FRM Part 1

📘 Book: Foundations of Risk Management (FRM)

This book builds the base of risk, financial markets, models, and governance.

🧠 MODULE / CHAPTER-WISE SUMMARY

📌

Module 1: Risk Management – Foundations

Summary:

Introduces what risk is and why managing it is critical.
Explains types of risk:
- Market risk
- Credit risk
- Operational risk
Covers risk vs return trade-off
Discusses corporate governance and risk culture

Key Idea:

Risk is uncertainty that can impact financial outcomes.

📌

Module 2: Risk Appetite & Governance

Summary:

Defines risk appetite (how much risk a firm is willing to take)
Role of:
- Board of Directors
- Senior Management
Introduces risk frameworks and policies

Key Idea:

Firms must align risk-taking with business strategy.

📌

Module 3: Financial Disasters & Lessons

Summary:

Case studies:
- Barings Bank collapse
- 2008 Financial Crisis
Explains causes:
- Poor governance
- Excess leverage
- Model misuse

Key Idea:

Most failures are due to human + system failures, not just markets.

📌

Module 4: Risk Measures

Summary:

Introduces:
- Variance, Standard deviation
- Value at Risk (VaR)
Explains how risk is quantified mathematically

Key Idea:

Risk must be measurable to be managed.

📌

Module 5: Capital Asset Pricing Model (CAPM)

Summary:

Explains relationship:
- Risk ↔ Expected return
Introduces:
- Beta (systematic risk)
Assumptions:
- Markets are efficient
- Investors are rational

Key Idea:

Only systematic risk is rewarded.

📌

Module 6: Arbitrage Pricing Theory (APT) & Multifactor Models

Summary:

Extends CAPM → multiple factors affect returns
Factors include:
- Inflation
- Interest rates
- Economic growth
Arbitrage concept:
- No risk-free profit opportunity should exist

Key Idea:

Returns are driven by multiple macroeconomic factors

📌

Module 7: Data, Models & Risk Management

Summary:

Focus on:
- Model risk
- Data quality
Model risk types:
- Input risk
- Estimation risk
- Valuation risk
- Hedging risk
Importance of:
- High-quality data
- Model validation

Key Idea:

Bad data = bad decisions.

📌

Module 8: Risk Data Aggregation (BCBS 239)

Summary:

Basel principles for banks
Focus on:
- Data accuracy
- Timeliness
- Completeness
Introduces:
- Risk reporting frameworks
- Role of Chief Data Officer (CDO)

Key Idea:

Firms must aggregate risk data across the entire organization.

📌

Module 9: Big Data & Analytics in Risk

Summary:

Use of:
- Machine learning
- Alternative data (web, sensors, mobile data)
Benefits:
- Better forecasting
- Improved decision-making

Key Idea:

Data is becoming the core asset in risk management.

🎯 MOST IMPORTANT TOPICS (EXAM FOCUS)

These are the high-weight and frequently tested areas:

🔥 1. Risk Types

Market risk
Credit risk
Operational risk

🔥 2. CAPM vs APT

Single factor vs multiple factors
Beta concept
Arbitrage principle

🔥 3. Value at Risk (VaR)

Definition
Interpretation
Limitations

🔥 4. Model Risk

Input risk
Estimation errors
Wrong assumptions (e.g., stationarity)

🔥 5. Financial Crises Case Studies

Causes
Lessons
Governance failures

🔥 6. BCBS 239 Principles

Governance
Accuracy & integrity
Timeliness
Completeness

🔥 7. Risk Data Aggregation

Importance
Challenges (IT systems, data fragmentation)

🔥 8. Multifactor Models

Fama-French models
Economic factors driving returns

🧩 SIMPLE WAY TO REMEMBER THE BOOK

Think of it in 4 layers:

1. What is Risk

→ Types, importance

2. How to Measure

→ VaR, CAPM, APT

3. What Can Go Wrong

→ Model risk, crises

4. How to Control

→ Governance, BCBS, data systems

Below are chapter-wise numerical FRM practice problems for VaR, CAPM, and APT, with answers.

1. VaR Numerical Problems

Q1. Basic VaR Interpretation

A portfolio has a 1-day 95% VaR of £2 million.

What does this mean?

Answer:

There is a 5% chance that the portfolio will lose more than £2 million in one day under normal market conditions.

