Post on 26-Mar-2015
Chapter 7 1
CHAPTER 7INTEREST RATE FUTURES
In this chapter, we explore one of the most successful innovations in the history of futures markets; that is, interest rate futures contracts. This chapter is organized into the following sections:
1. Interest Rate Futures Contracts
2. Pricing Interest Rate Futures Contracts
3. Speculating With Interest Rate Futures Contracts
4. Hedging With Interest Rate Futures Contracts
Chapter 7 2
Interest Rate Futures Introduction
Interest rate futures contracts are one of the most successful innovations in futures trading.
Pioneered in the United States, they have expanded internationally with strong presence in Great Britain and Singapore.
The CBOT specializes in contracts with long-term maturity (e.g., 2-year, 5-year and 10-year T-notes, and 5-year LIBOR-based swaps).
The CME International Monetary Market (IMM) specializes in contracts with short-term maturity (e.g., 1-month, and 3-month Eurodollar deposits).
Chapter 7 3
Short-Term Interest Rates Contracts
In this section, four short-term interest rate futures contracts will be examined:
1. Eurodollar Futures
2. Euribor Futures
3. TIEE 28 Futures
4. Treasury Bill Futures
Chapter 7 4
Eurodollar Futures Product Profile
Product Profile: The CME=s Eurodollar Futures Contract Size: Eurodollar Time Deposit having a principal value of $1,000,000 with a three-month maturity. Deliverable Grades: Cash Settled to 3-month Dollar LIBOR Tick Size: 0.01=$25.00 Months 11 thru 40; 0.005=$12.50 Months 2 thru 10; 0.0025=$6.25 for nearest expiring month. Price Quote: Price is quoted in terms of the IMM 3-month Eurodollar index, 100 minus the yield on an annual basis for a 360-day year with each basis point worth $25. Contract Months: March, June, September, and December cycle for 10 years Expiration and final Settlement: Eurodollar futures cease trading at 5:00 a.m. Chicago Time (11:00 a.m. London Time) on the second London bank business day immediately preceding the third Wednesday of the contract month; final settlement price is based on the British Bankers= Association Interest Settlement Rate. Trading Hours: Floor: 7:20 a.m.-2:00 p.m; Globex: Mon/Thurs 5:00 p.m.-4:00 p.m.; Shutdown period from 4:00 p.m. to 5:00 p.m. nightly; Sunday & holidays 5:30 p.m.-4:00 p.m. Daily Price Limit: None
Chapter 7 5
Eurodollar Futures
1. Eurodollar futures currently dominate the U.S. market for short-term futures contracts.
2. Rates on Eurodollar deposits are usually based on LIBOR (London Interbank Offer Rate).
– LIBOR is the rate at which banks are willing to lend funds to other banks in the interbank market.
3. Eurodollars are U.S. dollar denominated deposits held in a commercial bank outside the U.S.
4. The Eurodollar contracts is for $1,000,000.
5. A Eurodollar futures contract is based on a time deposit held in a commercial bank (e.g., 3-month Eurodollar)
6. Eurodollar contracts are non-transferable.
Chapter 7 6
Eurodollar Futures
7. Eurodollar futures were the first contract to use cash settlement rather than delivery of an actual good for contract fulfillment.
8. To establish the settlement rate at the close of trading, the IMM determines the three-month LIBOR rate.
9. This settlement rate is then used to compute the amount of the cash payment that must be made.
10.The yield on the Eurodollar contract is quoted on an add-on basis as follows:
Chapter 7 7
Eurodollar Add-on Yield
In order to calculate the add-on yield, the price and discount must be computed as follows:
))(( 360$
DTMPrice
Discount Yield onAdd
DiscountValue FacePrice $
360
))(($
DTMValue FaceDYDiscount
360
))(( DTMValue FaceDYValue FacePrice
Or equivalently
Chapter 7 8
Eurodollar Add-on Yield
Suppose you have a 90-day Eurodollar deposit with a discount yield of 8.32%.
Step 1: Compute the discount and the price.
