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Risk Metrics Calculation

by @zhengxinjipai

Calculate portfolio risk metrics including VaR, CVaR, Sharpe, Sortino, and drawdown analysis. Use when measuring portfolio risk, implementing risk limits, or...

Versionv1.0.0
Downloads797
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TERMINAL
clawhub install risk-metrics-calculation

πŸ“– About This Skill


name: risk-metrics-calculation description: Calculate portfolio risk metrics including VaR, CVaR, Sharpe, Sortino, and drawdown analysis. Use when measuring portfolio risk, implementing risk limits, or building risk monitoring systems.

Risk Metrics Calculation

Comprehensive risk measurement toolkit for portfolio management, including Value at Risk, Expected Shortfall, and drawdown analysis.

When to Use This Skill

  • Measuring portfolio risk
  • Implementing risk limits
  • Building risk dashboards
  • Calculating risk-adjusted returns
  • Setting position sizes
  • Regulatory reporting
  • Core Concepts

    1. Risk Metric Categories

    | Category | Metrics | Use Case | | ----------------- | --------------- | -------------------- | | Volatility | Std Dev, Beta | General risk | | Tail Risk | VaR, CVaR | Extreme losses | | Drawdown | Max DD, Calmar | Capital preservation | | Risk-Adjusted | Sharpe, Sortino | Performance |

    2. Time Horizons

    Intraday:   Minute/hourly VaR for day traders
    Daily:      Standard risk reporting
    Weekly:     Rebalancing decisions
    Monthly:    Performance attribution
    Annual:     Strategic allocation
    

    Implementation

    Pattern 1: Core Risk Metrics

    import numpy as np
    import pandas as pd
    from scipy import stats
    from typing import Dict, Optional, Tuple

    class RiskMetrics: """Core risk metric calculations."""

    def __init__(self, returns: pd.Series, rf_rate: float = 0.02): """ Args: returns: Series of periodic returns rf_rate: Annual risk-free rate """ self.returns = returns self.rf_rate = rf_rate self.ann_factor = 252 # Trading days per year

    # Volatility Metrics def volatility(self, annualized: bool = True) -> float: """Standard deviation of returns.""" vol = self.returns.std() if annualized: vol *= np.sqrt(self.ann_factor) return vol

    def downside_deviation(self, threshold: float = 0, annualized: bool = True) -> float: """Standard deviation of returns below threshold.""" downside = self.returns[self.returns < threshold] if len(downside) == 0: return 0.0 dd = downside.std() if annualized: dd *= np.sqrt(self.ann_factor) return dd

    def beta(self, market_returns: pd.Series) -> float: """Beta relative to market.""" aligned = pd.concat([self.returns, market_returns], axis=1).dropna() if len(aligned) < 2: return np.nan cov = np.cov(aligned.iloc[:, 0], aligned.iloc[:, 1]) return cov[0, 1] / cov[1, 1] if cov[1, 1] != 0 else 0

    # Value at Risk def var_historical(self, confidence: float = 0.95) -> float: """Historical VaR at confidence level.""" return -np.percentile(self.returns, (1 - confidence) * 100)

    def var_parametric(self, confidence: float = 0.95) -> float: """Parametric VaR assuming normal distribution.""" z_score = stats.norm.ppf(confidence) return self.returns.mean() - z_score * self.returns.std()

    def var_cornish_fisher(self, confidence: float = 0.95) -> float: """VaR with Cornish-Fisher expansion for non-normality.""" z = stats.norm.ppf(confidence) s = stats.skew(self.returns) # Skewness k = stats.kurtosis(self.returns) # Excess kurtosis

    # Cornish-Fisher expansion z_cf = (z + (z**2 - 1) * s / 6 + (z**3 - 3*z) * k / 24 - (2*z3 - 5*z) * s2 / 36)

    return -(self.returns.mean() + z_cf * self.returns.std())

    # Conditional VaR (Expected Shortfall) def cvar(self, confidence: float = 0.95) -> float: """Expected Shortfall / CVaR / Average VaR.""" var = self.var_historical(confidence) return -self.returns[self.returns <= -var].mean()

    # Drawdown Analysis def drawdowns(self) -> pd.Series: """Calculate drawdown series.""" cumulative = (1 + self.returns).cumprod() running_max = cumulative.cummax() return (cumulative - running_max) / running_max

    def max_drawdown(self) -> float: """Maximum drawdown.""" return self.drawdowns().min()

    def avg_drawdown(self) -> float: """Average drawdown.""" dd = self.drawdowns() return dd[dd < 0].mean() if (dd < 0).any() else 0

    def drawdown_duration(self) -> Dict[str, int]: """Drawdown duration statistics.""" dd = self.drawdowns() in_drawdown = dd < 0