Q2. Parametric VaR

Portfolio value = £10 million

Daily volatility = 2%

Confidence level = 95%

Z-score = 1.65

Calculate 1-day VaR.

Formula:

VaR = Portfolio Value × Volatility × Z-score

Calculation:

VaR = 10,000,000 × 0.02 × 1.65

VaR = £330,000

Q3. 99% VaR

Portfolio value = £25 million

Daily volatility = 1.5%

99% Z-score = 2.33

Calculation:

VaR = 25,000,000 × 0.015 × 2.33

VaR = £873,750

Q4. VaR Limitation

A bank reports a 99% daily VaR of £5 million.

Can the loss be more than £5 million?

Answer:

Yes. VaR only tells the threshold loss. It does not tell how large the loss can be beyond that threshold. That is why Expected Shortfall is useful.

2. CAPM Numerical Problems

Q5. Expected Return Using CAPM

Risk-free rate = 4%

Market return = 10%

Beta = 1.2

Formula:

Expected Return = Risk-free rate + Beta × Market Risk Premium

Market Risk Premium = 10% − 4% = 6%

Calculation:

Expected Return = 4% + 1.2 × 6%

Expected Return = 4% + 7.2%

Expected Return = 11.2%

Q6. Undervalued or Overvalued Stock

Expected return from CAPM = 11%

Analyst expected return = 14%

Is the stock undervalued or overvalued?

Answer:

The stock is undervalued, because the analyst expects 14%, but CAPM requires only 11%.

Q7. Beta Calculation

Risk-free rate = 3%

Market return = 9%

Stock expected return = 12%

Find beta.

Formula:

Beta = (Stock Return − Risk-free Rate) / (Market Return − Risk-free Rate)

Calculation:

Beta = (12% − 3%) / (9% − 3%)

Beta = 9% / 6%

Beta = 1.5

Q8. Defensive Stock

Risk-free rate = 5%

Market return = 11%

Beta = 0.6

Calculation:

Expected Return = 5% + 0.6 × (11% − 5%)

Expected Return = 5% + 3.6%

Expected Return = 8.6%

Interpretation:

Beta below 1 means the stock is less volatile than the market.

3. APT Numerical Problems

APT uses multiple factors, unlike CAPM. The book notes that APT assumes returns are explained by systematic factors, specific risk can be diversified away, and no arbitrage opportunities should exist.

Q9. Basic APT Expected Return

Risk-free rate = 3%

Factor	Beta	Risk Premium
Inflation	0.8	2%
GDP Growth	1.1	4%
Interest Rate	-0.5	3%

Formula:

Expected Return = Rf + β₁F₁ + β₂F₂ + β₃F₃

Calculation:

= 3% + 0.8×2% + 1.1×4% + (-0.5×3%)

= 3% + 1.6% + 4.4% − 1.5%

= 7.5%

Q10. APT Mispricing

APT expected return = 9%

Actual expected return = 12%

Is there an arbitrage opportunity?

Answer:

Yes. The asset offers 3% more than required by APT, so it may be underpriced.

Q11. Two-Factor APT

Risk-free rate = 2%

Beta to inflation = 1.5

Inflation premium = 3%

Beta to industrial production = 0.7

Industrial production premium = 4%

Calculation:

Expected Return = 2% + 1.5×3% + 0.7×4%

= 2% + 4.5% + 2.8%

= 9.3%

Q12. Negative Factor Beta

Risk-free rate = 4%

Beta to interest rate factor = -1.2

Interest rate premium = 2.5%

Calculation:

Expected Return = 4% + (-1.2 × 2.5%)

= 4% − 3%

= 1%

Interpretation:

Negative beta means the asset benefits when that factor moves adversely for the market.

Quick Exam Focus

VaR: interpretation, confidence level, volatility, limitation.

CAPM: beta, market risk premium, undervalued/overvalued.

APT: multiple factors, no arbitrage, factor betas.

Great — I went through your FRM Foundations book (Module: CAPM & APT) and distilled it into a high-yield, exam-focused summary with highlighted concepts exactly the way you need for revision.