800,20$$Discount
800,20000,000,1 Price
200,979$Price
360
))(( DTMValue FaceDYValue FacePrice
360
)90)((0832.0 1,000,0001,000,000Price
Chapter 7 9
Eurodollar Add-on Yield
))(( 360$
DTMPrice
Discount Yield onAdd
))((90
360
200,979
800,20$ Yield onAdd
25$360900001.000,000,1$
Step 2: Compute the add-on yield using:
A one basis point change in the Add-on Yield, on a 3-month Eurodollar contract implies a $25 change in price. This amount can be compute using:
360 DTMYield onAddValue Face
Eurodollar futures contract prices are quoted using the IMM Index which is a function of the 3-month LIBOR rate:
IMM Index = 100.00 - 3-Month LIBOR
0.085 Yield onAdd
Chapter 7 10
Euribor Futures
Euribors are Eurodollar time deposits.
Swaps dealers use Euribor futures to hedge the risk resulting from their activities.
Euribor futures are traded at:
Euronex.liffe
– Contracts are based on a 3-month time deposit with a €1,000,000 notional value.
– Contracts are cash settled at expiration .
Eurex
– Contracts are based on a 3-month time deposit with a €3,000,000 notional value.
– Contracts are cash-settled at expiration.
Chapter 7 11
Euribor Futures Product Profile
Product Profile: Euronext-Liffe Euribor Futures Contract Size: 1,000,000 with a three-month maturity. Deliverable Grades: Cash Settled to Euopean Bankers Federation=s Euribor Offered Rate (EBF Euribor) for three-month euro time deposits. Tick Size: .005 percent representing 12.5. Price Quote: 100 minus the Euribor rate of interest carried out to three decimal places. Contract Months: March, June, September, and December and four serial months so that 24 delivery months are available for trading, with the nearest six expirations being consecutive calendar months. Expiration and final Settlement: The last trading day is two business days prior to the third Wednesday of the contract month. Final settlement is based on Euopean Bankers Federation=s Euribor Offered Rate (EBF Euribor) for three-month euro time deposits at 10:00 a.m. London time on the last trading day. Trading Hours: 7:00 a.m. to 6:00 p.m. Daily Price Limit:
Chapter 7 12
TIEE 28 Futures
The TIEE 28 futures contract is based on the short-term (28-day) Mexican interest rate.
The contract is traded on the Mexican Derivatives Exchange (Mercado Mexicano de Derivados, or MexDer)
A 28-day TIIE futures contract has a face value of 100,000 Mexican pesos.
The contract is cash settled based on the 28-day Interbank Equilibrium Interest Rate (TIIE), calculated by Banco de México.
Chapter 7 13
TIEE 28 Futures TIEE 28 Futures
Product Profile: The MexDer=s TIEE Futures Contract Size: Each 28-Day TIIE Futures Contract covers a face value of One Hundred Thousand Mexican Pesos. Deliverable Grade Cash settled based of the 28-Day Interbank Equilibrium Interest Rate (TIIE), calculated by Banco de México based on quotations submitted by full-service banks using a mechanism designed to reflect conditions in the Mexican Peso Money Market. Tick Size: One basis point of the annualized percentile rate of yield Price Quote: Trading of 28-Day TIIE futures contracts use the annualized percentile rate of yield expressed in percentile terms, with two decimal places. Contract Months: MexDer lists different Series of the 28-Day TIIE Futures Contracts on a monthly basis for up to sixty months (five years). Expiration and final Settlement: The last trading day is the bank business day after Banco de México holds the primary auction of government securities in the week corresponding to the third Wednesday of the Maturity Month. Trading Hours: Bank businessdays from 7:30 a.m. to 3:00 p.m., Mexico City time. Daily Price Limit: None
Chapter 7 14
Treasury Bill Futures
1. A T-bill is the U.S. government borrowing money for a short period of time.
– Treasury bills have original maturities of 13 weeks and 26 weeks.
2. The Treasury bill futures contract calls for the delivery of T-bills having a face value of $1,000,000 and a time to maturity of 90 days at the expiration of the futures contract.
– 91-day and 92 day T-bills may also be delivered with a price adjustment.
– The contracts have delivery dates in March, June, September, and December.