    # Find drawdown periods drawdown_starts = in_drawdown & ~in_drawdown.shift(1).fillna(False) drawdown_ends = ~in_drawdown & in_drawdown.shift(1).fillna(False)

    durations = [] current_duration = 0

    for i in range(len(dd)): if in_drawdown.iloc[i]: current_duration += 1 elif current_duration > 0: durations.append(current_duration) current_duration = 0

    if current_duration > 0: durations.append(current_duration)

    return { "max_duration": max(durations) if durations else 0, "avg_duration": np.mean(durations) if durations else 0, "current_duration": current_duration }

    # Risk-Adjusted Returns def sharpe_ratio(self) -> float: """Annualized Sharpe ratio.""" excess_return = self.returns.mean() * self.ann_factor - self.rf_rate vol = self.volatility(annualized=True) return excess_return / vol if vol > 0 else 0

    def sortino_ratio(self) -> float: """Sortino ratio using downside deviation.""" excess_return = self.returns.mean() * self.ann_factor - self.rf_rate dd = self.downside_deviation(threshold=0, annualized=True) return excess_return / dd if dd > 0 else 0

    def calmar_ratio(self) -> float: """Calmar ratio (return / max drawdown).""" annual_return = (1 + self.returns).prod() ** (self.ann_factor / len(self.returns)) - 1 max_dd = abs(self.max_drawdown()) return annual_return / max_dd if max_dd > 0 else 0

    def omega_ratio(self, threshold: float = 0) -> float: """Omega ratio.""" returns_above = self.returns[self.returns > threshold] - threshold returns_below = threshold - self.returns[self.returns <= threshold]

    if returns_below.sum() == 0: return np.inf

    return returns_above.sum() / returns_below.sum()

    # Information Ratio def information_ratio(self, benchmark_returns: pd.Series) -> float: """Information ratio vs benchmark.""" active_returns = self.returns - benchmark_returns tracking_error = active_returns.std() * np.sqrt(self.ann_factor) active_return = active_returns.mean() * self.ann_factor return active_return / tracking_error if tracking_error > 0 else 0

    # Summary def summary(self) -> Dict[str, float]: """Generate comprehensive risk summary.""" dd_stats = self.drawdown_duration()

    return { # Returns "total_return": (1 + self.returns).prod() - 1, "annual_return": (1 + self.returns).prod() ** (self.ann_factor / len(self.returns)) - 1,

    # Volatility "annual_volatility": self.volatility(), "downside_deviation": self.downside_deviation(),

    # VaR & CVaR "var_95_historical": self.var_historical(0.95), "var_99_historical": self.var_historical(0.99), "cvar_95": self.cvar(0.95),

    # Drawdowns "max_drawdown": self.max_drawdown(), "avg_drawdown": self.avg_drawdown(), "max_drawdown_duration": dd_stats["max_duration"],

    # Risk-Adjusted "sharpe_ratio": self.sharpe_ratio(), "sortino_ratio": self.sortino_ratio(), "calmar_ratio": self.calmar_ratio(), "omega_ratio": self.omega_ratio(),

    # Distribution "skewness": stats.skew(self.returns), "kurtosis": stats.kurtosis(self.returns), }

    Pattern 2: Portfolio Risk

    class PortfolioRisk:
        """Portfolio-level risk calculations."""

    def __init__( self, returns: pd.DataFrame, weights: Optional[pd.Series] = None ): """ Args: returns: DataFrame with asset returns (columns = assets) weights: Portfolio weights (default: equal weight) """ self.returns = returns self.weights = weights if weights is not None else \ pd.Series(1/len(returns.columns), index=returns.columns) self.ann_factor = 252

    def portfolio_return(self) -> float: """Weighted portfolio return.""" return (self.returns @ self.weights).mean() * self.ann_factor

    def portfolio_volatility(self) -> float: """Portfolio volatility.""" cov_matrix = self.returns.cov() * self.ann_factor port_var = self.weights @ cov_matrix @ self.weights return np.sqrt(port_var)

    def marginal_risk_contribution(self) -> pd.Series: """Marginal contribution to risk by asset.""" cov_matrix = self.returns.cov() * self.ann_factor port_vol = self.portfolio_volatility()