📘 CHAPTER SUMMARY (VaR, CAPM, APT – Highlight Style)

🔴 1. CAPM (Capital Asset Pricing Model)

⭐ Core Formula (MOST IMPORTANT)

E(R_i)=R_f+\beta_i(E(R_m)-R_f)

👉 Directly confirmed in your book

🔥 Key Highlights

1. What CAPM says

Expected return depends ONLY on market risk (beta)
It is a single-factor model

2. Beta Meaning

β = sensitivity to market
β > 1 → aggressive
β < 1 → defensive

🎯 Exam Concepts

✔ Undervalued vs Overvalued

Above SML → Undervalued
Below SML → Overvalued

⚠️ Assumptions (VERY IMPORTANT)

Investors are risk-averse
Markets are efficient
Investors hold mean-variance optimal portfolios

❌ Limitations

Only one factor (market)
Unrealistic assumptions
Ignores macroeconomic effects

🔵 2. APT (Arbitrage Pricing Theory)

⭐ Core Formula

E(R)=R_f+\beta_1F_1+\beta_2F_2+\cdots+\beta_kF_k

🔥 Key Highlights

1. What APT says

Returns depend on multiple factors
More realistic than CAPM 👉 Confirmed: APT considers multiple systematic factors

🧠 Core Idea

👉 If mispricing exists → arbitrage happens → prices correct

⭐ 3 Key Assumptions (VERY HIGH WEIGHTAGE)

From your book:

Returns driven by systematic factors
Diversification removes specific risk
No arbitrage exists

🔁 CAPM vs APT (SUPER IMPORTANT)

Feature	CAPM	APT
Factors	Single (market)	Multiple
Assumptions	Strong	Fewer
Flexibility	Low	High
Theory type	Equilibrium	Arbitrage-based

👉 CAPM = special case of APT

📊 Common APT Factors (Exam Favorite)

From Chen, Roll, Ross model:

Inflation
Interest rate spread
Industrial production
Credit spread

⚠️ Important Notes

APT does NOT require normal distribution
No need for market portfolio
Investors exploit arbitrage → prices adjust quickly

⚠️ Limitations

Factors not explicitly defined
Model risk (wrong assumptions)
May fail in stress markets (e.g., 2008 crisis)

🟢 3. VaR (Value at Risk) — Quick High-Yield Summary

(Not deeply in this module, but essential for FRM)

⭐ Core Formula (Parametric VaR)

VaR=Z\times\sigma\times V

🔥 Key Highlights

1. Definition

Maximum expected loss at given confidence level

2. Interpretation

95% VaR = 5% chance of exceeding loss

⚠️ Limitations (VERY IMPORTANT)

Does NOT tell how bad losses can be
Assumes normality
Fails in extreme markets

🧠 FINAL REVISION (1-Minute Memory)

📌 CAPM

Single factor → market
Beta decides return
SML → pricing

📌 APT

Multi-factor
Arbitrage ensures pricing
More realistic

📌 VaR

Risk measure
Probability-based
Weak in tail risk

Perfect—here’s a chapter-wise (module-wise) detailed product list for BOOK 3 (Financial Markets & Products). I’ve kept it exam-focused, structured, and deeper than before, so you can revise and also answer tricky questions.

📘 BOOK 3 — PRODUCTS (CHAPTER-WISE DETAILED)

🔴 Module 1: Banks

🏦 Core Products

🔹 1. Deposit Products

Savings accounts
Current accounts
Term deposits (fixed deposits)

👉 Liability side of bank balance sheet

🔹 2. Loan Products

Retail loans (mortgage, personal loans)
Corporate loans
Syndicated loans

👉 Asset side (income generating)

🔹 3. Interbank Products

Repo (repurchase agreements)
Reverse repo

👉 Short-term liquidity management

⚠️ Exam Focus

Repo = collateralized borrowing
Maturity mismatch → key banking risk

🔴 Module 2: Insurance & Pension

🛡️ Insurance Products

🔹 Life Insurance

Term life
Whole life

🔹 General Insurance

Health insurance
Property & casualty

🧓 Pension Products

Defined Benefit (DB)
Defined Contribution (DC)

⚠️ Exam Focus

DB → employer risk
DC → employee risk
Adverse selection + moral hazard

🔴 Module 3: Fund Management

📊 Investment Products

🔹 Mutual Funds

Active management
NAV-based pricing

🔹 ETFs

Passive tracking
Exchange traded

🔹 Hedge Funds

Common Strategies:

Long/Short equity
Global macro
Event-driven
Arbitrage

⚠️ Exam Focus

Hedge funds → high leverage + high risk
ETFs → low cost + liquidity

🔴 Module 4: Derivatives (VERY IMPORTANT)

🔹 1. Forward Contracts

OTC
Customized
No daily settlement

🔹 2. Futures Contracts

Exchange traded
Standardized
Mark-to-market daily

⚠️ Key Concept

Margin system:
- Initial margin
- Variation margin

🔹 3. Options

Types

Call → right to buy
Put → right to sell

Styles

European
American

🔹 4. Swaps

Types

Interest rate swap
Currency swap
Credit default swap (CDS)

⚠️ Exam Focus (VERY HIGH)

Futures vs Forwards
Option payoff logic
Swap = exchange of cash flows

🔴 Module 5: Exchanges vs OTC

🔹 Exchange-Traded Products

Futures
Options

Features:

Standardized
Central clearing
Low counterparty risk

🔹 OTC Products

Forwards
Swaps
CDS

Features:

Customization
Higher credit risk

⚠️ Exam Focus

CCP reduces default risk
OTC → counterparty exposure

🔴 Module 6: Futures Markets (DETAILED)

📊 Key Product Features

🔹 Open Interest

Total outstanding contracts

🔹 Trading Volume

Daily trades (can exceed open interest)

🔹 Contract Specifications

Underlying asset
Contract size
Delivery terms

⚠️ Exam Focus

Most futures closed before delivery
Exchange acts as counterparty

🔴 Module 7+: Structured Products (CRITICAL)

🧩 Products

🔹 MBS (Mortgage-Backed Securities)

Pool of mortgages

🔹 ABS (Asset-Backed Securities)

Pool of loans (credit cards, auto loans)

🔹 CDO (Collateralized Debt Obligations)

Tranches:
- Senior (low risk)
- Mezzanine
- Equity (high risk)

⚠️ Exam Focus

Tranching = risk redistribution
Key cause of 2008 financial crisis

🔴 Cross-Module: Key Product Users

👥 Participants

Hedgers → reduce risk
Speculators → take risk
Arbitrageurs → exploit mispricing

🧠 FINAL MASTER SUMMARY

📌 Product Hierarchy (VERY IMPORTANT)

1. Basic Products

Equity
Bonds
Loans

2. Derivatives

Forwards
Futures
Options
Swaps

3. Structured Products

4. Investment Vehicles

Mutual funds
ETFs
Hedge funds

5. Risk Transfer Products

Insurance
CDS

⚡ ULTRA QUICK REVISION (10 SECONDS)

Banks → deposits + loans
Insurance → risk pooling
Funds → investments
Derivatives → risk transfer
Structured → risk slicing

Perfect—this is exactly the level that pushes you into FRM pass zone 🔥

I’ll give you:

Tricky exam-level MCQs (Book 3)
Numerical shortcuts for derivatives (high impact)

🧠 PART 1: 🔥 TRICKY FRM EXAM QUESTIONS (BOOK 3)

❓ Q1. Futures vs Forward (Trap Question)

A trader prefers futures over forwards mainly because:

A. Futures eliminate price risk

B. Futures eliminate liquidity risk

C. Futures reduce counterparty risk

D. Futures guarantee profit

✅ Answer: C

👉 Because exchange + margin + CCP reduce counterparty risk

❓ Q2. Open Interest Logic

If one trader opens a long position and another opens a new short position:

A. Open interest increases

B. Open interest decreases

C. Open interest stays same

D. Cannot be determined

✅ Answer: A

👉 New contracts created → open interest increases

❓ Q3. Repo Confusion (Very Common)

Repo is best described as:

A. Sale of securities without obligation

B. Borrowing unsecured funds

C. Collateralized borrowing

D. Equity financing

✅ Answer: C

❓ Q4. Hedge Fund Risk

Which risk is most associated with hedge funds?

A. Credit risk only

B. Liquidity + leverage risk

C. Inflation risk

D. Interest rate risk only

✅ Answer: B

❓ Q5. OTC vs Exchange (Trap)

Which statement is TRUE?

A. OTC has no counterparty risk

B. Exchange contracts are customized

C. OTC contracts are standardized

D. Exchange reduces counterparty risk

✅ Answer: D

❓ Q6. Option Trick

A call option gives:

A. Obligation to buy

B. Right to buy

C. Right to sell

D. Obligation to sell

✅ Answer: B

❓ Q7. CDS Understanding

A Credit Default Swap transfers:

A. Market risk

B. Credit risk

C. Liquidity risk

D. Currency risk

✅ Answer: B

❓ Q8. Structured Products (2008 Crisis)

Which contributed MOST to the crisis?

