Mingze Gao – AFIN8003 Week 8 - Credit Risk II: Loan Portfolio and Concentration Risk

	AAA-A	BBB-B	CCC-C	Default
AAA-A	0.85	0.10	0.04	0.01
BBB-B	0.12	0.83	0.03	0.02
CCC-C	0.03	0.13	0.80	0.04

Sector	$m	% of Total Exposure
Residential mortgages	62,738	77.8
Property and construction	6,887	8.5
Healthcare	2,763	3.4
Professional services	2,431	3.0
Agriculture	1,232	1.5
Transportation	606	0.8
Manufacturing and mining	682	0.8
Hospitality and accommodation	841	1.0
Other	2,453	3.0
Total	80,633	100.0

Loan portfolio diversification and MPT

MPT can be used to measure and control an FI’s aggregate credit risk exposure.

Any model that seeks to estimate an efficient frontier for loans needs to determine and measure three things:

The expected return on individual loans
The risk of individual loans
The correlation of default risks between loans

Expected return \(R_p\) of a portfolio of \(N\) assets:

\[ R_p = \sum_{i=1}^N X_i R_i \]

where

\(R_i\) is the expected return on the \(i\)th asset
\(X_i\) is the proportion of the asset portfolio invested in the \(i\)th asset (the desired concentration amount)

Loan portfolio diversification and MPT (cont’d)

Variance of returns (or risk) of the portfolio \(\sigma_p^2\) can be calculated as

\[ \begin{aligned} \sigma_i^2 &= \sum_{i=1}^N X_i^2 \sigma^2_i + \sum_{i=1}^N \sum_{j=1}^N X_i X_j \sigma_{ij} \\ &= \sum_{i=1}^N X_i^2 \sigma^2_i + \sum_{i=1}^N \sum_{j=1}^N X_i X_j \rho_{ij} \sigma_i \sigma_j \end{aligned} \]

where

\(\rho_{ij}\) is the correlation between the returns on the \(i\)th asset \(j\)th asset
\(\sigma_i^2\) is the variance of returns on the \(i\)th asset
\(\sigma_{ij}^2\) is the covariance of returns between the \(i\)th asset and \(j\)th asset

Loan portfolio diversification and MPT (cont’d)

The fundamental lesson of MPT is that by taking advantage of its size, an FI can diversify considerable amounts of credit risk as long as the returns on different assets are imperfectly correlated with respect to their default risk adjusted returns.

Code

import numpy as np
import matplotlib.pyplot as plt

# Define annualized returns and covariance matrix for two assets
mean_returns = np.array([0.04, 0.1])  # Expected annual returns for two assets
cov_matrix = np.array([[0.06, 0.02], [0.02, 0.10]])  # Covariance matrix of returns
individual_volatility = np.sqrt(np.diag(cov_matrix))  # Volatility of individual assets

# Define the number of portfolios to simulate
num_portfolios = 10000

# Initialize empty lists to store portfolio returns, volatilities, and weights
results = np.zeros((3, num_portfolios))

# Simulate random portfolios
for i in range(num_portfolios):
    # Generate random weights for the two assets
    weights = np.random.random(2)
    weights /= np.sum(weights)  # Ensure weights sum to 1

    # Calculate portfolio return and volatility (risk)
    portfolio_return = np.dot(weights, mean_returns)
    portfolio_volatility = np.sqrt(np.dot(weights.T, np.dot(cov_matrix, weights)))

    # Store the results
    results[0, i] = portfolio_volatility
    results[1, i] = portfolio_return
    results[2, i] = portfolio_return / portfolio_volatility  # Sharpe ratio

# Calculate the Global Minimum Variance Portfolio (GMVP)
inv_cov_matrix = np.linalg.inv(cov_matrix)
ones = np.ones(len(mean_returns))
weights_gmvp = inv_cov_matrix.dot(ones) / ones.T.dot(inv_cov_matrix).dot(ones)
gmvp_return = weights_gmvp.dot(mean_returns)
gmvp_volatility = np.sqrt(weights_gmvp.T.dot(cov_matrix).dot(weights_gmvp))

