CFA L1 | Derivatives | Free Study Tools

Learning Module #1 – Derivative Instruments and Market Features

What is a Derivative?

Derivative

A financial security whose value is derived from an underlying asset.

The derivative itself has no independent value
Its payoff depends entirely on how the underlying asset performs

Common Underlyings

Equities: individual stocks, equity indices, volatility
Fixed Income: bonds, interest rates
Commodities: oil, gold, agricultural products
Currencies: FX rates
Indices: stock, bond, or commodity indices

Analogy:
A derivative is like a shadow — it moves only because the object (underlying asset) moves.

Why Derivatives Exist (Big Picture)

Derivatives are used to:

Hedge risk (reduce uncertainty)
Speculate (take directional views)
Arbitrage (exploit mispricing)
Transfer risk to parties willing to bear it

Derivatives do not eliminate risk — they reallocate it.

Payoff Dependence

Derivative returns depend on:
- Price level of underlying
- Price changes
- Volatility
- Time
Small changes in the underlying can lead to large % changes in derivative value

Analogy:
Derivatives are financial leverage in pure form — like using a crowbar instead of your hands.

Exchange-Traded vs Over-the-Counter (OTC) Derivatives

Exchange-Traded Derivatives

Key Characteristics

Standardized contracts
Trade on a centralized exchange
Clearinghouse guarantees performance
High liquidity and price transparency
Low counterparty risk

Examples

Futures
Exchange-traded options

Analogy:
Exchange-traded derivatives are like buying a concert ticket from Ticketmaster — standardized, guaranteed, and regulated.

Over-the-Counter (OTC) Derivatives

Key Characteristics

Customized contracts
No central trading location
Trades negotiated directly between parties
Dealers or market makers connect buyers and sellers
No automatic clearinghouse guarantee

Risks

Less transparency
Less liquidity
Higher counterparty risk

Examples

Swaps
Forward contracts
Customized options

Analogy:
OTC derivatives are like private contracts — flexible, but you must trust the counterparty.

Counterparty Risk

Risk that the other party fails to honor contractual obligations.

Much higher in OTC markets
Minimal in exchange-traded markets due to clearinghouses

Central Counterparties (CCPs)

Why CCPs Were Created

To reduce systemic risk
To lower counterparty risk in OTC markets

How CCPs Work

CCP becomes the buyer to every seller
CCP becomes the seller to every buyer
Requires:
- Initial margin
- Variation margin
Enforces daily settlement

Analogy:
A CCP is like an escrow service — it steps in between both sides to guarantee the deal.

Market Participants

Hedgers

Use derivatives to reduce existing risk
Example: airline hedging fuel prices

Speculators

Take views on price direction or volatility
Accept risk for potential return

Arbitrageurs

Exploit pricing inconsistencies
Help enforce law of one price

Speculators and arbitrageurs provide liquidity, benefiting hedgers.

Key Risks in Derivatives Markets

Risk Type	Description
Market Risk	Underlying price moves unfavorably
Counterparty Risk	Other party defaults
Liquidity Risk	Inability to exit position
Operational Risk	Failures in systems/processes
Legal Risk	Contract enforceability issues

Standardization vs Customization Trade Off

Feature	Exchange-Traded	OTC
Contract Terms	Standardized	Customized
Liquidity	High	Lower
Transparency	High	Low
Counterparty Risk	Low	High
Flexibility	Low	High

Summary Table

Core Concepts:

Concept	Meaning
Derivative	Value depends on an underlying asset
Underlying	Asset determining derivative payoff
Exchange-Traded	Standardized, cleared, transparent
OTC	Customized, bilateral, higher risk
CCP	Central guarantor of trades

Key Takeaways

Derivatives derive value from an underlying asset, not standalone worth
Exchange-traded derivatives minimize counterparty risk via clearinghouses
OTC derivatives offer flexibility but introduce counterparty and liquidity risk
Central counterparties were introduced to reduce systemic risk
Derivatives transfer risk, they do not eliminate it
Market participants include hedgers, speculators, and arbitrageurs

Learning Module #2 – Forward Commitments and Contingent Claims

Firm Commitments

Firm Commitment

A contract in which both counterparties are obligated to complete the transaction at maturity.

Key idea:
There is no choice at expiration — both sides must perform.

Analogy:
A firm commitment is like agreeing today to buy a house in 3 months — backing out is not an option.

Forward Contracts

Definition

An agreement to buy or sell an asset in the future at a price agreed upon today (the forward price).

Positions

Buyer: Long position
Seller: Short position

Settlement Date Outcomes

If spot price > forward price:
- Long gains
- Short loses
If spot price < forward price:
- Short gains
- Long loses

Settlement Methods

Physical (actual) delivery
Cash settlement (difference between spot and forward price)

Market Features

Customized contracts
Traded OTC
No clearinghouse
Higher counterparty risk

Analogy:
A forward is like a custom-tailored suit — fits perfectly, but you can’t easily resell it.