– The delivery dates are chosen to make newly issued 13 week T-bills immediately deliverable against the futures contract.
Chapter 7 15
Treasury Bill Futures
Price quotations for T-bill futures use the International Monetary Market Index (IMM).
IMM Index = 100 - DY
Where:
DY = Discount Yield
Example
A discount Yield of 7.1% implies an IMM Index of:
IMM Index = 100 - 7.1
IMM Index = 92.9
Chapter 7 16
Treasury Bill Futures
Recall that a bill with 90 days to maturity and a 8.32% discount yield, has a price of $979,200 and a $discount of $20,800. For a futures contract with a discount yield of 8.32%, the price to be paid for the T-bill at delivery would be $979,200.
A one basis point shift implies a $25 change on a $1,000,000, 3-month futures contract.
If the futures yield rose to 8.35%, the delivery price would be $979,125.
Chapter 7 17
Other Short-Term Interest Rate Futures
Insert Figure 7.1 here
Chapter 7 18
Longer-Maturity Interest Rate Futures
Longer-maturity interest rate futures are based on coupon-bearing debt instruments as the underlying good.
These instruments require the delivery of an actual bond.
In this section, long-term interest rate futures contracts will be examined, including:
1. Treasury Bond Futures
2. Treasury Note Futures
3. Non-US Longer Maturity Interest Rate Futures
Chapter 7 19
Treasury Bond Futures
Traded at the CBOT, the Treasury bond futures contract is one of the most successful futures contracts.
Requires the delivery of T-bonds with a $100,000 face value and with at least 15 years remaining until maturity or until their first permissible call date.
T-bond contracts trade for delivery in March, June, September, and December.
Delivery against the T-bond contract is a several day process that the short trader can trigger to cause delivery on any business day of the delivery month.
– First Position Day
First permissible day for the short to declare his/her intentions to make delivery, with delivery taking place 2 business days later.
– Position Day
Short declares his/her intentions to make delivery. This may occur on the first position day or some other later day.
Delivery Day
Clearinghouse matches the short and long traders and requires them to fulfill their responsibilities.
Chapter 7 20
Treasury Bond FuturesPrice Quotation for Major Interest Rate Futures
Contracts
Insert Figure 7.1 Here
Chapter 7 21
Treasury Bond Futures Delivery Process
Insert Figure 7.2 here
Chapter 7 22
Treasury Bond Futures Product Profile
Product Profile: The CBOT=s 30 Year Treasury Bond Futures Contract Size: One U.S. Treasury bond with face value at maturity of $100,000 Deliverable Grades: U.S. Treasury bonds that, if callable, are not callable for at least 15 years from the first day of the delivery month or, if not callable, have a maturity of at least 15 years from the first day of the delivery month. The invoice price equals the futures settlement price times a conversion factor plus accrued interest. The conversion factor is the price of the delivered note ($1 par value) to yield 6 percent. Tick Size: 1/32 of a point ($31.25/contract); par is on the basis of 100 points. Price Quote: Points ($1,000) and thirty seconds a point; i.e., 84-16 equals 84 16/32. Contract Months: March, June, September, and December Expiration and final Settlement: The last trading day is the seventh business day preceding the last business day of the delivery month. The contract is settled with physical delivery. The last delivery day is the last business day of the delivery month. Trading Hours: Open Auction: 7:20 am - 2:00 pm, Central Time, Monday - FridayElectronic: 7:00 pm - 4:00 pm, Central Time, Sunday - FridayTrading in expiring contracts closes at noon, Chicago time, on the last trading day. Daily Price Limit: None.
Chapter 7 23
Treasury Bond Futures Conversion Factor
The T-bond contract does not specify exactly which bond must be delivered to fulfill the futures contract. Rather, a number of different bonds can be delivered to fulfill the futures contract.
Because the short trader chooses whether to make delivery, and which bond to deliver, the short trader will want to deliver the bond that is least expensive for him/her to obtain. This bond is called the cheapest-to-deliver bond.
To address this issue, a conversion factor is computed to equate the bonds.
