internal fixed-point units), which comfortably covers operational regimes while preventing overflow.
|
||||
- Ratio shortcuts: Where possible, we form ratios such as $r_0 = \exp\!\big((q_i - q_j)/b\big)$ directly, avoiding separate exponentials and a division, improving both precision and cost.
|
||||
|
||||
B.2 Monotonicity and error budgets
|
||||
- Kernel monotonicity: The closed forms in A.2–A.4 are strictly increasing in input and satisfy $y'(a) \in (0,1)$ for feasible states. Numerical implementations preserve monotonicity by:
|
||||
- using log-sum-exp,
|
||||
- guarding denominators (e.g., $r_0 + 1 - e^{\,y/b} > 0$),
|
||||
- clamping to capacity when necessary and solving inverses in the capped branch.
|
||||
- Error targets: Prices, shares, and swap amounts are computed to within small relative error (e.g., $\le 10^{-9}$ for typical ranges). Guards reject or cap inputs that would violate error or domain constraints.
|
||||
|
||||
B.3 Polynomial approximations in balanced 2-asset mode
|
||||
- Domains: For $|\delta| \le \delta_\star$ and $\big|a/b\big| \le \tau_\star$, $\exp$ and $\ln$ are approximated by minimax polynomials on compact intervals $[-\tau_\star, \tau_\star]$ and $[\,1 - u_\star,\, 1 + u_\star\,]$, respectively, with $u_\star$ induced by the $\exp$ range.
|
||||
- Construction: Coefficients are obtained offline (e.g., via Remez) to minimize the maximum relative error over the domain.
|
||||
- Remainder bounds: Standard analytic bounds apply:
|
||||
$$\big|e^{x} - P_d(x)\big| \;\le\; e^{\tau_\star}\,\frac{\tau_\star^{\,d+1}}{(d+1)!},$$
|
||||
$$\big|\ln(1 + u) - Q_d(u)\big| \;\le\; \frac{|u|^{\,d+1}}{(d+1)\,(1 - |u|)^{\,d+1}},\qquad |u| < 1.$$
|
||||
Degree $d$ and domain parameters $(\delta_\star, \tau_\star, u_\star)$ are chosen to meet the global error budget while maintaining monotonicity of the composed swap mapping.
|
||||
|
||||
B.4 Implementation notes for stability
|
||||
- Prefer single-pass accumulations with on-the-fly recentering for $\sum \exp(\cdot)$.
|
||||
- Maintain consistent reciprocals (e.g., precompute $1/b$) to reduce rounding dispersion.
|
||||
- Use explicit positivity checks (e.g., size metric $S > 0$, $\exp$ arguments within bounds, denominators $> 0$).
|
||||
- When a computed “inner” argument to $\ln(\cdot)$ is $\le 0$ due to rounding, switch to a conservative branch (cap-and-invert) rather than continuing.
|
||||
|
||||
C. Additional figures and tables (to be included)
|
||||
- Price impact curves vs. constant-product and constant-mean baselines across $\kappa$.
|
||||
- Parameter sweeps for $\kappa$ and $S$ showing depth and slippage profiles.
|
||||
- Numerical accuracy: worst-case relative error heatmaps for prices and swap amounts; monotonicity checks.
|
||||
- Gas microbenchmarks: general path vs. balanced 2-asset approximations; cache effects.
|
||||
|
||||
D. Glossary and notation
|
||||
- $n$: number of assets.
|
||||
- $i, j$: asset indices in $\{0,\dots,n-1\}$.
|
||||
- $\mathbf{q}\in \mathbb{R}_{\ge 0}^{\,n}$: vector of normalized internal quantities; $q_i$ is the $i$-th component.
|
||||
- $S(\mathbf{q}) = \sum_i q_i$: size metric (aggregate pool size).
|
||||
- $\kappa > 0$: fixed liquidity proportionality constant.
|
||||
- $b(\mathbf{q}) = \kappa \cdot S(\mathbf{q})$: effective LMSR liquidity parameter.
|
||||
- $w_i = e^{q_i / b}$; $W = \sum_i w_i$.
|
||||
- $\pi_i = w_i / W$: price share (softmax probability).
|
||||
- $P(\text{base}\to\text{quote}) = \exp\!\big((q_{\text{quote}} - q_{\text{base}})/b\big)$: pairwise marginal price ratio.
|
||||
- $a$: exact-in input amount for asset $i$ (fee-free kernel).
|
||||
- $y$: exact-out output amount for asset $j$ (fee-free kernel).
|
||||
- $r_0 = \exp\!\big((q_i - q_j)/b\big)$: initial ratio for an $i\to j$ swap.
|
||||
- $\Lambda$: user-specified price limit (maximum acceptable $p_i/p_j$).
|
||||
- $\alpha$: proportional growth/redeem factor for liquidity operations.
|
||||
|
||||
E. References
|
||||
- Hanson, R. (2002). [Logarithmic Market Scoring Rules for Modular Combinatorial Information Aggregation.](https://mason.gmu.edu/~rhanson/mktscore.pdf)
|
||||
- Abernethy, J., Chen, Y., & Waggoner, B. (2013). Low-Regret Learning in Prediction Markets.
|
||||
- Uniswap (Hayden Adams et al.). Constant product market maker design docs and whitepapers.
|
||||
- Balancer. Constant mean market makers and multi-asset pool design notes.
|
||||
- Curve Finance. StableSwap invariant design notes.