A. Equity markets

B. Government bonds

C. Structured products (CDOs)

D. ETFs

✅ Answer: C

❓ Q9. Margin System (Trap)

Variation margin is used to:

A. Open position

B. Cover daily losses

C. Pay final settlement

D. Reduce interest rates

✅ Answer: B

❓ Q10. Adverse Selection

Adverse selection occurs:

A. After contract signing

B. Before contract signing

C. During settlement

D. During trading

✅ Answer: B

🧠 PART 2: ⚡ NUMERICAL SHORTCUTS (DERIVATIVES)

🔴 1. Futures Pricing Shortcut

⭐ Formula

F = S \times (1 + r)^T

⚡ Shortcut (Exam Hack)

If T is small, use: 👉 F ≈ S + S \times r \times T

Example:

Spot = 100

Rate = 5%

Time = 1 year

👉 F ≈ 100 + 5 = 105

🔴 2. Futures P&L Shortcut

⭐ Formula

\text{P&L} = (F_{new} – F_{old}) \times \text{contract size}

⚡ Shortcut

Long → profit if price ↑
Short → profit if price ↓

Example:

Bought futures at 100, now 105

Contract = 100 units

👉 Profit = 5 × 100 = 500

🔴 3. Option Payoff Shortcut (VERY IMPORTANT)

⭐ Call Option

\max(S-K,0)

👉 Shortcut:

If S > K → profit
If S < K → 0

⭐ Put Option

\max(K-S,0)

👉 Shortcut:

If S < K → profit
If S > K → 0

🔴 4. Break-even Shortcut (Options)

Call Option

👉 Break-even = Strike + Premium

Put Option

👉 Break-even = Strike − Premium

🔴 5. Swap Shortcut (Interest Rate Swap)

⚡ Concept

Fixed vs Floating exchange
Net payment only

Shortcut:

👉 Payment = Difference × Notional

Example:

Fixed = 5%

Floating = 4%

Notional = 1M

👉 Payment = 1% × 1M = 10,000

🔴 6. CDS Shortcut

⚡ Concept

Premium paid until default
If default → protection seller pays

Shortcut:

👉 Loss = Notional × (1 − Recovery Rate)

Example:

Notional = 1M

Recovery = 40%

👉 Loss = 1M × 0.6 = 600,000

🧠 FINAL EXAM STRATEGY (VERY IMPORTANT)

🔥 Focus Areas

Futures vs forwards
Option payoff logic
Swap cash flow
CDS concept

⚡ Speed Tricks

Don’t derive formulas → memorize shortcuts
Solve payoff questions visually
Always check long vs short position

Perfect—let’s do FRM Book 4: Valuation & Risk Models in the same crisp, exam-focused style 👇

📘 FRM BOOK 4 — 🔥 ULTRA-SHORT SUMMARY

🧠 1. WHAT IS FINANCIAL RISK MEASUREMENT?

👉 Quantifying potential losses in portfolios

🎯 Goal:

Measure risk
Control risk
Allocate capital

🧠 2. MEAN–VARIANCE FRAMEWORK

Key Idea:

👉 Return vs Risk trade-off

Mean = expected return
Variance = risk

⚡ Formula Insight

👉 Higher return → higher risk

⚠️ Limitation

Assumes normal distribution
Fails in extreme events (tail risk)

🧠 3. NORMAL DISTRIBUTION (VERY IMPORTANT)

Properties:

Symmetrical
Mean = Median = Mode

⚡ Exam Insight

👉 Real markets ≠ normal (fat tails exist)

🧠 4. VALUE AT RISK (VaR) — ⭐ MOST IMPORTANT

Definition:

👉 Maximum loss at a given confidence level

Example:

👉 95% VaR = “loss won’t exceed X 95% of time”

⚡ Types of VaR

Historical VaR
Variance–Covariance (Delta-Normal)
Monte Carlo

⚡ Shortcut

👉 VaR = threshold loss, not worst-case

🧠 5. EXPECTED SHORTFALL (ES)

Definition:

👉 Average loss beyond VaR

⚡ Insight

👉 ES > VaR (always more conservative)

🔥 Exam Favorite

👉 ES is a coherent risk measure, VaR is not

🧠 6. COHERENT RISK MEASURES

Must satisfy:

Monotonicity
Subadditivity
Positive homogeneity
Translation invariance

⚡ Key Point

👉 VaR ❌ (fails subadditivity sometimes)

👉 ES ✅

🧠 7. DELTA-NORMAL MODEL

Idea:

👉 Linear approximation of portfolio

Assumptions:

Normal returns
Linear instruments

⚠️ Limitation

👉 Not good for options (nonlinear)

🧠 8. HISTORICAL SIMULATION

Process:

👉 Use past returns to simulate risk

⚡ Pros:

No assumptions

⚠️ Cons:

Depends on past data

🧠 9. MONTE CARLO SIMULATION

Idea:

👉 Simulate thousands of scenarios

⚡ Pros:

Very flexible

⚠️ Cons:

Computationally expensive

🧠 10. VOLATILITY (CORE CONCEPT)

Types:

Historical volatility
Implied volatility

⚡ Key Model

👉 GARCH (time-varying volatility)

⚠️ Insight

👉 Volatility is not constant

🧠 11. CORRELATION

Definition:

👉 Relationship between assets

⚡ Key Point

👉 Diversification works only if correlation < 1

⚠️ Crisis Insight

👉 Correlations ↑ during crisis (diversification fails)

🧠 12. CREDIT RISK MODELS

Components:

Probability of default (PD)
Loss given default (LGD)
Exposure at default (EAD)

⚡ Formula Insight

👉 Expected Loss = PD × LGD × EAD

🧠 13. OPTION PRICING (BLACK-SCHOLES)

Core Idea:

👉 Price using risk-neutral world

Assumptions:

No arbitrage
Constant volatility
Continuous trading

⚡ Key Insight

👉 Price depends on:

Stock price
Strike
Time
Volatility
Interest rate

🧠 14. RISK-NEUTRAL VALUATION

Idea:

👉 Assume investors are risk-neutral

Process:

Expected payoff
Discount at risk-free rate

⚡ Shortcut

👉 Use risk-free rate instead of actual return

🧠 15. MODEL RISK

Definition:

👉 Risk of wrong model assumptions

⚠️ Sources:

Wrong inputs
Wrong assumptions
Overfitting

🧠 FINAL 10 EXAM TAKEAWAYS 🚀

🔥 MUST REMEMBER

VaR = threshold loss
ES = average worst loss
ES is better than VaR
Delta-normal fails for options
Historical = past-based
Monte Carlo = simulation-based
Volatility is time-varying
Correlation increases in crisis
Black-Scholes = risk-neutral pricing
Models are always imperfect

⚡ ULTRA-FAST REVISION (30 sec)

👉 VaR = max loss (confidence level)

👉 ES = tail loss

👉 Volatility = risk measure

👉 Correlation = diversification driver

👉 Black-Scholes = option pricing

👉 Monte Carlo = simulation

Below is your Book 4: Valuation & Risk Models — FRM revision pack.

📘 1. Numerical Cheat Sheet — Book 4

1. Portfolio Mean

\mu_p = w_1\mu_1+w_2\mu_2

2. Portfolio Variance

\sigma_p^2=w_1^2\sigma_1^2+w_2^2\sigma_2^2+2w_1w_2\rho\sigma_1\sigma_2

3. Parametric VaR

VaR = Z \times \sigma \times V

4. Time Scaling VaR

VaR_T = VaR_1 \times \sqrt{T}

5. Expected Shortfall

ES = E(Loss \mid Loss > VaR)

6. Expected Loss — Credit Risk

EL = PD \times LGD \times EAD

7. Recovery / Loss Given Default

LGD = 1 – Recovery\ Rate

8. Delta Approximation

\Delta P = \delta \Delta S

9. Delta-Gamma Approximation

\Delta P = \delta \Delta S + \frac{1}{2}\gamma(\Delta S)^2

10. EWMA Volatility

\sigma_n^2 = \lambda\sigma_{n-1}^2+(1-\lambda)r_{n-1}^2

11. GARCH(1,1)

\sigma_n^2=\omega+\alpha r_{n-1}^2+\beta\sigma_{n-1}^2

12. Bond Price Approximation

\frac{\Delta P}{P} \approx -D\Delta y+\frac{1}{2}C(\Delta y)^2

13. DV01

DV01 = Dollar\ change\ for\ 1bp\ yield\ move

14. Option Payoff

Call:

\max(S-K,0)

Put:

\max(K-S,0)

Book 4 covers VaR, ES, coherent risk measures, historical simulation, delta-normal VaR, Monte Carlo, volatility models, credit risk, stress testing, discounting, bond risk, binomial trees, Black-Scholes, and Greeks.

