Related papers: The Limits of Lognormal: Assessing Cryptocurrency Volatility and VaR using Geometric Brownian Motion

The Limits of Lognormal: Assessing Cryptocurrency Volatility and VaR using Geometric Brownian Motion

URL: http://arxiv.org/abs/2601.14272v1
Date: Fri, 09 Jan 2026 05:14:16 GMT
Title: The Limits of Lognormal: Assessing Cryptocurrency Volatility and VaR using Geometric Brownian Motion
Authors: Ekleen Kaur,
Abstract summary: This study is a part of a series of subsequent works to fine-tune model risk analysis for cryptocurrencies.<n>We establish a foundational benchmark by applying the traditional industry-standard Geometric Brownian Motion (GBM) model.<n>Results reveal limitations of the Lognormal assumption: the calculated Value-at-Risk at the 5% confidence level over the one-year horizon.
Score: 0.0
License: http://creativecommons.org/licenses/by-sa/4.0/
Abstract: The integration of cryptocurrencies into institutional portfolios necessitates the adoption of robust risk modeling frameworks. This study is a part of a series of subsequent works to fine-tune model risk analysis for cryptocurrencies. Through this first research work, we establish a foundational benchmark by applying the traditional industry-standard Geometric Brownian Motion (GBM) model. Popularly used for non-crypto financial assets, GBM assumes Lognormal return distributions for a multi-asset cryptocurrency portfolio (XRP, SOL, ADA). This work utilizes Maximum Likelihood Estimation and a correlated Monte Carlo Simulation incorporating the Cholesky decomposition of historical covariance. We present our stock portfolio model as a Minimum Variance Portfolio (MVP). We observe the model's structural shift within the heavy-tailed, non-Gaussian cryptocurrency environment. The results reveal limitations of the Lognormal assumption: the calculated Value-at-Risk at the 5% confidence level over the one-year horizon. For baselining our results, we also present a holistic comparative analysis with an equity portfolio (AAPL, TSLA, NVDA), demonstrating a significantly lower failure rate. This performance provides conclusive evidence that the GBM model is fundamentally the perfect benchmark for our subsequent works. Results from this novel work will be an indicator for the success criteria in our future model for crypto risk management, rigorously motivating the development and application of advanced models.

Related papers

The Limits of Conditional Volatility: Assessing Cryptocurrency VaR under EWMA and IGARCH Models [0.0]
The application of the standard static Geometric Brownian Motion (GBM) model for cryptocurrency risk management resulted in a systemic failure.<n>This study addresses a critical literature gap by comparatively testing three conditional volatility models the EWMA/IGARCH baseline, an IGARCH model augmented with explicit mean reversion (IGARCH + MR), and a modified EGARCH-style asymmetric shock model within a correlated Monte Carlo VaR framework.<n>Our results demonstrate that imposing stationarity drastically underestimates downside risk (5 percent value-at-risk reduced by 50%), while the asymmetric model (Model 3) leads to severe over-penalization.
arXiv Detail & Related papers (2026-01-20T09:11:24Z)
CryptoBench: A Dynamic Benchmark for Expert-Level Evaluation of LLM Agents in Cryptocurrency [60.83660377169452]
This paper introduces CryptoBench, the first expert-curated, dynamic benchmark designed to rigorously evaluate the real-world capabilities of Large Language Model (LLM) agents.<n>Unlike general-purpose agent benchmarks for search and prediction, professional crypto analysis presents specific challenges.
arXiv Detail & Related papers (2025-11-29T09:52:34Z)
Building crypto portfolios with agentic AI [46.348283638884425]
The rapid growth of crypto markets has opened new opportunities for investors, but at the same time exposed them to high volatility.<n>This paper presents a practical application of a multi-agent system designed to autonomously construct and evaluate crypto-asset allocations.
arXiv Detail & Related papers (2025-07-11T18:03:51Z)
crypto price prediction using lstm+xgboost [0.0]
This research proposes a hybrid deep learning and machine learning model that integrates Long Short-Term Memory (LSTM) networks and Extreme Gradient Boosting (XGBoost) for cryptocurrency price prediction.<n>The LSTM component captures temporal dependencies in historical price data, while XGBoost enhances prediction by modeling nonlinear relationships with auxiliary features such as sentiment scores and macroeconomic indicators.<n>The model is evaluated on historical datasets of Bitcoin, Dogecoin, and Litecoin, incorporating both global and localized exchange data.
arXiv Detail & Related papers (2025-06-27T09:49:25Z)
CryptoMamba: Leveraging State Space Models for Accurate Bitcoin Price Prediction [28.15955243872829]
We propose CryptoMamba, a novel Mamba-based State Space Model (SSM) architecture designed to capture long-range dependencies in financial time-series data.<n>Our experiments show that CryptoMamba not only provides more accurate predictions but also offers enhanced generalizability across different market conditions.<n>Our findings signal a huge advantage for SSMs in stock and cryptocurrency price forecasting tasks.
arXiv Detail & Related papers (2025-01-02T02:16:56Z)
Explainable Post hoc Portfolio Management Financial Policy of a Deep Reinforcement Learning agent [44.99833362998488]
We develop a novel Explainable Deep Reinforcement Learning (XDRL) approach for portfolio management. By executing our methodology, we can interpret in prediction time the actions of the agent to assess whether they follow the requisites of an investment policy.
arXiv Detail & Related papers (2024-07-19T17:40:39Z)
Hawkes-based cryptocurrency forecasting via Limit Order Book data [1.6236898718152877]
We present a novel prediction algorithm using limit order book (LOB) data rooted in the Hawkes model. Our approach offers a precise forecast of return signs by leveraging predictions of future financial interactions. The efficacy of our approach is validated through Monte Carlo simulations across 50 scenarios.
arXiv Detail & Related papers (2023-12-21T16:31:07Z)
Cryptocurrency Portfolio Optimization by Neural Networks [81.20955733184398]
This paper proposes an effective algorithm based on neural networks to take advantage of these investment products. A deep neural network, which outputs the allocation weight of each asset at a time interval, is trained to maximize the Sharpe ratio. A novel loss term is proposed to regulate the network's bias towards a specific asset, thus enforcing the network to learn an allocation strategy that is close to a minimum variance strategy.
arXiv Detail & Related papers (2023-10-02T12:33:28Z)
Value-Distributional Model-Based Reinforcement Learning [59.758009422067]
Quantifying uncertainty about a policy's long-term performance is important to solve sequential decision-making tasks. We study the problem from a model-based Bayesian reinforcement learning perspective. We propose Epistemic Quantile-Regression (EQR), a model-based algorithm that learns a value distribution function.
arXiv Detail & Related papers (2023-08-12T14:59:19Z)
Joint Latent Topic Discovery and Expectation Modeling for Financial Markets [45.758436505779386]
We present a groundbreaking framework for financial market analysis. This approach is the first to jointly model investor expectations and automatically mine latent stock relationships. Our model consistently achieves an annual return exceeding 10%.
arXiv Detail & Related papers (2023-06-01T01:36:51Z)
TPLVM: Portfolio Construction by Student's $t$-process Latent Variable Model [3.5408022972081694]
We propose the Student's $t$-process latent variable model (TPLVM) to describe non-Gaussian fluctuations of financial timeseries by lower dimensional latent variables. By comparing these portfolios, we confirm the proposed portfolio outperforms that of the existing Gaussian process latent variable model.
arXiv Detail & Related papers (2020-01-29T02:02:02Z)

This list is automatically generated from the titles and abstracts of the papers in this site.