|
||||
- Fixed-point arithmetic references and standard libraries for 64.64 computations.
|
||||
## Abstract
|
||||
We present a multi-asset automated market maker whose pricing kernel is the Logarithmic Market Scoring Rule (LMSR) ([R. Hanson, 2002](https://mason.gmu.edu/~rhanson/mktscore.pdf)). The pool maintains the convex potential $C(\mathbf{q}) = b(\mathbf{q}) \log\!\Big(\sum_i e^{q_i / b(\mathbf{q})}\Big)$ over normalized inventories $\mathbf{q}$, and sets the effective liquidity parameter proportional to pool size as $b(\mathbf{q}) = \kappa \, S(\mathbf{q})$ with $S(\mathbf{q}) = \sum_i q_i$ and fixed $\kappa>0$. This proportional parameterization preserves scale-invariant responsiveness while retaining softmax-derived pairwise price ratios under a quasi-static-$b$ view, enabling any-to-any swaps within a single potential. We derive and use closed-form expressions for two-asset reductions to compute exact-in, exact-out, limit-hitting (swap-to-limit), and capped-output trades. We discuss stability techniques such as log-sum-exp, ratio-once shortcuts, and domain guards for fixed-point arithmetic. Liquidity operations (proportional and single-asset joins/exits) follow directly from the same potential and admit monotone, invertible mappings. Parameters are immutable post-deployment for transparency and predictable depth calibration.
|
||||
|
||||
## Introduction and Motivation
|
||||
Multi-asset liquidity typically trades off simplicity and expressivity. Classical CFMMs define multiplicative invariants over reserves, while LMSR specifies a convex cost function whose gradient yields prices. Our goal is a multi-asset AMM that uses LMSR to support any-to-any swaps, shares risk across many assets, and scales depth predictably with pool size. By setting $b(\mathbf{q})=\kappa S(\mathbf{q})$, we achieve scale invariance: proportional rescaling of all balances scales $b$ proportionally and preserves pairwise price ratios, so the market’s responsiveness is consistent across liquidity regimes. The derivations below formulate instantaneous prices, closed-form swap mappings, limit logic, and liquidity operations tailored to this parameterization.
|
||||
|
||||
## System Model and Pricing Kernel
|
||||
We consider $n\ge 2$ normalized assets with state vector $\mathbf{q}=(q_0,\dots,q_{n-1})\in\mathbb{R}_{\ge 0}^{\,n}$ and size metric $S(\mathbf{q})=\sum_i q_i$. The kernel is the LMSR cost function
|
||||
$$
|
||||
C(\mathbf{q}) = b(\mathbf{q}) \log\!\left(\sum_{i=0}^{n-1} e^{q_i / b(\mathbf{q})}\right), \qquad b(\mathbf{q})=\kappa\,S(\mathbf{q}),\quad \kappa>0.
|
||||
$$
|
||||
For numerical stability we evaluate $C$ with a log-sum-exp recentering. Let $y_i := q_i/b(\mathbf{q})$ and $M:=\max_i y_i$. Then
|
||||
$$
|
||||
C(\mathbf{q}) \;=\; b(\mathbf{q}) \left( M + \log \sum_{i=0}^{n-1} e^{\,y_i - M} \right),
|
||||
$$
|
||||
which prevents overflow/underflow when the $y_i$ are dispersed. Quantities are represented in fixed-point with explicit range and domain guards; equations are presented over the reals for clarity.
|
||||
|
||||
## Gradient, Price Shares, and Pairwise Prices
|
||||
With $b$ treated as a constant parameter, the LMSR gradient recovers softmax shares
|
||||
$$
|
||||
\frac{\partial C}{\partial q_i} \;=\; \frac{e^{q_i/b}}{\sum_k e^{q_k/b}} \;=:\; \pi_i(\mathbf{q}),
|
||||
$$
|
||||
so that the ratio of marginal prices is $\pi_j/\pi_i = \exp\!\big((q_j-q_i)/b\big)$. When $b(\mathbf{q})=\kappa S(\mathbf{q})$ depends on state, $\frac{\partial C}{\partial q_i}$ acquires a common additive term across $i$ from $\partial b/\partial q_i$, but pairwise ratios remain governed by softmax differences. We therefore use a quasi-static-$b$ view for pricing steps, holding $b$ fixed at the pre-trade state for the infinitesimal move, and define the instantaneous pairwise marginal price ratio for exchanging $i$ into $j$ as
|
||||
$$
|
||||
P(i\to j \mid \mathbf{q}) \;=\; \exp\!\left(\frac{q_j - q_i}{b(\mathbf{q})}\right).
|
||||
$$
|
||||
This ratio drives swap computations and is invariant to proportional rescaling $\mathbf{q}\mapsto \lambda\mathbf{q}$ because $b$ scales by the same factor.
|
||||
|
||||
## Two-Asset Reduction and Exact Swap Mappings
|
||||
Swaps are computed in the two-asset subspace spanned by the in-asset $i$ and out-asset $j$, with all other coordinates held fixed under a quasi-static-$b$ step. Let
|
||||
$$
|
||||
r_0 \;:=\; \exp\!\left(\frac{q_i - q_j}{b}\right), \qquad b \equiv b(\mathbf{q})\;\text{ held quasi-static}.
|
||||
$$
|
||||
Along the $i\!\to\! j$ path, the instantaneous ratio evolves multiplicatively as $r(t)=r_0\,e^{t/b}$ where $t$ denotes cumulative input of asset $i$. In the two-asset reduction the infinitesimal output satisfies
|
||||
$$
|
||||
\mathrm{d}y \;=\; \frac{r(t)}{1+r(t)}\,\mathrm{d}t.