Futures Contracts

Definition

Similar to forwards, but with key differences:

Key Features

Standardized contracts
Exchange-traded
Regulated
Clearinghouse guarantees performance
Daily settlement (mark-to-market)

Daily Settlement (Mark-to-Market)

Gains/losses are realized daily
Reduces accumulation of losses
Limits counterparty risk

Margin System

Initial Margin

Good-faith deposit to enter a futures position

Maintenance Margin

Minimum account balance required
If balance < maintenance margin → margin call
Investor must deposit funds to return to initial margin

Analogy:
Margin is a security deposit — if it gets too low, you must top it up.

How Futures Avoid Defaults

Price Limits

Restrict how much price can move in a day

Circuit Breakers

Temporarily halt trading if extreme price moves occur

CFA Insight:
These mechanisms reduce panic and systemic risk.

Swaps

Definition

A series of forward contracts where two parties exchange cash flows over time.

Key Characteristics

No initial exchange of principal
Customized OTC contracts
Not traded on exchanges

Plain Vanilla Interest Rate Swap

One party pays fixed interest
Other party pays floating interest
Payments netted at each settlement date

Analogy:
A swap is like agreeing to trade lunch meals every day — you swap fixed for variable.

Contingent Claims

Definition

Contracts whose payoff depends on whether a future event occurs.

Buyer has the right, not obligation
Seller has the obligation

Examples

Options
Credit derivatives

Analogy:
Contingent claims are like insurance — you get paid only if something happens.

Option Contracts

Option Basics

Buyer (holder) pays a premium
Buyer gets a right, not obligation
Seller (writer) receives premium and takes obligation

Call Options

Call Option

Gives the holder the right to buy an asset at a strike price before expiration.

Party	Position
Buyer	Long call
Seller	Short call

Payoff Rules

Exercised if stock price > strike price
Not exercised if stock price ≤ strike price
Break-even price:

$Breakeven = Strike Price + Premium$

Risk/Return

Long call: unlimited upside, max loss = premium
Short call: max gain = premium, unlimited loss

Analogy:
A call option is a down payment on upside potential.

Put Options

Put Option

Gives the holder the right to sell an asset at a strike price.

Party	Position
Buyer	Long put
Seller	Short put

Payoff Rules

Exercised if stock price < strike price
Not exercised if stock price ≥ strike price

Risk/Return

Long put: max gain when stock → 0; max loss = premium
Short put: max gain = premium; max loss when stock → 0

Analogy:
A put option is price insurance — protection against falling prices.

Credit Derivatives

Definition

Instruments that compensate bondholders if a credit event occurs.

Credit Events Include

Borrower default
Credit rating downgrade

Analogy:
Credit derivatives are insurance policies on bonds.

Summary Tables

Forward vs Futures

Feature	Forward	Futures
Trading Venue	OTC	Exchange
Standardization	Custom	Standard
Clearinghouse	No	Yes
Settlement	At maturity	Daily
Counterparty Risk	High	Low

Options Payoff Summary

Position	Max Gain	Max Loss
Long Call	Unlimited	Premium
Short Call	Premium	Unlimited
Long Put	Strike − Premium	Premium
Short Put	Premium	Strike

Key Takeaways

Firm commitments create obligations for both parties
Forwards are customized but carry high counterparty risk
Futures reduce default risk via daily settlement & margining
Swaps are series of forward contracts with netted payments
Contingent claims give rights to buyers and obligations to sellers
Options have asymmetric payoffs
Long options have limited downside; short options have potentially large losses
Credit derivatives protect against credit events

Learning Module #3 – Benefits, Risks & Issuer/Investor Uses

Benefits of Derivatives

Derivatives improve how financial markets function, price risk, and allocate capital.

Greater Market Efficiency

Allow faster incorporation of information into prices
Facilitate arbitrage → enforce law of one price

Analogy:
Derivatives act like express lanes in markets — information travels faster.

Hedging Risk

Transfer unwanted risk to parties willing to accept it
Stabilize cash flows and portfolio values

Example:

Airline hedges fuel costs with oil futures
Bank hedges interest rate exposure with swaps

Information Gathering & Price Discovery

Derivative prices embed market expectations
Used to infer:
- Expected future prices
- Expected volatility (implied volatility)

Options markets often reveal volatility expectations before spot markets.

Risk Allocation & Transfer

Risk flows to investors most willing and able to bear it
Improves overall economic efficiency

Analogy:
Derivatives are like insurance marketplaces — risk goes to specialists.