Chapter 7 24
Treasury Bond Futures Conversion Factor
Where:
DSP = Decimal Settlement Price
(The decimal equivalent of the quoted price)
CF = Conversion Factor
(the conversion factor as provided by the CBOT)
AI = Accrued Interest
(Interest that has accrued since the last coupon payment onthe bond)
This system is effective as long as the term structure of interest rates is flat and the bond yield is 6%. However, if the term structure of interest rates is not flat, or if bond yields are not 6%, some bonds will still be less expensive to deliver against the futures contract than others.
AICFDSP ))(000,100($Amount Invoice
Chapter 7 25
T-Bond and T-Notes Delivery Sequence
Table 7.1 shows key dates in the delivery process for T-bond and T-note futures contracts in 1997.
Table 7.1 The Delivery Sequence for T-Bond & T-Note Futures Expiring in 1997
Contract Expiration
First Position
First Notice
First Delivery
Last Trading
Last Delivery
MAR 97 FEB 27 FEB 28 MAR 3 MAR 21 MAR 31 JUN MAY 29 MAY 30 JUN 2 JUN 20 JUN 30 SEPT AUG 28 AUG 29 SEPT 2 SEP 19 SEP 30 DEC NOV 26 NOV 28 DEC 1 DEC 19 DEC 31
Chapter 7 26
Treasury Bond Futures Conversion Factor
Table 7.1
Conversion Factors for Treasury-Bond Futures for September and December 2004
Coupon
Maturity Date
Sep-04
Dec-04
5 1/4
11/15/28
0.9052
0.9056
5 1/4 02/15/29 0.9047 0.9052 5 1/2 08/15/28 0.9370 0.9374 6 02/15/26 0.9999 1.0000 6 1/8 11/15/27 1.0155 1.0153 6 1/8 08/15/29 1.0159 1.0159 6 1/4 08/15/23 1.0278 1.0277 6 1/4 05/15/30 1.0324 1.0322 6 3/8 08/15/27 1.0461 1.0460 6 1/2 11/15/26 1.0606 1.0602 6 5/8 02/15/27 1.0761 1.0758 6 3/4 08/15/26 1.0903 1.0899 6 7/8 08/15/25 1.1029 1.1024 7 1/8 02/15/23 1.1236 1.1228 7 1/4 08/15/22 1.1352 1.1343 7 1/2 11/15/24 1.1734 1.1721 7 5/8 11/15/22 1.1774 1.1759 7 5/8 02/15/25 1.1889 1.1878 7 7/8 02/15/21 1.1928 1.1911 8 11/15/21 1.2113 1.2094 8 1/8 05/15/21 1.2206 1.2185 8 1/8 08/15/21 1.2224 1.2206 8 1/2 02/15/20 1.2474 1.2450 8 3/4 05/15/20 1.2750 1.2721 8 3/4 08/15/20 1.2775 1.2750
Source: Chicago Board of Trade web site: www.cbot.com.
Chapter 7 27
Treasury Note Futures
Treasury note futures are a shorter maturity version of a Treasury bond.
• T-note Futures are very similar to Treasury bond futures.
• T-note futures contracts are available for 2-year, 5-year, and 10-year maturities.
Contract Size
2-year contract $200,000
5-year & 10 year contract $100,000
Deliverable Maturities
2-year contract 21 -24 month
5-year contract 4 yrs 3 mos. to 5 yrs 3 mos.
10-year contract 6 yrs 6 mos. to 10 years
Chapter 7 28
CBOT’s 10-Year Treasury Note FuturesProduct Profile
Product Profile: The CBOT=s 10 Year Treasury Note Futures
Contract Size: One U.S. Treasury Note with face value at maturity of $100,000 Deliverable Grades: U.S. Treasury notes maturing at least 6.5 years, but not more than 10 years, from the first day of the delivery month. The invoice price equals the futures settlement price times a conversion factor plus accrued interest. The conversion factor is the price of the delivered note ($1 par value) to yield 6 percent. Tick Size: One half of 1/32 of a point ($15.625/contract) rounded up to the nearest cent; par is on the basis of 100 points. Price Quote: Points ($1,000) and one half of 1/32 of a point; i.e., 84-16 equals 84 16/32, 84-165 equals 84 16.5/32 Contract Months: March, June, September, and December Expiration and final Settlement: The last trading day is the seventh business day preceding the last business day of the delivery month. The contract is settled with physical delivery. The last delivery day is the last business day of the delivery month. Trading Hours: Open Auction: 7:20 am - 2:00 pm, Central Time, Monday - FridayElectronic: 7:00 pm - 4:00 pm, Central Time, Sunday - FridayTrading in expiring contracts closes at noon, Chicago time, on the last trading day. Daily Price Limit: None.