|
||||
$$
|
||||
Integrating from $t=0$ to $t=a$ yields the exact-in closed form
|
||||
$$
|
||||
y(a) \;=\; b \,\ln\!\Big( 1 + r_0 \,\big(1 - e^{-a/b}\big) \Big).
|
||||
$$
|
||||
This mapping has $y(0)=0$, is strictly increasing and concave in $a$, and satisfies $y'(0)=\frac{r_0}{1+r_0}$ with asymptote $\lim_{a\to\infty} y = b\,\ln(1+r_0)$. The inverse exact-out mapping follows by solving for $a$ in terms of target $y$. Writing $E:=e^{y/b}$, we obtain
|
||||
$$
|
||||
a(y) \;=\; b \,\ln\!\left(\frac{r_0}{\,r_0 + 1 - E\,}\right),
|
||||
$$
|
||||
which is strictly increasing and convex for $y\in\big[0,\, b\ln(1+r_0)\big]$. These two expressions are the workhorses for exact-in and exact-out swaps in our kernel.
|
||||
|
||||
## Price Limits, Swap-to-Limit, and Capacity Caps
|
||||
Users may provide a maximum acceptable marginal price ratio $\Lambda>0$ for $p_i/p_j$. The marginal ratio trajectory $r(t)=r_0 e^{t/b}$ first reaches the limit at the unique
|
||||
$$
|
||||
a_{\text{lim}} \;=\; b \,\ln\!\left(\frac{\Lambda}{r_0}\right),
|
||||
$$
|
||||
and the output realized at that truncation is
|
||||
$$
|
||||
y_{\text{lim}} \;=\; b \,\ln\!\Big( 1 + r_0 \,\big(1 - r_0/\Lambda\big) \Big).
|
||||
$$
|
||||
Outputs are further bounded by available inventory; if a computed $y$ would exceed $q_j$, we cap at $y=q_j$ and compute the implied input by inverting the exact-out formula,
|
||||
$$
|
||||
a_{\text{cap}} \;=\; b \,\ln\!\left(\frac{r_0}{\,r_0 + 1 - e^{\,q_j/b}\,}\right).
|
||||
$$
|
||||
These limit and capacity branches ensure monotone, conservative behavior near domain edges.
|
||||
|
||||
## Liquidity Operations from the Same Potential
|
||||
Liquidity is accounted via pool shares $L$ taken proportional to the size metric, and we set $L=S(\mathbf{q})$ without loss of generality. At initialization with seed balances $\mathbf{q}^{(0)}$ the pool sets $L^{(0)}=S^{(0)}$ and $b^{(0)}=\kappa S^{(0)}$. A proportional deposit that scales balances to $\mathbf{q}'=(1+\alpha)\mathbf{q}$ mints $\Delta L = \alpha S(\mathbf{q})$ shares and scales liquidity to $b'=(1+\alpha)b$. Single-asset deposits target a proportional growth while rebalancing through kernel swaps: providing amount $a$ of asset $i$ induces a growth factor $\alpha\ge 0$ satisfying the monotone equation
|
||||
$$
|
||||
a \;=\; a_{\text{req}}(\alpha) \;=\; \alpha q_i \;+\; \sum_{j\ne i} b \,\ln\!\left(\frac{r_{0,j}}{\,r_{0,j} + 1 - e^{\,\alpha q_j/b}\,}\right), \quad r_{0,j}:=\exp\!\left(\frac{q_i-q_j}{b}\right),
|
||||
$$
|
||||
and mints $\Delta L=\alpha S(\mathbf{q})$ upon the unique solution. Proportional withdrawals burn $\Delta L$ and return $\alpha=\Delta L/S(\mathbf{q})$ of each asset, updating $b$ to $(1-\alpha)b$. Single-asset withdrawals redeem $\alpha q_i$ directly and swap each redeemed $\alpha q_j$ for $j\ne i$ into $i$ using the exact-in mapping evaluated on the local post-burn state; any capacity overrun is handled by a cap-and-invert branch as above. Because all operations reduce to the same two-asset closed forms, they inherit monotonicity and uniqueness.
|
||||
|
||||
### Single-Asset Mint and Redeem
|
||||
|
||||
#### Single-Asset Mint
|
||||
Given a deposit of amount $a>0$ of asset $i$, the pool targets a proportional growth factor $\alpha \ge 0$ so that the post-mint state can be rebalanced to $(1+\alpha)\,\mathbf{q}$ using fee-free kernel swaps from $i$ into each $j\ne i$. For each $j\ne i$, let $y_j := \alpha\,q_j$ and define $r_{0,j} := \exp\!\big((q_i - q_j)/b\big)$. The input required to realize $y_j$ via the exact-out inverse is
|
||||
$$
|
||||
x_j(\alpha) \;=\; b \,\ln\!\left(\frac{r_{0,j}}{\,r_{0,j} + 1 - e^{\,y_j/b}\,}\right),
|
||||
$$
|
||||
so the total required input for growth $\alpha$ is
|
||||
$$
|
||||
a_{\text{req}}(\alpha) \;=\; \alpha\,q_i \;+\; \sum_{j\ne i} x_j(\alpha).
|
||||
$$
|
||||
Properties and solver:
|
||||
- Monotonicity: $a_{\text{req}}(\alpha)$ is strictly increasing on its feasible domain, guaranteeing a unique solution.