# Plot the efficient frontier
plt.figure(figsize=(10, 6))
plt.scatter(
    results[0, :], results[1, :], c=results[2, :], cmap="Blues", marker="o", alpha=1
)
plt.colorbar(label="Sharpe Ratio")

# Plot individual assets as red dots
plt.scatter(
    individual_volatility[0],
    mean_returns[0],
    # color="red",
    marker="o",
    s=100,
    label="Asset 1",
)
plt.scatter(
    individual_volatility[1],
    mean_returns[1],
    # color="blue",
    marker="o",
    s=100,
    label="Asset 2",
)
# Plot GMVP
plt.scatter(gmvp_volatility, gmvp_return, color="red", marker="X", s=100, label="GMVP")

# Set axis limits to start from 0
plt.xlim(0, np.max(results[0, :]) + 0.02)  # Add a small margin on the right
plt.ylim(0, np.max(results[1, :]) + 0.02)  # Add a small margin on the top

# Annotate the plot
plt.title("Efficient Frontier with Two Assets")
plt.xlabel("Volatility (Risk)")
plt.ylabel("Expected Return")
plt.legend(loc="upper left")
plt.show()

Minimum risk portfolio (Global Minimum Variance Portfolio, GMVP)

Combination of assets that reduces the variance of portfolio returns on the lowest feasible level.

Moody’s Analytics RiskFrontier Model

Moody’s Analytics RiskFrontier model (previously Portfolio Manager model) estimates the return, risk and correlations between loans in an FI’s loan portfolio (with its own proprietary methods), which are then incorporated into the standard MPT equations to get an estimate of the risk and return of the FI’s loan portfolio.

Moody’s Analytics Credit Monitor model estimates EDF (Expected Default Frequency) to examine the default risk of individual loans.
Moody’s Analytics RiskFrontier model then uses EDF to identify the overall risk of the loan portfolio.
- Does not require loan returns to be normally distributed
- Applies MPT to the loan portfolio, although many loans have non-traded aspects

Moody’s Analytics RiskFrontier Model (cont’d)

In Moody’s Analytics RiskFrontier model, portfolio return and risk are a function of:

the extent to which loan (exposure) values can change over a one-year horizon, and
- based on EDF and the loss given default (LGD)
how these value changes move together across different loans in the loan portfolio (correlations).
- based on the joint impact of close to 1,000 different systematic factors, which reflect the global economy, region, industry, and country

Moody’s Analytics RiskFrontier Model (cont’d)

Required input variables:

\(R_i\): Expected return on a loan to a borrower \(i\) is the loan’s all-in-drawn spread (\(AIS\)) minus expected loss (expected default frequency times loss given default (LGD)).¹ \[ R_i = AIS_i - E(L_i) = AIS_i - (EDF_i\times LGD_i) \]
- The Basel Committee assessed a fixed 45% LGD on secured loans if fully secured by physical, non–real estate collateral and 40% if fully secured by receivables.

\(\sigma_i\): Risk of a loan to borrower \(i\), “unexpected loss”, is the volatility of the loan’s default rate \(\sigma_{D_i}\) times the amount lost given default (LGD).² \[ \sigma_i = UL_i = \sigma_{D_i} \times LGD_i = \sqrt{EDF_i(1-EDF_i)} \times LGD_i \]
- Assume defaults are binomially distributed (default or not), the standard deviation of default rate (\(\sigma_{D_i}\)) is \(\sqrt{EDF_i(1-EDF_i)}\).

\(\rho_{ij}\): Correlation of default risks between borrowers \(i\) and \(j\) is the correlation between the systematic return components of the asset returns of \(i\) and \(j\).