Chapter 7 29
Non-US Long Maturity Interest Rate Futures
Product Profile: Eurex=s Euro Bund Futures
Contract Size: One German bund with a par value of 100,000 euros. Deliverable Grades: A long-term debt instrument issued by the German Federal Government with a term of 82 to 102 years and an interest rate of 6 percent. The invoice price equals the futures settlement price times a conversion factor plus accrued interest. Tick Size: 0.01 percent, representing 10 euros. Price Quote: In a percentage of par value, carried out two decimal places. . Contract Months: The three successive months within the March, June, September, and December delivery cycle. Expiration and final Settlement: The last trading day is two trading days prior to the delivery day of the contract month. The delivery day is the 10th calendar day of the contract month, if this day is an exchange trading day; otherwise, the immediately following exchange trading day. Trading Hours: Eurex operates in three trading phases. In the pre-trading period users may make inquiries or enter, change or delete orders and quotes in preparation for trading. This period is between 7:30 and 8:00 a.m. The main trading period is between 8:00 a.m. and 7:00 p.m. Trading ends with the post-trading period between 7:00 p.m. and 8:00 p.m. Daily Price Limit: None
Chapter 7 30
Pricing Interest Rate Futures Contracts
Because, interest rate futures trade in a full carry market, the foundation for pricing interest rate futures is the Cost-of-Carry-Model that we discussed in Chapter 3.
This section introduces a review of the Cost-of-Carry Model as discussed in Chapter 3, including:
1. Cost-of-Carry Rule 3
2. Cost-of-Carry Rule 6
3. Features that Promote Full Carry
4. Repo Rates
5. Cost-of-Carry Model in Perfect Market
6. Cash-and-Carry Arbitrage for Interest Rate Futures
Chapter 7 31
Cost-of-Carry Rule 3
Recall: the cost-of-carry rule #3 says:
Where:
S0 = The current spot price
F0,t = The current futures price for delivery of the product at time t
C0,t= The percentage cost required to store (or carry) the commodity from today until time t
)1( ,00,0 tt CSF
Chapter 7 32
Cost-of-Carry Rule 6
Recall: the cost-of-carry rule #6 says:
F0,d = the futures price at t=0 for the the distant delivery contract maturing at t=d
Fo,n= the futures price at t=0 for the nearby delivery contract maturing at t=n
Cn,d= the percentage cost of carrying the good from t=nto t=d
)1( ,,0,0 dnnd CFF
Chapter 7 33
Full Carry Features
Recall from Chapter 3 that there are five features that promote full carry:
1. Ease of Short Selling
2. Large Supply
3. Non-Seasonal Production
4. Non-Seasonal Consumption
5. High Storability
Interest rates futures have each of these features and thus conform well to the Cost-of-Carry Model.
Chapter 7 34
Repo Rate
Recall from Chapter 3 that if we assume that the only carrying cost is the financing cost, we can compute the implied repo rate as:
tt
CS
F,0
0
,01
tt
CS
F,0
0
,01
or
Interest rate futures conform almost perfectly to the Cost-of-Carry Model. However, we must take into account some of the peculiar aspects of debt instruments.
Chapter 7 35
Cost-of-Carry Model in Perfect Market
Assumptions
1. Markets are perfect.
2. The financing cost is the only cost of carrying charge.
3. Ignore the options that the seller may possess such as the option to deliver differing securities.
4. Ignore the differences between forward and futures prices.
Chapter 7 36
Cash-and-Carry Arbitrage for Interest Rate Futures
Recall from Chapter 3 that in order to earn an arbitrage profit, a trader might want to try a cash-and-carry arbitrage.