    # Marginal contribution mrc = (cov_matrix @ self.weights) / port_vol return mrc

    def component_risk(self) -> pd.Series: """Component contribution to total risk.""" mrc = self.marginal_risk_contribution() return self.weights * mrc

    def risk_parity_weights(self, target_vol: float = None) -> pd.Series: """Calculate risk parity weights.""" from scipy.optimize import minimize

    n = len(self.returns.columns) cov_matrix = self.returns.cov() * self.ann_factor

    def risk_budget_objective(weights): port_vol = np.sqrt(weights @ cov_matrix @ weights) mrc = (cov_matrix @ weights) / port_vol rc = weights * mrc target_rc = port_vol / n # Equal risk contribution return np.sum((rc - target_rc) ** 2)

    constraints = [ {"type": "eq", "fun": lambda w: np.sum(w) - 1}, # Weights sum to 1 ] bounds = [(0.01, 1.0) for _ in range(n)] # Min 1%, max 100% x0 = np.array([1/n] * n)

    result = minimize( risk_budget_objective, x0, method="SLSQP", bounds=bounds, constraints=constraints )

    return pd.Series(result.x, index=self.returns.columns)

    def correlation_matrix(self) -> pd.DataFrame: """Asset correlation matrix.""" return self.returns.corr()

    def diversification_ratio(self) -> float: """Diversification ratio (higher = more diversified).""" asset_vols = self.returns.std() * np.sqrt(self.ann_factor) weighted_vol = (self.weights * asset_vols).sum() port_vol = self.portfolio_volatility() return weighted_vol / port_vol if port_vol > 0 else 1

    def tracking_error(self, benchmark_returns: pd.Series) -> float: """Tracking error vs benchmark.""" port_returns = self.returns @ self.weights active_returns = port_returns - benchmark_returns return active_returns.std() * np.sqrt(self.ann_factor)

    def conditional_correlation( self, threshold_percentile: float = 10 ) -> pd.DataFrame: """Correlation during stress periods.""" port_returns = self.returns @ self.weights threshold = np.percentile(port_returns, threshold_percentile) stress_mask = port_returns <= threshold return self.returns[stress_mask].corr()

    Pattern 3: Rolling Risk Metrics

    class RollingRiskMetrics:
        """Rolling window risk calculations."""

    def __init__(self, returns: pd.Series, window: int = 63): """ Args: returns: Return series window: Rolling window size (default: 63 = ~3 months) """ self.returns = returns self.window = window

    def rolling_volatility(self, annualized: bool = True) -> pd.Series: """Rolling volatility.""" vol = self.returns.rolling(self.window).std() if annualized: vol *= np.sqrt(252) return vol

    def rolling_sharpe(self, rf_rate: float = 0.02) -> pd.Series: """Rolling Sharpe ratio.""" rolling_return = self.returns.rolling(self.window).mean() * 252 rolling_vol = self.rolling_volatility() return (rolling_return - rf_rate) / rolling_vol

    def rolling_var(self, confidence: float = 0.95) -> pd.Series: """Rolling historical VaR.""" return self.returns.rolling(self.window).apply( lambda x: -np.percentile(x, (1 - confidence) * 100), raw=True )

    def rolling_max_drawdown(self) -> pd.Series: """Rolling maximum drawdown.""" def max_dd(returns): cumulative = (1 + returns).cumprod() running_max = cumulative.cummax() drawdowns = (cumulative - running_max) / running_max return drawdowns.min()

    return self.returns.rolling(self.window).apply(max_dd, raw=False)

    def rolling_beta(self, market_returns: pd.Series) -> pd.Series: """Rolling beta vs market.""" def calc_beta(window_data): port_ret = window_data.iloc[:, 0] mkt_ret = window_data.iloc[:, 1] cov = np.cov(port_ret, mkt_ret) return cov[0, 1] / cov[1, 1] if cov[1, 1] != 0 else 0

    combined = pd.concat([self.returns, market_returns], axis=1) return combined.rolling(self.window).apply( lambda x: calc_beta(x.to_frame()), raw=False ).iloc[:, 0]

    def volatility_regime( self, low_threshold: float = 0.10, high_threshold: float = 0.20 ) -> pd.Series: """Classify volatility regime.""" vol = self.rolling_volatility()

    def classify(v): if v < low_threshold: return "low" elif v > high_threshold: return "high" else: return "normal"

    return vol.apply(classify)

    Pattern 4: Stress Testing

    class StressTester:
        """Historical and hypothetical stress testing."""