Operational Advantages

Lower Trading Costs

Fewer transactions vs cash markets

Higher Liquidity

Easier to enter/exit positions

Lower Cash Requirements

Margin vs full notional value

Ability to Short

Easier than shorting physical assets

Analogy:
Derivatives are financial power tools — less effort, more impact.

Risks of Derivatives

Derivatives magnify both gains and losses.

Speculation & Leverage Risk

Small underlying moves → large derivative value changes
Can amplify losses rapidly

Exam warning:
Leverage is the most commonly tested derivative risk.

Lack of Transparency

Especially in OTC markets
Hard to observe prices, exposures, or risks
Can obscure true financial positions

Basis Risk

Occurs when the derivative does not perfectly offset the underlying exposure.

Causes:

Differences in:
- Underlying asset
- Maturity
- Location
- Quality

Analogy:
Basis risk is like buying the wrong size umbrella — partial protection only.

Liquidity Risk

Inability to close positions without significant price impact
More severe during market stress

Timing (Cash Flow) Risk

Derivative cash flows occur at different times than underlying exposures
Creates mismatch risk

Counterparty Risk

Other party fails to perform
More prominent in OTC derivatives

Systemic Risk

Failure of one major participant can affect entire system
Interconnected derivative positions amplify shocks

CFA Insight:
This risk motivated the creation of central counterparties (CCPs).

Uses of Derivatives by Issuers

Issuers use derivatives mainly for risk management, not speculation.

Cash Flow Hedge

Purpose:
Offset variability in future cash flows.

Examples:

Floating-rate debt → interest rate swap
Forecasted commodity purchases → commodity futures

Analogy:
Cash flow hedges smooth monthly paychecks.

Fair Value Hedge

Purpose:
Offset changes in the market value of assets or liabilities.

Examples:

Fixed-rate bond value hedged with interest rate swap
Inventory value hedged with commodity futures

Net Investment Hedge

Purpose:
Hedge foreign exchange risk from foreign subsidiaries.

Instruments:

Currency swaps
Currency forwards

Analogy:
Net investment hedges protect overseas “branches” from currency storms.

Uses of Derivatives by Investors

Replicating Cash Market Strategies

Use derivatives to mimic:
- Equity exposure
- Bond exposure
- Commodity exposure

Advantage:
Lower cost and faster execution.

Hedging Portfolio Risk

Protect against:
- Market downturns
- Interest rate changes
- Currency movements

Modifying or Adding Exposures

Increase/decrease:
- Duration
- Equity beta
- Volatility exposure

Analogy:
Derivatives are portfolio “dials” — turn risk up or down instantly.

Summary Tables

Benefits vs Risks

Benefits	Risks
Efficient pricing	Leverage risk
Risk transfer	Counterparty risk
Liquidity	Liquidity risk
Low cost	Basis risk
Short selling	Systemic risk

Issuer Hedge Types

Hedge Type	What It Protects	Typical Instruments
Cash Flow Hedge	Future cash flows	Swaps, futures
Fair Value Hedge	Market value	Swaps, futures
Net Investment Hedge	FX exposure	Currency swaps/forwards

Key Takeaways

Derivatives enhance market efficiency and price discovery
They allow precise risk transfer and hedging
Leverage magnifies gains and losses
Basis risk means hedges are rarely perfect
OTC derivatives introduce transparency and counterparty risk
Issuers hedge cash flows, values, and FX exposure
Investors use derivatives to hedge, replicate, and modify exposures

Learning Module #4 – Arbitrage Replication & Cost of Carry

Arbitrage

What Is Arbitrage?

Arbitrage is earning a riskless profit from a mispricing by:

Buying an asset at a lower price
Selling the same (or economically identical) asset at a higher price

True arbitrage has no risk, no net investment, and non-negative profit.

Law of One Price

If two assets or portfolios have identical cash flows, they must have the same price.

If prices differ → arbitrage opportunity exists
Markets tend to eliminate arbitrage quickly

Analogy:
Two identical phones shouldn’t sell for different prices — if they do, resellers step in.

Arbitrage via Mispricing (Discounting Error)

If:

Discounted future value ≠ present value

Then:

Buy the cheaper version
Sell the overpriced version
Lock in profit

Hedged Portfolio (Riskless Portfolio)

Combine a derivative + underlying asset
Structure eliminates uncertainty
Produces a certain payoff at maturity

Result:
Return on this hedged portfolio must equal the risk-free rate.

If return > risk-free rate → arbitrage exists

Analogy:
A hedged portfolio is like locking in a fixed paycheck regardless of market weather.

Risk-Neutral (No-Arbitrage) Pricing

Derivatives are priced so arbitrage is impossible
Price = value that makes expected return = risk-free rate
This is called risk-neutral pricing

Forward Pricing (No-Arbitrage Condition)

$S_{0} = \frac{F_{0} (T)}{(1 + r_{f})^{T}}$

Spot price today equals the discounted forward price
If violated → arbitrage opportunity

Replication

Replication Principle

A derivative can be replicated using:

The underlying asset
Borrowing or lending at the risk-free rate

If two strategies produce the same payoff at time T, they must have the same price today.