Recall further that a cash-and-carry arbitrage involves selling a futures contract, buying the commodity and storing it until the futures delivery date. Then you would deliver the commodity against the futures contract.
Applying the cash-and-carry arbitrage to interest rate futures requires careful selection of the commodity’s interest rate (T-bill, T-bond etc) that will be purchased.
Each of the interest rate futures contracts specifies the maturity of the interest rate instrument to be delivered. The interest rate instrument must have this maturity on the delivery date.
Chapter 7 37
Cash-and-Carry Arbitrage for Interest Rate Futures
Example, a T-bill futures contract requires the delivery of a T-bill with 90 days to maturity on the delivery date.
So, if you sell a T-bill futures contract that calls for delivery in 77 days, we must purchase a T-bill that will have 90 days to maturity, 77 days from today, in order to meet your obligations. That is, you must purchase a T-bill that has 167 days to maturity today.
0 77
1. Sell futures Contract.2. Buy T-bill Futures contract w/ 167 days to maturity.
4. T-bill matures
167
3. Deliver T-bill (that has now 90 days to maturity) against futures contract.
Table 7.2 and 7.3 further develop this example.
Chapter 7 38
Cash-and-Carry Arbitrage for Interest Rate Futures
Table 7.2
Interest Rate Futures and Arbitrage
Today's Date: January 5
Futures
Discount Yield
Price ($1,000,000 Face Value)
MAR Contract (Matures in 77 days on March 22)
12.50%
$968,750
Cash Bills: 167Bday TBbill (Deliverable on MAR fu-tures)
10.00
953,611
77Bday TBbill
6.00
987,167
Assume that markets are perfect including the assumption of borrowing and lending at a risk-less rate represented by the T-bill yields. Suppose that you have gathered the information in Table 7.2 and wish to determine if an arbitrage opportunity is present.
How was the bill price of $987,167 from Table 7.2 calculated?
Chapter 7 39
Cash-and-Carry Arbitrage for Interest Rate Futures
The bill prices were calculated as follows:
360
))((Price Bill
DTMValue FaceDYValue Face
For the March Futures Contract
360
)90)(000,000,1(125.0000,000,1Price Bill
750,968Price Bill
For the March 167-day T-bill
360
)167)(000,000,1(10.0000,000,1Price Bill
611,953Price Bill
For the 77-day T-bill with $1,000,000 face value
360
)77)(000,000,1(06.0000,000,1Price Bill
166,987Price Bill
Chapter 7 40
Cash-and-Carry Arbitrage for Interest Rate Futures
The transactions necessary to earn an arbitrage profit are given in Table 7.3.
Table 7.3
CashBandBCarry Arbitrage Transactions
January 5 Borrow $953,611 for 77 days by issuing a 77Bday TBbill at 6%. Buy 167Bday TBbill yielding 10% for $953,611. Sell MAR TBbill futures contract with a yield of 12.50% for $968,750.
March 22 Deliver the originally purchased TBbill against the MAR futures contract and collect $968,750. Repay debt on 77Bday TBbill that matures today for $966,008.
Profit: $968,750 B 966,008 $ 2,742
How was the $966,008 from Table 7.3 calculated?
Chapter 7 41
Cash-and-Carry Arbitrage for Interest Rate Futures
The $966,008 is the face value of a 77-day T-bill with a current price of $953,611. To calculate this value, rearrange the bill price formula:
)(360 DTMDY
Price Bill 360Value Face
)77(06.0360
)611,953($360
Value Face
38.355
960,299,343Value Face
10.008,966Value Face
Rearranging the equation results:
360
))((Price Bill
DTMValue FaceDYValue Face
Chapter 7 42
Cash-and-Carry Arbitrage to Interest Rate Futures
When delivery is due on the futures contract on March 22, you deliver the T-bill (which now has 90 days to maturity) against the futures contract.