Moody’s Analytics RiskFrontier Model (cont’d)

To measure the unobservable default risk correlation between any two borrowers, the Moody’s Analytics Global Correlation Model (GCORR) uses the systematic asset return components of the two borrowers and calculates a correlation that is based on a factor model rather than direct historical observations.

Figure 2: GCorr Corporate Factor Structure

Figure 2 provides a visual representation of the Moody’s Analytics GCorr Corporate factor structure.

Moody’s Analytics RiskFrontier Model (example)

Suppose that an FI holds two loans with the following characteristics. Assume that the correlation \(\rho_{12}=-0.25\), what are the return and risk of the portfolio?

Loan \(i\)	\(X_i\)	Spread between loan rate and FI’s cost of funds	Fees	LGD	EDF
1	0.6	5%	2%	25%	3%
2	0.4	4.5%	1.5%	20%	2%

The return and risk on loan 1 are:

\[ \begin{aligned} R_1 &= (0.05+0.02) - (0.03\times0.25) = 0.0625 \\ \sigma_1 &= \sqrt{0.03\times0.97} \times 0.25 = 0.04265 \end{aligned} \]

The return and risk on loan 2 are:

\[ \begin{aligned} R_2 &= (0.045+0.015) - (0.02\times0.2) = 0.056 \\ \sigma_2 &= \sqrt{0.02\times0.98} \times 0.2 = 0.028 \end{aligned} \]

The return and risk of the portfolio are then:

\[ \begin{aligned} R_p &= 0.6\times 0.0625 + 0.4\times 0.056 = 0.0599 \text{ or } 5.99\% \\ \sigma_p^2 &= (0.6)^2(0.04265)^2 + (0.4)^2(0.028)^2 + 2(0.6)(0.4)(-0.25)(0.04265)(0.028) = 0.0006369 \\ \sigma_p &= \sqrt{0.0006369} = 0.0252 = 2.52\% \end{aligned} \]

Partial application of portfolio theory

Loan volume-based models
Loan loss ratio-based models

Partial application of portfolio theory: Loan volume-based models

Direct application of MPT is often difficult for FIs lacking information on market prices because many of the loans are not always able to be bought and sold in established markets.

Data can be gathered from:

Reports to the central bank
Data on shared national credit
Commercial databases

Data provides market benchmarks against which FIs can compare their loan portfolios.

Table 3: Allocation of the Loan Portfolio to Different Sectors (in percentages)

	(1) National	(2) Bank A	(3) Bank B
Real estate	45%	65%	10%
C&I	30	20	25
Individual	15	10	55
Others	10	5	10
Total	100	100	100

Partial application of portfolio theory: Loan volume-based models (cont’d)

Deviations from the market portfolio benchmark indicate the relative degree of loan concentration.
Relative measure of loan allocation deviation:

\[ \sigma_j = \sqrt{\frac{\sum_{i=1}^N (X_{ij}-X{i})^2}{N}} \]

where

\(\sigma_j\) is the standard deviation of bank \(j\)’s asset allocation proportions from the national benchmark
\(X_i\) is the national asset allocations
\(X_{ij}\) is the asset allocation proportions of the \(j\)th bank
\(N\) is the number of observations or loan categories

Partial application of portfolio theory: Loan volume-based models (cont’d)

Refer to Table 3. We get the deviation of Bank A’s loan portfolio allocation as follows:

\[ \begin{aligned} (X_{1A}-X_1)^2 &= (0.65-0.45)^2 = 0.04 \\ (X_{2A}-X_2)^2 &= (0.20-0.30)^2 = 0.01 \\ (X_{3A}-X_3)^2 &= (0.10-0.15)^2 = 0.0025 \\ (X_{4A}-X_4)^2 &= (0.05-0.10)^2 = 0.0025 \end{aligned} \] and therefore \[ \sigma_A = \sqrt{\frac{0.04+0.01+0.0025+0.0025}{4}} = 11.73\% \]