|
||||
- Solver: bracket $\alpha$ (e.g., start from $\alpha\sim a/S$ and double until $a_{\text{req}}(\alpha)\ge a$ or a safety cap), then bisection to a small tolerance $\varepsilon$ (e.g., $\sim10^{-6}$ in fixed-point units).
|
||||
- Guards: enforce $b>0$, $e^{y_j/b}$ within range, and positivity of the denominator $r_{0,j}+1-e^{y_j/b}$; if a guard would be violated for some $j$, treat that path as infeasible and adjust the bracket.
|
||||
- Outcome: the consumed input is $a_{\text{in}} = a_{\text{req}}(\alpha^\star) \le a$ and minted LP shares are $\Delta L = \alpha^\star S(\mathbf{q})$.
|
||||
|
||||
#### Single-Asset Redeem
|
||||
Burning a proportional share $\alpha \in (0,1]$ returns a single asset $i$ by redeeming and rebalancing from other assets into $i$:
|
||||
1) Form the local state after burn, $\mathbf{q}_{\text{local}}=(1-\alpha)\,\mathbf{q}$.
|
||||
2) Start with the direct redemption $\alpha\,q_i$ in asset $i$.
|
||||
3) For each $j\ne i$, withdraw $a_j := \alpha\,q_j$ and swap $j\to i$ using the exact-in form evaluated at $\mathbf{q}_{\text{local}}$:
|
||||
$$
|
||||
r_{0,j} \;=\; \exp\!\left(\frac{q^{\text{local}}_j - q^{\text{local}}_i}{b}\right),\qquad
|
||||
y_{j\to i} \;=\; b \,\ln\!\Big(1 + r_{0,j}\,\big(1 - e^{-a_j/b}\big)\Big).
|
||||
$$
|
||||
4) Capacity cap and inverse: if $y_{j\to i} > q^{\text{local}}_i$, cap to $y=q^{\text{local}}_i$ and solve the implied input via
|
||||
$$
|
||||
a_{j,\text{used}} \;=\; b \,\ln\!\left(\frac{r_{0,j}}{\,r_{0,j} + 1 - e^{\,q^{\text{local}}_i/b}\,}\right),
|
||||
$$
|
||||
then update $\mathbf{q}_{\text{local}}$ accordingly.
|
||||
5) The single-asset payout is
|
||||
$$
|
||||
Y_i \;=\; \alpha\,q_i \;+\; \sum_{j\ne i} y_{j\to i}, \qquad \text{with LP burned } L_{\text{in}} = \alpha \, S(\mathbf{q}).
|
||||
$$
|
||||
Guards and behavior:
|
||||
- Enforce $b>0$, positivity of inner terms (e.g., $r_{0,j} + 1 - e^{y/b} > 0$), and safe exponent ranges; treat any per-asset numerical failure as zero contribution rather than aborting the whole redeem.
|
||||
- The mapping is monotone in $\alpha$; the cap-and-invert branch preserves safety near capacity.
|
||||
|
||||
### LP Pricing vs. an Asset Token
|
||||
With LP supply set to $L=S(\mathbf{q})$, the instantaneous price of one LP share in units of asset $k$ aggregates marginal exchange rates from each asset into $k$:
|
||||
$$
|
||||
P_L^{(k)}(\mathbf{q}) \;=\; \frac{1}{S(\mathbf{q})}\,\sum_{j=0}^{n-1} q_j \,\exp\!\left(\frac{q_j - q_k}{b(\mathbf{q})}\right).
|
||||
$$
|
||||
Interpretation: proportional deposits leave $P_L^{(k)}$ unchanged; swap fees retained in the pool increase $S$ relative to outstanding $L$, raising $P_L^{(k)}$ (implicit fee accrual). This expression helps LPs and integrators reason about share valuation and dilution across assets.
|
||||
|
||||
## Numerical Methods and Safety Guarantees
|
||||
We evaluate log-sum-exp with recentring, compute ratios like $r_0=\exp((q_i-q_j)/b)$ directly rather than dividing exponentials, and guard all $\exp$ and $\ln$ calls to bounded domains with explicit checks on positivity of inner terms such as $r_0+1-e^{y/b}$. Fixed-point implementations precompute reciprocals like $1/b$ to reduce dispersion, clamp to capacity before inversion, and select cap-and-invert rather than extrapolating when inner terms approach zero. These measures ensure the swap maps remain strictly order-preserving and free of nonphysical outputs. Property-based and differential testing can confirm monotonicity of $y(a)$ and $a(y)$, uniqueness of limit hits when $\Lambda>r_0$, and adherence to predefined error budgets.
|
||||
|
||||
## Balanced Regime Optimization: Approximations, Dispatcher, and Stability
|
||||
Since transcendental operations are gas-expensive on EVM chains, we use polynomial approximations in near-balanced regimes (e.g., stable-asset pairs) while preserving monotonicity and domain safety. Parameterize $\delta := (q_i - q_j)/b$ and $\tau := a/b$ for an $i\!\to\! j$ exact-in step. The exact mapping
|
||||
$$
|
||||
y(a) \;=\; b \,\ln\!\Big(1 + e^{\delta}\,\big(1 - e^{-\tau}\big)\Big)
|
||||
$$
|
||||
admits small-argument expansions for $|\delta|\ll 1$ and $|\tau|\ll 1$. Using $e^{\pm x}\approx 1\pm x+\tfrac{x^2}{2}$ and $\ln(1+u)\approx u - \tfrac{u^2}{2}$, we obtain
|
||||
$$
|
||||
y(a) \;\approx\; b \left[ r_0 \tau - \tfrac{1}{2} r_0 \tau^2 \right] + \mathcal{O}\!\left(\tau^3,\, |\delta|\,\tau^2\right), \qquad r_0=e^{\delta}\approx 1+\delta+\tfrac{\delta^2}{2},
|
||||
$$
|
||||
and at $\delta=0$ the symmetry reduces to $y(a)\approx \tfrac{a}{2} - \tfrac{a^2}{4b} + \cdots$.