📊 2. VaR + ES Solved Examples

Example 1: Simple VaR

Portfolio value = £10,000,000

Daily volatility = 2%

Confidence = 95%

Z = 1.65

VaR = 10,000,000 \times 0.02 \times 1.65

VaR = £330,000

Meaning: there is a 5% chance loss exceeds £330,000 in one day.

Example 2: 10-day VaR

1-day VaR = £330,000

Time = 10 days

VaR_{10} = 330,000 \times \sqrt{10}

VaR_{10} = £1,043,551

Shortcut: multiply by √T, not by T.

Example 3: Historical Simulation VaR

Worst losses from 500 scenarios:

1st = £7.8m

2nd = £6.5m

3rd = £4.6m

4th = £4.3m

5th = £3.9m

For 99% VaR:

500 \times 1\% = 5

So VaR = 5th worst loss = £3.9m.

Expected Shortfall = average of losses worse than VaR:

ES = \frac{7.8+6.5+4.6+4.3}{4}

ES = £5.8m

Book 4 uses this same historical simulation logic: with 500 scenarios, 99% VaR is the fifth-worst loss, and ES is the average of losses beyond VaR.

Example 4: Discrete Expected Shortfall

Loss outcomes:

Loss	Probability
£10m	3%
£3m	7%
Gain £1m	90%

At 95% confidence, tail = 5%.

Worst 5% contains:

3% chance of £10m loss
2% chance of £3m loss

ES = \frac{3}{5}(10)+\frac{2}{5}(3)

ES = 6+1.2 = £7.2m

⚠️ 3. FRM Exam Traps — Book 4

Trap 1: VaR is not worst-case loss

VaR only says the threshold. It does not say how bad losses are beyond that threshold.

Trap 2: ES is better than VaR

VaR can fail subadditivity.

ES is coherent and captures tail severity.

Trap 3: Do not multiply VaR by time

Wrong:

VaR_{10} = 10 \times VaR_1

Correct:

VaR_{10} = \sqrt{10} \times VaR_1

Trap 4: Delta-normal fails for options

Delta-normal assumes linearity. Options are nonlinear, so gamma matters.

Trap 5: Historical simulation is not assumption-free in practice

It avoids normality assumptions, but it assumes the past is relevant to the future.

Trap 6: Monte Carlo is flexible but not magic

Bad assumptions → bad simulation. More simulations do not fix a wrong model.

Trap 7: Correlation increases in crisis

Diversification may fail when you need it most.

Trap 8: Implied volatility is forward-looking

Historical volatility looks backward.

Implied volatility reflects market expectations.

Trap 9: Credit ratings are not guarantees

Ratings can lag market information and may fail during stress.

Trap 10: Duration ignores convexity

For large yield changes, use duration + convexity, not duration alone.

🧠 4. Memory Tricks for Book 4 Models

VaR

“VaR = Very Approximate Risk”

It gives a cutoff, not the full disaster.

ES

“ES = Extreme Scenario average”

Average loss after VaR is breached.

Coherent Risk

Remember: M-S-H-T

Monotonicity
Subadditivity
Homogeneity
Translation invariance

Historical Simulation

“History repeats — maybe.”

Good because no normality assumption. Weak because history may not repeat.

Delta-Normal

“Delta likes straight lines.”

Works well for linear portfolios, weak for options.

Monte Carlo

“Many random worlds.”

Powerful but depends on assumptions.

EWMA

“Recent returns matter more.”

Higher λ = slower reaction.

Lower λ = faster reaction.

GARCH

“Volatility remembers and returns.”

It reacts to shocks and mean-reverts.

Duration

“Duration = first-order bond sensitivity.”

Convexity

“Convexity corrects duration.”

Black-Scholes

“BSM = option price from risk-neutral world.”

Use risk-free rate, not expected stock return.