Replication Logic

$Asset + Derivative = Risk-free payoff at T$

Discounting this payoff at the risk-free rate gives today’s value
Equivalent to holding a risk-free asset

Analogy:
Replication is like rebuilding a Lego model two different ways — if the final model is identical, the cost must be the same.

Cost of Carry

What Is Cost of Carry?

The net cost (or benefit) of holding an asset until maturity. $Cost of Carry = Benefits - Costs$

Benefits of Holding an Asset

Dividends (equities)
Interest payments
Convenience yield (physical commodities)

Costs of Holding an Asset

Storage
Insurance
Financing costs (implicit via interest rates)

Spot Price with Cost of Carry

$S_{0} = \frac{F_{0} (T)}{(1 + r_{f})^{T}} + P V (Benefits) - P V (Costs)$

Forward price adjusted for:
- Holding benefits
- Holding costs

Interpretation

High benefits → higher spot price
High costs → lower spot price
Forward price reflects net cost of carry

Analogy:
Owning a house has benefits (rent) and costs (maintenance) — net effect determines value.

Arbitrage & Cost of Carry in FX Markets

If:

You can borrow at a lower domestic risk-free rate
Lend at a higher foreign risk-free rate

Then:

FX forward prices adjust to prevent arbitrage

Higher future exchange rates offset interest rate differentials

Exam-Focused Intuition

Arbitrage forces prices into no-arbitrage equilibrium
Derivative pricing is based on replication, not expectations
Cost of carry explains why forward prices differ from spot prices
If risk-free returns differ → prices adjust to eliminate profit opportunities

Summary Tables

Arbitrage Concepts

Concept	Meaning
Arbitrage	Riskless profit from mispricing
Law of One Price	Same cash flows → same price
Hedged Portfolio	Risk eliminated
Risk-Neutral Pricing	Return = risk-free rate

Cost of Carry Components

Component	Examples
Benefits	Dividends, interest, convenience yield
Costs	Storage, insurance
Net Carry	Benefits − Costs

Key Takeaways

Arbitrage exists when identical cash flows have different prices
Law of one price underpins all derivative pricing
Hedged portfolios must earn the risk-free rate
Risk-neutral pricing ensures no-arbitrage
Replication ties derivative prices to underlying assets
Cost of carry explains forward vs spot price differences
FX forward prices adjust to eliminate interest rate arbitrage

Learning Module #5 – Pricing & Valuation of Forward Contracts

Price vs. Value of a Forward Contract

Price of a Forward

The contracted forward price agreed at initiation
Never changes over the life of the contract

Analogy:
The forward price is like the sticker price written on a receipt — it doesn’t change.

Value of a Forward

The current economic worth of the contract
Changes over time as spot prices and interest rates move
Price = fixed number in the contract
Value = what the contract is worth today

Value of a Forward at Time t

$V_{t} = S_{t} - P V_{t} ⁣ [F_{0} (T)]$

Difference between:
- Current spot price
- Present value of the contracted forward price

Present Value of Forward Price

$P V_{t} ⁣ [F_{0} (T)] = \frac{F_{0} (T)}{(1 + r_{f})^{(T - t)}}$

At Initiation

$V_{0} = 0$

No arbitrage → neither party pays anything upfront

At Expiration

$V_{T} = S_{T} - F_{0} (T)$

No discounting needed at maturity

Analogy:
At expiration, the forward is settled like paying today’s price minus the price you locked in earlier.

Forward Value with Costs and Benefits

If the underlying provides benefits (e.g., dividends) or costs (e.g., storage): $V_{t} = S_{t} + P V (Benefits) - P V (Costs) - P V_{t} ⁣ [F_{0} (T)]$

Interpretation:

Benefits increase forward value
Costs reduce forward value

Forward & Spot Rates

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Spot Rates

Interest rates for immediate borrowing/lending to a specific maturity

Forward Rates

Implied future interest rates
Derived from current spot rates

Forward rates are implied by today’s yield curve, not forecasts.

Discount Factors

Definition

A discount factor is the present value of one unit of currency received in the future.
$D F_{t} = \frac{1}{(1 + s_{t})^{t}}$

Where $s_{t}$ st = spot rate to maturity $t$ t

Uses

Discount individual cash flows
Build present values
Derive forward rates
Value derivatives with varying maturities

Analogy:
Discount factors are time-travel converters — they translate future money into today’s dollars.

Forward Rates from Spot Rates (Intuition)

If spot rates are known:
- You can bootstrap discount factors
- Then derive forward rates
Ensures no-arbitrage consistency across maturities

Forward Rate Agreements (FRAs)

What Is an FRA?