|
||||
|
||||
### Dispatcher preconditions and thresholds (approx path):
|
||||
- Scope: two-asset pools only; otherwise use the exact path.
|
||||
- Magnitude bounds: $|\delta| \le 0.01$ and $\tau := a/b$ satisfies $0 < \tau \le 0.5$.
|
||||
- Tiering: use the quadratic surrogate for $\tau \le 0.1$, and include a cubic correction for $0.1 < \tau \le 0.5$.
|
||||
- Limit-price gate: approximate the limit truncation only when a positive limit is provided with $\Lambda>r_0$ and $|(\Lambda/r_0)-1| \le 0.1$; otherwise compute the limit exactly (or reject if $\Lambda \le r_0$).
|
||||
- Capacity and positivity: require $b>0$ and $a>0$, and ensure the approximated output $\tilde{y}(a) \le q_j$; otherwise fall back to the exact cap-and-invert.
|
||||
- Example thresholds: $\delta_\star=0.01$, $\tau_{\text{tier1}}=0.1$, $\tau_\star=0.5$, and an auxiliary limit-ratio gate $|x| \le 0.1$ where $x=(\Lambda/r_0)-1$ (for reference, $e^{\delta_\star}\approx 1.01005$).
|
||||
|
||||
### Approximation Path
|
||||
- Replace $\exp$ on the bounded $\tau$ domain and $\ln(1+\cdot)$ with verified polynomials to meet a global error budget while maintaining $\tilde{y}'(a)>0$ on the domain.
|
||||
- Cache common subexpressions (e.g., $r_0=e^\delta$, $\tau=a/b$) and guard inner terms to remain in $(0,\infty)$.
|
||||
|
||||
### Fallback Policy
|
||||
- If any precondition fails (magnitude, domain, capacity, or limit binding), evaluate the exact closed forms for $y(a)$ or $a(y)$ (with cap and limit branches), preserving monotonicity and uniqueness.
|
||||
- Prefer cap-and-invert near capacity or when the inner term of $\ln(\cdot)$ approaches zero.
|
||||
|
||||
### Error Shape
|
||||
- The small-argument expansion above shows the leading behavior; when using polynomial surrogates, the composed relative error can be kept within a target $\epsilon$ with degrees chosen for the specified $(\delta_\star,\tau_\star,u_\star)$, yielding an error budget of the form $\epsilon \approx \epsilon_{\exp} + \epsilon_{\ln} + c_1 \tau_\star + c_2 |\delta_\star| \tau_\star$ for modest constants $c_1,c_2$.
|
||||
- These bounds ensure the approximated path remains order-preserving and safely within domain; outside the domain, the dispatcher reverts to the exact path.
|
||||
- Regardless of path, our policy prioritizes monotonicity, domain safety, and conservative decisions at boundaries.
|
||||
|
||||
## Fees and Economic Considerations
|
||||
Swap fees are applied outside the fee-free kernel. For an exact-in submission $a$ on asset $i$, the effective kernel input is $a_{\text{eff}}=(1-f_{\text{swap}})a$. The kernel computes output using $a_{\text{eff}}$, while the retained fee remains in the pool, increasing $S(\mathbf{q})$ relative to outstanding $L$ and thereby accruing value to LPs implicitly. Scale invariance under $b=\kappa S$ implies that proportional growth of inventories preserves price ratios while deepening notional liquidity linearly. The classical LMSR bounded-loss intuition for constant $b$ gives $b\ln n$ in appropriate units; under our proportional $b$, this scales with $S$, so the instantaneous bound per unit of $S$ is proportional to $\kappa\ln n$.
|
||||
|
||||
## Risk Management and Bounded Loss
|
||||
Under constant $b$, classical LMSR admits a worst-case loss bound of $b \ln n$ in the payoff numéraire. With $b(\mathbf{q})=\kappa S(\mathbf{q})$, the per-state bound scales with the current size metric, giving an instantaneous worst-case loss $b(\mathbf{q}) \ln n = \kappa\,S(\mathbf{q})\,\ln n$; per unit of size $S$ this is $\kappa \ln n$. Because $b$ varies with state, global worst-case loss along an arbitrary path depends on how $S$ evolves, but the proportionality clarifies how risk scales with liquidity. Operational mitigations include user price limits (swap-to-limit), capacity caps on outputs ($y \le q_j$), minimum bootstrap $S^{(0)}$ to avoid thin-liquidity regimes, and strict numerical guards (e.g., positivity of inner logarithm arguments) to prevent nonphysical states.