    # Historical crisis periods HISTORICAL_SCENARIOS = { "2008_financial_crisis": ("2008-09-01", "2009-03-31"), "2020_covid_crash": ("2020-02-19", "2020-03-23"), "2022_rate_hikes": ("2022-01-01", "2022-10-31"), "dot_com_bust": ("2000-03-01", "2002-10-01"), "flash_crash_2010": ("2010-05-06", "2010-05-06"), }

    def __init__(self, returns: pd.Series, weights: pd.Series = None): self.returns = returns self.weights = weights

    def historical_stress_test( self, scenario_name: str, historical_data: pd.DataFrame ) -> Dict[str, float]: """Test portfolio against historical crisis period.""" if scenario_name not in self.HISTORICAL_SCENARIOS: raise ValueError(f"Unknown scenario: {scenario_name}")

    start, end = self.HISTORICAL_SCENARIOS[scenario_name]

    # Get returns during crisis crisis_returns = historical_data.loc[start:end]

    if self.weights is not None: port_returns = (crisis_returns @ self.weights) else: port_returns = crisis_returns

    total_return = (1 + port_returns).prod() - 1 max_dd = self._calculate_max_dd(port_returns) worst_day = port_returns.min()

    return { "scenario": scenario_name, "period": f"{start} to {end}", "total_return": total_return, "max_drawdown": max_dd, "worst_day": worst_day, "volatility": port_returns.std() * np.sqrt(252) }

    def hypothetical_stress_test( self, shocks: Dict[str, float] ) -> float: """ Test portfolio against hypothetical shocks.

    Args: shocks: Dict of {asset: shock_return} """ if self.weights is None: raise ValueError("Weights required for hypothetical stress test")

    total_impact = 0 for asset, shock in shocks.items(): if asset in self.weights.index: total_impact += self.weights[asset] * shock

    return total_impact

    def monte_carlo_stress( self, n_simulations: int = 10000, horizon_days: int = 21, vol_multiplier: float = 2.0 ) -> Dict[str, float]: """Monte Carlo stress test with elevated volatility.""" mean = self.returns.mean() vol = self.returns.std() * vol_multiplier

    simulations = np.random.normal( mean, vol, (n_simulations, horizon_days) )

    total_returns = (1 + simulations).prod(axis=1) - 1

    return { "expected_loss": -total_returns.mean(), "var_95": -np.percentile(total_returns, 5), "var_99": -np.percentile(total_returns, 1), "worst_case": -total_returns.min(), "prob_10pct_loss": (total_returns < -0.10).mean() }

    def _calculate_max_dd(self, returns: pd.Series) -> float: cumulative = (1 + returns).cumprod() running_max = cumulative.cummax() drawdowns = (cumulative - running_max) / running_max return drawdowns.min()

    Quick Reference

    # Daily usage
    metrics = RiskMetrics(returns)
    print(f"Sharpe: {metrics.sharpe_ratio():.2f}")
    print(f"Max DD: {metrics.max_drawdown():.2%}")
    print(f"VaR 95%: {metrics.var_historical(0.95):.2%}")

    Full summary

    summary = metrics.summary() for metric, value in summary.items(): print(f"{metric}: {value:.4f}")

    Best Practices

    Do's

  • Use multiple metrics - No single metric captures all risk
  • Consider tail risk - VaR isn't enough, use CVaR
  • Rolling analysis - Risk changes over time
  • Stress test - Historical and hypothetical
  • Document assumptions - Distribution, lookback, etc.
  • Don'ts

  • Don't rely on VaR alone - Underestimates tail risk
  • Don't assume normality - Returns are fat-tailed
  • Don't ignore correlation - Increases in stress
  • Don't use short lookbacks - Miss regime changes
  • Don't forget transaction costs - Affects realized risk
  • Resources

  • Risk Management and Financial Institutions (John Hull)
  • Quantitative Risk Management (McNeil, Frey, Embrechts)
  • pyfolio Documentation
  • πŸ“‹ Tips & Best Practices

    Do's

  • Use multiple metrics - No single metric captures all risk
  • Consider tail risk - VaR isn't enough, use CVaR
  • Rolling analysis - Risk changes over time
  • Stress test - Historical and hypothetical
  • Document assumptions - Distribution, lookback, etc.
  • Don'ts

  • Don't rely on VaR alone - Underestimates tail risk
  • Don't assume normality - Returns are fat-tailed
  • Don't ignore correlation - Increases in stress
  • Don't use short lookbacks - Miss regime changes
  • Don't forget transaction costs - Affects realized risk