A derivative whose underlying is a future interest rate.

Most commonly based on LIBOR
Used to lock in a borrowing or lending rate in the future
Parties exchange:
- Fixed rate (agreed today)
- Floating rate (market rate at settlement)

Purpose of an FRA

Hedge interest rate risk
Protect against rate increases (borrowers) or rate decreases (lenders)

Analogy:
An FRA is like setting a thermostat today for a room you’ll use later — you lock in comfort regardless of weather.

FRA Settlement & Net Payment

Only net cash flow is exchanged
No exchange of principal

Net Payment Formula

$Net Payment = ({MRR}_{b - a} - Fixed Rate) \times Notional Principal \times Period$

Where:

${MRR}_{b - a}$ = market reference rate for the period
Period = year fraction

Who Pays Whom?

If market rate > fixed rate → fixed-rate receiver gets paid
If market rate < fixed rate → fixed-rate payer gets paid

Summary Tables

Forward Contract: Price vs Value

Concept	Meaning
Forward Price	Fixed contract price
Forward Value	Current economic worth
Value at Initiation	0
Value at Expiration	S_T – F₀(T)

FRA Overview

Feature	Description
Underlying	Future interest rate (LIBOR)
Purpose	Hedge interest rate risk
Cash Exchange	Net settlement only
Risk Hedged	Interest rate movements

Key Takeaways

Forward price is constant, forward value fluctuates
At initiation, no-arbitrage → forward value = 0
Forward value equals spot minus discounted forward price
Costs and benefits must be included in valuation
Discount factors convert future cash flows into present value
Forward rates are implied by spot rates
FRAs lock in future borrowing/lending rates and settle in cash

Learning Module #6 – Pricing & Valuation of Futures Contracts

Futures vs Forwards – Pricing Differences

Although futures and forwards have similar payoffs at maturity, their pricing can differ before maturity due to daily settlement and interest rate effects.

Forward Contracts (Recap)

Customized / tailored
Traded OTC
No clearinghouse
No daily settlement
Gains/losses realized only at maturity
Higher counterparty risk

Analogy:
A forward is like agreeing to settle the bill at the end of the month — no cash moves until the end.

Futures Contracts (Recap)

Standardized
Exchange-traded
Regulated
Guaranteed by a clearinghouse
Daily settlement (mark-to-market)
Gains/losses credited or debited every day

Analogy:
A futures contract is like paying or getting paid daily as prices change.

Mark-to-Market & Futures Valuation

Daily Settlement (Mark-to-Market)

Futures positions are revalued each trading day
Daily gains are:
- Added to margin account
- Available for withdrawal
Daily losses:
- Subtracted from margin account
- May trigger margin calls

Because cash flows occur daily, the timing of gains and losses matters.

Interest Rates & Futures Prices

Key Relationship

Futures prices are positively correlated with interest rates

Why This Happens

When interest rates rise:
- Futures prices tend to rise
- Long futures positions receive daily gains
- Gains can be reinvested at higher rates
This makes futures more attractive than forwards in rising-rate environments

Opposite Case (Intuition)

When interest rates fall:
- Futures prices tend to fall
- Long futures holders receive losses earlier
- Losses are financed at lower rates
In this case, forwards may be relatively more attractive

Analogy:
Futures are like getting paid early — if interest rates are high, early cash is more valuable.

Futures vs Forwards – Pricing Implications

Because of daily settlement:

Futures prices may be:
- Higher than forward prices when interest rates and futures prices are positively correlated
- Lower than forward prices when they are negatively correlated

This distinction matters only when interest rates are stochastic (changing).

Futures Value over Time

At initiation:
- Futures value = 0
After initiation:
- Value realized daily, not accumulated
At maturity:
- Futures and forwards converge to the same payoff

Summary Tables

Futures vs Forwards

Feature	Forwards	Futures
Trading Venue	OTC	Exchange
Standardization	Customized	Standardized
Clearinghouse	No	Yes
Daily Settlement	No	Yes
Counterparty Risk	High	Low
Cash Flow Timing	At maturity	Daily

Interest Rates & Pricing

Scenario	More Attractive
Rising interest rates	Futures
Falling interest rates	Forwards
Stable rates	Roughly equal

Key Takeaways

Futures and forwards differ due to daily settlement
Futures prices are positively correlated with interest rates
Rising rates favor futures because gains are reinvested sooner
Timing of cash flows can cause futures prices ≠ forward prices
At maturity, futures and forwards converge
Clearinghouses reduce counterparty risk in futures markets

Learning Module #7 – Pricing & Valuation of Interest Rate Swaps

What is a Swap?

A swap is a derivative in which two parties agree to exchange a series of cash flows on periodic settlement dates over a specified time period.