|
||||
|
||||
## Deployment and Parameter Fixity
|
||||
The parameter tuple $(\kappa, f_{\text{swap}}, \phi)$ is set at deployment and remains immutable, with $\kappa>0$ defining $b(\mathbf{q})=\kappa S(\mathbf{q})$, $f_{\text{swap}}$ the swap fee rate, and $\phi$ the protocol share of fees. Given the initial state $\mathbf{q}^{(0)}$ with $S^{(0)}>0$, the induced pricing map is fully determined by
|
||||
$$
|
||||
C(\mathbf{q}) = b(\mathbf{q}) \log\!\left(\sum_i e^{q_i / b(\mathbf{q})}\right), \qquad b(\mathbf{q})=\kappa S(\mathbf{q}),
|
||||
$$
|
||||
and the two-asset closed forms above. Fixity eliminates governance risk, makes depth calibration transparent, and simplifies integration for external routers and valuation tools.
|
||||
|
||||
## Conclusion
|
||||
By coupling LMSR with the proportional parameterization $b(\mathbf{q})=\kappa S(\mathbf{q})$, we obtain a multi-asset AMM that preserves softmax-driven price ratios under a quasi-static-$b$ view and supports any-to-any swaps via a single convex potential. Exact two-asset reductions yield closed-form mappings for exact-in, exact-out, limit-hitting, and capped-output trades, and the same formulas underpin liquidity operations with monotonicity and uniqueness. Numerical stability follows from log-sum-exp evaluation, ratio-first derivations, guarded transcendental domains, and optional near-balance approximations, while fixed parameters provide predictable scaling and transparent economics.
|
||||
|
||||
## References
|
||||
Hanson, R. (2002) [_Logarithmic Market Scoring Rules for Modular Combinatorial Information Aggregation_](https://mason.gmu.edu/~rhanson/mktscore.pdf)
|
||||
|
||||
@@ -1,100 +0,0 @@
|
||||
# LMSR-based Multi-Asset AMM
|
||||
|
||||
Abstract
|
||||
We present a multi-asset automated market maker whose pricing kernel is the Logarithmic Market Scoring Rule (LMSR). The pool maintains the convex potential $C(\mathbf{q}) = b(\mathbf{q}) \log\!\Big(\sum_i e^{q_i / b(\mathbf{q})}\Big)$ over normalized inventories $\mathbf{q}$, and sets the effective liquidity parameter proportional to pool size as $b(\mathbf{q}) = \kappa \, S(\mathbf{q})$ with $S(\mathbf{q}) = \sum_i q_i$ and fixed $\kappa>0$. This proportional parameterization preserves scale-invariant responsiveness while retaining softmax-derived pairwise price ratios under a quasi-static-$b$ view, enabling any-to-any swaps within a single potential. We derive and use closed-form expressions for two-asset reductions to compute exact-in, exact-out, limit-hitting (swap-to-limit), and capped-output trades. We discuss stability techniques such as log-sum-exp, ratio-once shortcuts, and domain guards for fixed-point arithmetic. Liquidity operations (proportional and single-asset joins/exits) follow directly from the same potential and admit monotone, invertible mappings. Parameters are immutable post-deployment for transparency and predictable depth calibration.
|
||||
|
||||
Introduction and Motivation
|
||||
Multi-asset liquidity typically trades off simplicity and expressivity. Classical CFMMs define multiplicative invariants over reserves, while LMSR specifies a convex cost function whose gradient yields prices. Our goal is a multi-asset AMM that uses LMSR to support any-to-any swaps, shares risk across many assets, and scales depth predictably with pool size. By setting $b(\mathbf{q})=\kappa S(\mathbf{q})$, we achieve scale invariance: proportional rescaling of all balances scales $b$ proportionally and preserves pairwise price ratios, so the market’s responsiveness is consistent across liquidity regimes. The derivations below formulate instantaneous prices, closed-form swap mappings, limit logic, and liquidity operations tailored to this parameterization.
|
||||
|
||||
System Model and Pricing Kernel
|
||||
We consider $n\ge 2$ normalized assets with state vector $\mathbf{q}=(q_0,\dots,q_{n-1})\in\mathbb{R}_{\ge 0}^{\,n}$ and size metric $S(\mathbf{q})=\sum_i q_i$. The kernel is the LMSR cost function
|
||||
$$
|
||||
C(\mathbf{q}) = b(\mathbf{q}) \log\!\left(\sum_{i=0}^{n-1} e^{q_i / b(\mathbf{q})}\right), \qquad b(\mathbf{q})=\kappa\,S(\mathbf{q}),\quad \kappa>0.
|
||||
$$
|
||||
For numerical stability we evaluate $C$ with a log-sum-exp recentering. Let $y_i := q_i/b(\mathbf{q})$ and $M:=\max_i y_i$. Then
|
||||
$$
|
||||
C(\mathbf{q}) \;=\; b(\mathbf{q}) \left( M + \log \sum_{i=0}^{n-1} e^{\,y_i - M} \right),
|
||||
$$
|
||||
which prevents overflow/underflow when the $y_i$ are dispersed. Quantities are represented in fixed-point with explicit range and domain guards; equations are presented over the reals for clarity.
