Financial-Principles > Credit >Credit Exposures

Credit Exposures

 

Credit Exposures estimate the cost of replacing positions by measuring the net outstanding amount due by a counterparty.

To this effect, Credit Exposures take into account close-out netting, if both parties to the trades have signed the ISDA Master agreement, as well as Collateral provisions, including any guaranteed collateral posted by the Home-Office or "Sponsor".

Credit Exposures are always computed over multiple horizons, which assumes proper non-stationary forward volatility and correlation projections, position ageing, yield curve mean-reversion(*) and cost of carry accumulation.

Credit Exposures are the starting point to all other credit risk analytics, such as migration or loss given default.

Credit Exposures do not include the probability of this event taking place.

Credit Exposures give way to numerous statistics:

Credit Exposures Against What Counterparty, Master Agreement or Accounts ?

Most simplistic systems model exposure against a Counterparty. More advanced engines use the notion of master agreements.

Risksvr™ takes this a few steps further and handles counterparty related information through Accounts.

Accounts encompass the binding relationship between buying and selling parties and thus extends beyond positive/ negative mark-to-market accumulation, collateral provisions etc, and condense the legal repercussions of payment delinquency and default.

The account is therefore defined by the party engaged in the relationship, the ISDA netting policy,, the collateral posted by the party and it's Home office or any party that will act as a sponsor  for the party, the country, the rating and the recovery class of the party which acts as the recovery rate and recovery volatility repository.

Terminology:

V(t) : is the value of a portfolio at time t.
E(t) : is the credit exposure at time t and is computed as Max{V(t),0}.
f : is the pdf (probability density function)
F : is the cdf (cumulative density Function) of V(t).
T : is the instrument's time to maturity or expiration date.

Exposure at any time t can be zero.

 

Credit Exposure Calculation

To compute Credit Exposure and related statistics, we need to know what will be the cost of replacing our positions if the counterparty defaults on us.
In theory, credit exposures are computed over the entire simulation horizon.

In practice and since we are only interested in the amount that is positive to the receiving side, 
we compute credit exposure by taking the sum of all positive values or replacement costs of the asset over the simulation horizon.

Netting - ISDA Master Agreement provisions

Both current and future potential exposures are affected by netting, if both parties have signed an ISDA master agreement.

A netting agreement specifies whether or not two or more trades should be allowed to offset each other.
If netting is active, the gross replacement cost of all positive values give way to the Maximum between 0 and the sum of all netted assets long and short that are held against the party in the account.

Posted Collateral

Both current and future potential exposure take into account collateral posted by the party and it's home office.

 

Mean, Peak Potential Future Exposure Calculation

Expected Future Exposure – Mean Exposure, decreases over time

Potential Future Exposure (Mean Exposure + 1 (one) standard deviation) 84.3%

User Defined Potential Future Exposure Mean Exposure + confidence multiplier * std)

Top of page Current Exposure

The current exposure is the cost of replacement of the exposure(s) today

Top of page Expected Exposure


The expected exposure at time t is the mean exposure at time t, and is given by

.


Top of page Mean Expected Exposure

Mean Exposure is computed by accumulating the simulated position(s) values over each time horizons divided by the number of simulations.


Top of page Average Expected Exposure

The average exposure is the mean of the expected exposure, over time, applying a time-based discount factor:


Top of page Maximum Exposure at Time t

The maximum exposure at time t is the maximum percentile of the exposure at time t.

For Credit Exposure, the industry standard is 95% (which corresponds to a 5% percentile) so that: 

Top of page Maximum Exposure

The Maximum Exposure is computed as the Maximum amount computed over all the simulations horizons.


Top of page Peak Exposure

The peak exposure is the maximum value of the maximum exposure over the entire simulation horizon.
In other words it is the maximum of the 5% (tail) percentile.


Top of page Expected Future Exposure

The Expected Future Exposure at each future time node is the Mean of the portfolio's simulated values


Top of page Potential Future Exposure [PFE]

The Potential Future Exposure at each time step is the Mean plus the portfolio's standard deviations times the confidence interval.

 

Top of page Maximum Total Potential Exposure

The Maximum Total Potential Exposure is the time when the Potential Future Exposure is highest, if normal distribution is assumed, which might be a mistake, it can be proven maximum value is reached at time/3.

It is however important to understand distribution is rarely normal. Indeed, Credit exposure are NOT computed with a zero mean. (the value is akin to Earning at Risk) and due to the long simulation horizon, Mean Reversion can play an important role.

Top of page Future Potential Exposure

is the difference between the Current Exposure and the Maximum Total Potential Exposure.
This is the measure of the  additional exposure you can expect to incur between the Start Date and time T

Top of page Worst Case Exposure

Worst Case Exposure defines the probability of the contract over time.

Top of page Exposure Volatility or Quantiles


The Simple Approach: Exposure Volatility.

Exposure volatility is computed by taking the sum of squares of the difference between each simulated Exposure and the mean exposure (or zero in the "mean-zero" framework) divided by the number of simulations-1.

The Exposure Volatility is then factored by the confidence multiplier in order to reach the desired confidence level or "band". (i.e. we multiply by 1.654 to obtain a 95% confidence,  1.99 to obtain a 97.5 % confidence, etc.).

This simplification is similar to parametric Value-at-Risk. Some implementations simplify further by approximating the price volatility by adjusting  the underlying market risk factor volatility instead of performing a true revaluation !

The Real Approach: Credit Exposure Tails, buckets and Shortfall Probability.

A more precise Exposure is estimated by computing the exact distribution through buckets and quantiles.


The only drawback with this approach lies in the cumbersome configuration.

Indeed, the quality of results can often depend on exposure bucket size or widths, the Reference mean value and the number of buckets, which in turn vary at each level of the drilldown.

There are fortunately a number of elegant numerical solutions to automate this procedure.

Quantile accumulation is therefore a much better measure as it captures precisely the true distribution or when "sharper" results are expected.


Note:

This is because none of the measures incorporate the probability of default (aka Credit Curves) which are by definition non-decreasing.

In particular, average exposure only uses the discount factor weights.

However, since default likelihood is an increasing function of time, an exposure well into the distant future should represent more risk than the same size exposure in the near future.

This suggests an extension to the average exposure function to include defaults with the credit default curve.

Lack of Mean Reversion tends to under-estimate the risk of long positions.




2010© RiskServers SA. All rights reserved.