Payments are based on:
- A notional principal (never exchanged)
- A fixed rate, floating rate, or other reference

Plain Vanilla Interest Rate Swap (Most Testable)

One party pays fixed
One party pays floating (market reference rate, e.g., LIBOR)
Only the net payment is exchanged at each settlement date

Analogy:
A swap is like two roommates splitting rent where one pays a fixed amount every month and the other pays whatever the variable utilities bill turns out to be — only the difference changes hands.

Key Characteristics of Swaps

No principal exchanged
Net settlement only
No cash exchanged at initiation
Value = 0 at initiation
Exposed to counterparty risk
OTC instruments (not exchange-traded)

Swaps vs Forwards – Similarities

Swaps and forwards share several important features:

Lock in a fixed rate
Net payment at settlement
Symmetric payoff profiles
No upfront payment
Counterparty risk
Zero value at initiatio

A swap is economically equivalent to a bundle of forward contracts.

Swaps as a Series of Forward Rate Agreements (FRAs)

Core Idea

A swap can be decomposed into a series of FRAs, one for each settlement period.

Each FRA:
- Covers a specific future period
- Has its own forward rate
The swap uses one single fixed rate applied across all periods

Analogy:
A swap is like buying a season pass instead of individual tickets — same total exposure, simplified pricing.

Pricing a Swap (At Initiation)

Swap Price = Fixed Swap Rate

At initiation, the swap rate is set so that: $P V (Fixed Leg) = P V (Floating Leg)$

This ensures: ${Swap Value}_{0} = 0$

Two Ways to Price a Swap

Method 1: Using an n-Year Swap Rate

Apply a single fixed rate over the entire swap life
Discount fixed payments using spot rates

Method 2: Using a Series of FRAs

Determine forward rates for each period
Discount each expected cash flow using appropriate spot rates
Sum present values

Valuing a Swap After Initiation

Once market rates change, the swap acquires positive or negative value.

Settlement Value Formula

$Settlement Value = (MRR - Fixed Swap Rate) \times Notional Principal \times Period$

Where:

MRR = Market Reference Rate for the period

Who Pays Whom?

If MRR > fixed rate → fixed-rate receiver gains
If MRR < fixed rate → fixed-rate payer gains

Analogy:
If you locked in a cheap fixed rate and market rates rise, you’re “winning” every period.

Intuition for Swap Value Changes

Fixed-rate side:
- Benefits when market rates move away from fixed rate
Floating-rate side:
- Always resets to market → PV ≈ par at reset dates
Value changes driven primarily by interest rate movements

Summary Tables

Swap Basics

Feature	Description
Instrument Type	OTC derivative
Principal	Not exchanged
Settlement	Net cash flow
Value at Initiation	0
Risk	Counterparty risk

Swaps vs Forwards

Feature	Swaps	Forwards
Structure	Series of payments	Single payment
Rate Locked	Fixed	Fixed
Value at Initiation	0	0
Counterparty Risk	Yes	Yes

Key Takeaways

A swap exchanges streams of cash flows, not principal
Plain vanilla swaps exchange fixed for floating
Swaps have zero value at initiation
Pricing sets PV fixed = PV floating
Swaps can be replicated with a series of FRAs
Swap value changes as market rates change
Only net payments are exchanged

Learning Module #8: Option Pricing & Valuation

Call and Put Options: Core Definitions

Call Option

Gives the holder the right (not obligation) to buy an underlying asset at the strike price (X)

Exercise Rule:

Exercised when: $S > X$

Put Option

Gives the holder the right to sell the underlying asset at the strike price (X)

Exercise Rule:

Exercised when: $S < X$

Moneyness of Options (Highly Testable)

Call Option

Status	Condition
In the Money (ITM)	$S > X$ S>X
At the Money (ATM)	$S = X$ S=X
Out of the Money (OTM)	$S < X$ S<X

Put Option

Status	Condition
In the Money (ITM)	$S < X$ S<X
At the Money (ATM)	$S = X$ S=X
Out of the Money (OTM)	$S > X$ S>X

Analogy:
Think of moneyness like a coupon — if you can buy cheaper or sell higher right now, it’s valuable.

Intrinsic Value (IV)

Definition:
Profit obtained if the option is exercised immediately

Formulas

Call: $I V = \max (0, S - X)$
Put: $I V = \max (0, X - S)$

Key Rule:

IV = 0 when option is ATM or OTM

Time Value & Option Premium

Option Value Decomposition

$Option Premium = Intrinsic Value + Time Value$

Time Value reflects uncertainty before expiration
At expiration: $Time Value = 0$

Analogy:
Time value is like paying extra for flexibility — more time means more chances to win.

Present Value of Strike Price

If exercise occurs at maturity: $P V (X) = \frac{X}{(1 + r)^{T}}$

This is used when calculating lower bounds.