|
||||
|
||||
Gradient, Price Shares, and Pairwise Prices
|
||||
With $b$ treated as a constant parameter, the LMSR gradient recovers softmax shares
|
||||
$$
|
||||
\frac{\partial C}{\partial q_i} \;=\; \frac{e^{q_i/b}}{\sum_k e^{q_k/b}} \;=:\; \pi_i(\mathbf{q}),
|
||||
$$
|
||||
so that the ratio of marginal prices is $\pi_j/\pi_i = \exp\!\big((q_j-q_i)/b\big)$. When $b(\mathbf{q})=\kappa S(\mathbf{q})$ depends on state, $\frac{\partial C}{\partial q_i}$ acquires a common additive term across $i$ from $\partial b/\partial q_i$, but pairwise ratios remain governed by softmax differences. We therefore use a quasi-static-$b$ view for pricing steps, holding $b$ fixed at the pre-trade state for the infinitesimal move, and define the instantaneous pairwise marginal price ratio for exchanging $i$ into $j$ as
|
||||
$$
|
||||
P(i\to j \mid \mathbf{q}) \;=\; \exp\!\left(\frac{q_j - q_i}{b(\mathbf{q})}\right).
|
||||
$$
|
||||
This ratio drives swap computations and is invariant to proportional rescaling $\mathbf{q}\mapsto \lambda\mathbf{q}$ because $b$ scales by the same factor.
|
||||
|
||||
Two-Asset Reduction and Exact Swap Mappings
|
||||
Swaps are computed in the two-asset subspace spanned by the in-asset $i$ and out-asset $j$, with all other coordinates held fixed under a quasi-static-$b$ step. Let
|
||||
$$
|
||||
r_0 \;:=\; \exp\!\left(\frac{q_i - q_j}{b}\right), \qquad b \equiv b(\mathbf{q})\;\text{ held quasi-static}.
|
||||
$$
|
||||
Along the $i\!\to\! j$ path, the instantaneous ratio evolves multiplicatively as $r(t)=r_0\,e^{t/b}$ where $t$ denotes cumulative input of asset $i$. In the two-asset reduction the infinitesimal output satisfies
|
||||
$$
|
||||
\mathrm{d}y \;=\; \frac{r(t)}{1+r(t)}\,\mathrm{d}t.
|
||||
$$
|
||||
Integrating from $t=0$ to $t=a$ yields the exact-in closed form
|
||||
$$
|
||||
y(a) \;=\; b \,\ln\!\Big( 1 + r_0 \,\big(1 - e^{-a/b}\big) \Big).
|
||||
$$
|
||||
This mapping has $y(0)=0$, is strictly increasing and concave in $a$, and satisfies $y'(0)=\frac{r_0}{1+r_0}$ with asymptote $\lim_{a\to\infty} y = b\,\ln(1+r_0)$. The inverse exact-out mapping follows by solving for $a$ in terms of target $y$. Writing $E:=e^{y/b}$, we obtain
|
||||
$$
|
||||
a(y) \;=\; b \,\ln\!\left(\frac{r_0}{\,r_0 + 1 - E\,}\right),
|
||||
$$
|
||||
which is strictly increasing and convex for $y\in\big[0,\, b\ln(1+r_0)\big]$. These two expressions are the workhorses for exact-in and exact-out swaps in our kernel.
|
||||
|
||||
Price Limits, Swap-to-Limit, and Capacity Caps
|
||||
Users may provide a maximum acceptable marginal price ratio $\Lambda>0$ for $p_i/p_j$. The marginal ratio trajectory $r(t)=r_0 e^{t/b}$ first reaches the limit at the unique
|
||||
$$
|
||||
a_{\text{lim}} \;=\; b \,\ln\!\left(\frac{\Lambda}{r_0}\right),
|
||||
$$
|
||||
and the output realized at that truncation is
|
||||
$$
|
||||
y_{\text{lim}} \;=\; b \,\ln\!\Big( 1 + r_0 \,\big(1 - r_0/\Lambda\big) \Big).
|
||||
$$
|
||||
Outputs are further bounded by available inventory; if a computed $y$ would exceed $q_j$, we cap at $y=q_j$ and compute the implied input by inverting the exact-out formula,
|
||||
$$
|
||||
a_{\text{cap}} \;=\; b \,\ln\!\left(\frac{r_0}{\,r_0 + 1 - e^{\,q_j/b}\,}\right).
|
||||
$$
|
||||
These limit and capacity branches ensure monotone, conservative behavior near domain edges.
|
||||
|
||||
Liquidity Operations from the Same Potential
|
||||
Liquidity is accounted via pool shares $L$ taken proportional to the size metric, and we set $L=S(\mathbf{q})$ without loss of generality. At initialization with seed balances $\mathbf{q}^{(0)}$ the pool sets $L^{(0)}=S^{(0)}$ and $b^{(0)}=\kappa S^{(0)}$. A proportional deposit that scales balances to $\mathbf{q}'=(1+\alpha)\mathbf{q}$ mints $\Delta L = \alpha S(\mathbf{q})$ shares and scales liquidity to $b'=(1+\alpha)b$. Single-asset deposits target a proportional growth while rebalancing through kernel swaps: providing amount $a$ of asset $i$ induces a growth factor $\alpha\ge 0$ satisfying the monotone equation
|
||||
$$
|
||||
a \;=\; a_{\text{req}}(\alpha) \;=\; \alpha q_i \;+\; \sum_{j\ne i} b \,\ln\!\left(\frac{r_{0,j}}{\,r_{0,j} + 1 - e^{\,\alpha q_j/b}\,}\right), \quad r_{0,j}:=\exp\!\left(\frac{q_i-q_j}{b}\right),
|
||||
$$
|
||||
and mints $\Delta L=\alpha S(\mathbf{q})$ upon the unique solution. Proportional withdrawals burn $\Delta L$ and return $\alpha=\Delta L/S(\mathbf{q})$ of each asset, updating $b$ to $(1-\alpha)b$. Single-asset withdrawals redeem $\alpha q_i$ directly and swap each redeemed $\alpha q_j$ for $j\ne i$ into $i$ using the exact-in mapping evaluated on the local post-burn state; any capacity overrun is handled by a cap-and-invert branch as above. Because all operations reduce to the same two-asset closed forms, they inherit monotonicity and uniqueness.