Partial application of portfolio theory: Loan loss ratio-based models

Estimates systematic loan loss risk of a particular sector or industry to the loan loss risk of an FI’s total loan portfolio

Use of time-series regression of quarterly losses:

\[ \frac{\text{Sectoral losses in the } i\text{th sector}}{\text{Loans to the } i\text{th sector}} = \alpha + \beta \frac{\text{Total loan losses}}{\text{Total loans}} \]

where

\(\alpha\) measures the loan loss rate for a sector that has no sensitivity to losses on the aggregate loan portfolio
\(\beta\) measures the systematic loss sensitivity of the \(i\)th sector loans to total loan losses

The implication of this model is that sectors with lower \(\beta\)s could have higher concentration limits than high \(\beta\) sectors—since low \(\beta\) loan sector risks (loan losses) are less systematic (that is, are more diversifiable in a portfolio sense).

Regulatory models

Federal Reserve’s 1994 Ruling on Credit Concentration Risk:
- Adopted a subjective approach based on examiner discretion.
- Rejected technical models due to insufficient data and undeveloped methods at the time.
2006 Regulatory Changes:
- Bank for International Settlements (BIS): Released guidance on credit risk assessment and valuation for loans, structured around 10 principles on risk assessment and supervisory evaluation.
- Office of the Comptroller of the Currency (OCC): Released guidance on sound risk management practices for commercial real estate lending.
OCC/Fed Joint Study on 2006 CRE Concentration Guidance (April 2013):
- 13% of banks with construction loans exceeding 100% of capital failed.
- 23% of banks exceeding both construction and total CRE lending criteria failed, compared to only 0.5% of banks that did not exceed either criterion.
- Regulators encouraged financial institutions to review their policies and practices related to CRE lending.

Credit Spread at End of Forward Agreement	Credit Spread Seller (bank)	Credit Spread Buyer (counterparty)
\(\phi_T>\phi_F\)	Receives \((\phi_T - \phi_F) \times MD \times A\)	Pays \((\phi_T - \phi_F) \times MD \times A\)
\(\phi_T<\phi_F\)	Pays \((\phi_F - \phi_T) \times MD \times A\)	Receives \((\phi_F - \phi_T) \times MD \times A\)

AFIN8003 Week 8 - Credit Risk II: Loan Portfolio and Concentration Risk

Credit Risk II: Loan Portfolio and Concentration Risk

Introduction

Simple models of loan concentration risk

Simple models

Simple model: migration analysis

Simple model: migration analysis (cont’d)

Simple model: concentration limits

Simple model: concentration limits (cont’d)

Loan portfolio diversification and Modern Portfolio Theory (MPT)

Loan portfolio diversification and MPT

Loan portfolio diversification and MPT (cont’d)

Loan portfolio diversification and MPT (cont’d)

Moody’s Analytics RiskFrontier Model

Moody’s Analytics RiskFrontier Model (cont’d)

Moody’s Analytics RiskFrontier Model (cont’d)

Moody’s Analytics RiskFrontier Model (cont’d)

Moody’s Analytics RiskFrontier Model (example)

Partial application of portfolio theory

Partial application of portfolio theory: Loan volume-based models

Partial application of portfolio theory: Loan volume-based models (cont’d)

Partial application of portfolio theory: Loan volume-based models (cont’d)

Partial application of portfolio theory: Loan loss ratio-based models

Regulatory models

Use of derivatives to manage credit risk

Credit derivatives

Credit forward contracts and credit risk hedging

Credit forward contracts and credit risk hedging (cont’d)

Credit options

Credit (default) swaps (CDS)

Basics of CDS

Credit swaps: total return swaps

Credit swaps: total return swaps (cont’d)

Credit swaps: pure credit swaps

Credit swaps: pure credit swaps (cont’d)

Finally…

Suggested readings

References