European vs American Options

Feature	American	European
Exercise Timing	Anytime	Only at maturity
Flexibility	Higher	Lower
Value	≥ European	≤ American

Upper and Lower Bounds of Option Prices

Call Option Bounds

Upper Bound: $C \leq S$
Lower Bound: $C \geq \max (0, S - \frac{X}{(1 + r)^{T}})$

Put Option Bounds

Upper Bound: $P \leq X$
Lower Bound: $P \geq \max (0, \frac{X}{(1 + r)^{T}} - S)$

Options can never be worth more than their maximum possible payoff.

Factors Affecting Option Values

Price of Underlying Asset (S)

↑ Stock Price:
- Call → more valuable
- Put → less valuable

Analogy:
Calls love rallies, puts love crashes.

Strike Price (X)

Higher X:
- Call → less valuable
- Put → more valuable

Risk-Free Rate (r)

↑ Interest Rates:
- Call → more valuable
- Put → less valuable

Reason:
Paying later (PV of X falls) benefits calls.

Volatility (σ)

↑ Volatility:
- Call ↑
- Put ↑

Why?
More volatility = higher chance of expiring deep ITM

Stock Benefits and Costs of Carry

Call holders:
- ❌ Do not receive dividends
- ❌ Do not pay storage or financing costs
Put holders:
- Benefit from dividends reducing stock price

Inverse Relationships (Exam Traps)

Call Value Decreases When:

Strike price ↑
Stock benefits ↑

Put Value Decreases When:

Stock price ↑
Risk-free rate ↑
Cost of carry ↑

Summary Tables

Option Payoff Summary

Option	Profits When
Call	( S > X )
Put	( S < X )

Factors Affecting Option Prices

Factor	Call	Put
Stock Price ↑	↑	↓
Strike Price ↑	↓	↑
Volatility ↑	↑	↑
Risk-Free Rate ↑	↑	↓

Key Takeaways

Option value = intrinsic + time
Time value goes to zero at expiration
Calls benefit from higher prices and rates
Puts benefit from lower prices
Volatility increases all option values
Option prices are bounded — arbitrage prevents violations
American options ≥ European options

Learning Module #9: Option Replication Using Put-Call Parity

Put-Call Parity – Core Concepts

Put-Call Parity defines a no-arbitrage relationship between European calls, European puts, the underlying asset, and a risk-free bond.

If parity does not hold → arbitrage opportunity exists

Standard Put-Call Parity Formula

$C + \frac{X}{(1 + r)^{T}} = P + S$

Where:

$C$ = Call price
$P$ = Put price
$S$ = Spot price of underlying
$X$ = Strike price
$r$ = Risk-free rate
$T$ = Time to maturity

Call and put must have the same strike price and maturity.

Intuition Behind Put-Call Parity

Left Side (Fiduciary Call)

$C + \frac{X}{(1 + r)^{T}}$

Buy a call
Invest PV of strike price in a risk-free bond
Guarantees ability to buy the asset at maturity

Right Side (Protective Put)

$S + P$

Buy the stock
Buy a put for downside protection
Guarantees a minimum payoff equal to the strike price

Key Insight

Both portfolios produce identical payoffs at maturity, so they must cost the same today.

Analogy:
Two different roads leading to the same destination must cost the same taxi fare — otherwise arbitrageurs step in.

Protective Put

Definition

$Protective Put = S + P$

Long stock
Long put

Payoff Behavior

Upside from stock appreciation
Downside limited to strike price

Analogy:
Owning a house with insurance — upside if prices rise, floor if disaster strikes.

Fiduciary Call

Definition

$Fiduciary Call = C + \frac{X}{(1 + r)^{T}}$

Long call
Risk-free bond funding the strike price

Payoff Behavior

Same payoff as protective put
Less capital tied up initially

Fiduciary call and protective put are economically equivalent.

Synthetic Positions

Put-call parity allows replication of positions using other instruments.

Synthetic Call

Rearrange parity: $C = S + P - \frac{X}{(1 + r)^{T}}$

Interpretation:

Long stock
Long put
Short risk-free bond

Synthetic Put

$P = C + \frac{X}{(1 + r)^{T}} - S$

Synthetic Stock

$S = C + \frac{X}{(1 + r)^{T}} - P$

Synthetic Risk-Free Bond

$\frac{X}{(1 + r)^{T}} = S + P - C$

Negative sign = short position

Forward Put-Call Parity

Put-call parity can also be expressed using forwards: $C - P = \frac{F_{0}}{(1 + r)^{T}}$

Where:

$F_{0}$ = Forward price of the underlying

Meaning:
The difference between call and put prices reflects the present value of the forward contract.