|
||||
|
||||
Fees and Economic Considerations
|
||||
Swap fees are applied outside the fee-free kernel. For an exact-in submission $a$ on asset $i$, the effective kernel input is $a_{\text{eff}}=(1-f_{\text{swap}})a$. The kernel computes output using $a_{\text{eff}}$, while the retained fee remains in the pool, increasing $S(\mathbf{q})$ relative to outstanding $L$ and thereby accruing value to LPs implicitly. Scale invariance under $b=\kappa S$ implies that proportional growth of inventories preserves price ratios while deepening notional liquidity linearly. The classical LMSR bounded-loss intuition for constant $b$ gives $b\ln n$ in appropriate units; under our proportional $b$, this scales with $S$, so the instantaneous bound per unit of $S$ is proportional to $\kappa\ln n$.
|
||||
|
||||
Balanced Regime, Approximations, and Stability
|
||||
Near balance it is useful to parameterize $\delta := (q_i - q_j)/b$ and $\tau := a/b$. The exact mapping
|
||||
$$
|
||||
y(a) \;=\; b \,\ln\!\Big(1 + e^{\delta}\,\big(1 - e^{-\tau}\big)\Big)
|
||||
$$
|
||||
admits small-argument expansions when $|\delta|\ll 1$ and $|\tau|\ll 1$. Using $e^{\pm x}\approx 1\pm x+\tfrac{x^2}{2}$ and $\ln(1+u)\approx u - \tfrac{u^2}{2}$, we obtain
|
||||
$$
|
||||
y(a) \;\approx\; b \left[ r_0 \tau - \frac{1}{2} r_0 \tau^2 \right] + \mathcal{O}\!\left(\tau^3,\, |\delta|\,\tau^2\right), \qquad r_0=e^{\delta}\approx 1+\delta+\tfrac{\delta^2}{2},
|
||||
$$
|
||||
and at $\delta=0$ the symmetry reduces to $y(a)\approx \tfrac{a}{2} - \tfrac{a^2}{4b} + \cdots$. In designated near-balance domains one may replace $\exp$ and $\ln$ with verified polynomial approximations to reduce computational cost while maintaining monotonicity and bounded error; a dispatcher enforces preconditions on $|\delta|$, $|a|/b$, and positivity of inner arguments, otherwise falling back to the exact forms. Regardless of path, our numerical policy prioritizes monotonicity, domain safety, and conservative branches at decision boundaries.
|
||||
|
||||
Numerical Methods and Safety Guarantees
|
||||
We evaluate log-sum-exp with recentring, compute ratios like $r_0=\exp((q_i-q_j)/b)$ directly rather than dividing exponentials, and guard all $\exp$ and $\ln$ calls to bounded domains with explicit checks on positivity of inner terms such as $r_0+1-e^{y/b}$. Fixed-point implementations precompute reciprocals like $1/b$ to reduce dispersion, clamp to capacity before inversion, and select cap-and-invert rather than extrapolating when inner terms approach zero. These measures ensure the swap maps remain strictly order-preserving and free of nonphysical outputs. Property-based and differential testing can confirm monotonicity of $y(a)$ and $a(y)$, uniqueness of limit hits when $\Lambda>r_0$, and adherence to predefined error budgets.
|
||||
|
||||
Deployment and Parameter Fixity
|
||||
The parameter tuple $(\kappa, f_{\text{swap}}, \phi)$ is set at deployment and remains immutable, with $\kappa>0$ defining $b(\mathbf{q})=\kappa S(\mathbf{q})$, $f_{\text{swap}}$ the swap fee rate, and $\phi$ the protocol share of fees. Given the initial state $\mathbf{q}^{(0)}$ with $S^{(0)}>0$, the induced pricing map is fully determined by
|
||||
$$
|
||||
C(\mathbf{q}) = b(\mathbf{q}) \log\!\left(\sum_i e^{q_i / b(\mathbf{q})}\right), \qquad b(\mathbf{q})=\kappa S(\mathbf{q}),
|
||||
$$
|
||||
and the two-asset closed forms above. Fixity eliminates governance risk, makes depth calibration transparent, and simplifies integration for external routers and valuation tools.
|
||||
|
||||
Conclusion
|
||||
By coupling LMSR with the proportional parameterization $b(\mathbf{q})=\kappa S(\mathbf{q})$, we obtain a multi-asset AMM that preserves softmax-driven price ratios under a quasi-static-$b$ view and supports any-to-any swaps via a single convex potential. Exact two-asset reductions yield closed-form mappings for exact-in, exact-out, limit-hitting, and capped-output trades, and the same formulas underpin liquidity operations with monotonicity and uniqueness. Numerical stability follows from log-sum-exp evaluation, ratio-first derivations, guarded transcendental domains, and optional near-balance approximations, while fixed parameters provide predictable scaling and transparent economics.
|
||||
|
||||
References
|
||||
Hanson, R. (2002). Logarithmic Market Scoring Rules for Modular Combinatorial Information Aggregation. https://mason.gmu.edu/~rhanson/mktscore.pdf
|
||||
Reference in New Issue
Block a user