Firm Value Using Parity

Parity concepts extend beyond options:

Equity = Call option on firm assets
Debt = Risk-free bond − Put option

This framework underlies structural credit risk models

Common CFA Exam Traps

Using parity for American options ❌ (parity strictly applies to European options)
Mismatched strikes or maturities ❌
Forgetting to discount the strike price ❌
Misinterpreting negative signs (short positions) ❌

Summary Tables

Put-Call Parity Components

Portfolio	Composition
Protective Put	( S + P )
Fiduciary Call	( C + PV(X) )
Synthetic Call	( S + P – PV(X) )

Synthetic Position Reference

Want Exposure To	Use
Call	Stock + Put − Bond
Put	Call + Bond − Stock
Stock	Call + Bond − Put
Bond	Stock + Put − Call

Key Takeaways

Put-call parity enforces no-arbitrage pricing
Protective put = fiduciary call
Synthetic positions replicate payoffs exactly
Strike prices and maturities must match
Negative signs indicate short positions
Parity works strictly for European options
Violations imply arbitrage opportunities

Learning Module #10: One-Period Binomial Model

What is the One-Period Binomial Model?

The one-period binomial model values a derivative by assuming the underlying asset price can move to one of two possible values at expiration:

Up state
Down state

This framework enforces no-arbitrage pricing and introduces risk-neutral valuation, which is foundational for later option-pricing models.

Analogy:
Think of tomorrow’s weather forecast: either it rains or it doesn’t. The model prices today based on both outcomes.

Stock Price Tree

At time 0: $S_{0}$

At time 1: $S_{u} = S_{0} \times u (up move)$ $S_{d} = S_{0} \times d (down move)$

Where:

$u$ u = up-factor
$d$ d = down-factor

Step-by-Step Valuation

Step 1: Value the Option at Expiration

For a call option: $C_{u} = \max (0, S_{u} - X)$ $C_{d} = \max (0, S_{d} - X)$

This gives the option’s payoff in each state.

Step 2: Compute the Hedge Ratio (Δ)

$Hedge Ratio (HR) = \frac{C_{u} - C_{d}}{S_{u} - S_{d}}$

Interpretation:

Number of shares needed per option to eliminate risk
Also known as delta (Δ)

Analogy:
It’s the amount of stock needed to “balance” the option so gains in one cancel losses in the other.

Step 3: Construct the Risk-Free Portfolio

Long HR shares of stock
Short 1 call option

Portfolio value today: $V_{0} = H R \cdot S_{0} - C_{0}$

Portfolio value tomorrow (both states): $V_{u} = H R \cdot S_{u} - C_{u}$ $V_{d} = H R \cdot S_{d} - C_{d}$

Because risk is eliminated: $V_{u} = V_{d}$

Step 4: Discount at the Risk-Free Rate

Since the portfolio is risk-free, it must earn the risk-free rate: $V_{0} = \frac{V_{1}}{1 + R_{f}}$

Solve for the option price $C_{0}$ .

Step 5: No-Arbitrage Condition

The discounted future value must equal today’s value

If this condition fails → arbitrage opportunity exists

Risk-Neutral Probabilities

If probabilities of up and down moves are not given, use risk-neutral probabilities.

Risk-Neutral Probability of Up Move

$q = \frac{(1 + R_{f}) - d}{u - d}$

Down Move Probability

$1 - q$

Risk-Neutral Pricing Formula

$C_{0} = \frac{q C_{u} + (1 - q) C_{d}}{1 + R_{f}}$

These are not real probabilities — they are mathematical tools to enforce no-arbitrage.

Analogy:
Risk-neutral probabilities are like adjusting the odds so the “casino” (market) makes no free money.

Key Intuitions and Exam Traps

Key Intuition

Investors are assumed to be risk-neutral
Expected returns = risk-free rate
Risk preferences are absorbed into prices, not probabilities
This logic scales to multi-period trees and Black-Scholes

Common CFA Exam Traps

Forgetting to compute payoffs at expiration first
Mixing real probabilities with risk-neutral probabilities
Not discounting at the risk-free rate
Misinterpreting hedge ratio sign
Forgetting that arbitrage-free portfolios must earn $R_{f}$ Rf

Summary Tables

Binomial Valuation Steps

Step	Action
1	Compute option payoffs
2	Calculate hedge ratio
3	Build risk-free portfolio
4	Discount at ( R_f )
5	Enforce no-arbitrage

Key Variables

Symbol	Meaning
( u )	Up-factor
( d )	Down-factor
( q )	Risk-neutral probability
( HR )	Hedge ratio (delta)
( R_f)	Risk-free rate

Key Takeaways

Binomial models assume two future price states
Option value comes from replication and no-arbitrage
Hedge ratio eliminates risk
Risk-free portfolios earn the risk-free rate
Risk-neutral probabilities simplify valuation
This is the foundation for all modern option pricing