0
1. Borrow money2. Buy 167-day T-bill3. Sell a futures contract
4. Deliver the T-bill against the futures contract5. Pay off the loan
1
Combined, these transactions appear as follows on a timeline:
Time Transaction Cash Flow Mar 22 Deliver 167-day T-bill
(that now has 90 days to maturity) against the futures contract
$968,750
Mar 22 Repay debt on 77-day T-Bill that matures today
$966,008
Profit/contract $2,742
Chapter 7 43
Reverse Cash-and-Carry Arbitrage to Interest Rate Futures
Using the same values as shown in Table 7.2, now assume that the rate on the 77-day T-bill is 8%.
Given this new information and Table 7.2 prices, a reverse cash-and-carry arbitrage opportunity is present. Table 7.4 shows the result.
To calculate the values in Table 7.4 follow the steps shown for the previous cash-and-carry example.
Table 7.4
Reverse CashBandBCarry Arbitrage Transactions
January 5 Borrow $952,174 by issuing a 167Bday TBbill at 10%. Buy a 77Bday TBbill yielding 8% for $952,174 that will pay $968,750 on March 22. Buy one MAR futures contract with a yield of 12.50% for $968,750.
March 22 Collect $968,750 from the maturing 77Bday TBbill. Pay $968,750 and take delivery of a 90Bday TBbill from the MAR futures contract.
June Collect $1,000,000 from the maturing 90Bday TBbill that was delivered on the futures contract. Pay $998,493 debt on the maturing 167Bday TBbill.
Profit: $1,000,000 B 998,493 $ 1,507
Chapter 7 44
Reverse Cash-and-Carry Arbitrage to Interest Rate Futures
Combined, these transactions appear as follows on a timeline:
Jan 5 Mar 22
1. Borrow money2. Buy 77-day T-bill3. Buy a futures contract
6. Collect 1 M from mature
T-bill7. Pay off loan
Jun 20
4. Collect from maturing T-bill5. Accept delivery on 90-day contract
Chapter 7 45
Interest Rate Futures Rate Relationships
Rate relationship that must exist between interest rates to avoid arbitrage:
Consider two methods of holding a T-bill for 167 days.
Method 1:
Buy a 167 day T-bill
Method 2:
Buy a 77 day T-bill.
Buy a futures contract for delivery of a 90 day T-bill in 77 days.
Use the futures contract to buy a 90-day T-bill.
These investment appear as follows on a timeline.
Chapter 7 46
Interest Rate Futures Rate Relationships
Method 2
Jan 5 Mar 22
1. Buy 77-day T-bill2. Buy a future contract for 90-day T-bill w/ 77 days to maturity
5. Collect from maturing T-bill
Jun 20
3. Collect from maturing T-bill4. Buy a 90-day T-bill using the futures contract
Either of these two methods of investing in T-bills has exactly the same investment and exactly the same risk.
Since both investment have exactly the same risk and exactly the same investment, they must have exactly the same yield to avoid arbitrage.
Jan 5 Mar 22
1. Buy 167-day T-bill
2. Collect from maturing T-bill
Jun 20
Method 1
Chapter 7 47
Financing Cost and Implied Repo Rate
Calculate the rate that must exist on the 77-day T-bill to avoid the arbitrage as follows:
Event Discount Yield Price MAR Contract (Matures on March 22 or 77 days)
12.5% $968,750
Cash T-bill 167-day T-bill (deliverable on MAR futures)
10% $953,611
77-Day T-bill ??% $???
Use the no arbitrage equation to determine the appropriate yield on the 77-day T-bill by, using the following equation:
360XContract Futures of Price
Price BillT Term LongContract Futures of PriceYieldNA
DTMFC
Where:NA Yield = the no arbitrage YieldDTMFC = days to maturity of the futures contract
Chapter 7 48
Financing Cost and Implied Repo Rate
36077
750,968$
611,953750,968$
XYield NA
86.204,207$
139,15$Yield NA
07306.0Yield NA
So in order for there to be no arbitrage opportunities available, the yield on the 77 day T-bill must be 7.3063%.
If the yield on the 77 day T-bill is greater than 7.3063%, then engage in a reverse cash-and-carry arbitrage. If the yield on the 77 day T-bill is less than 7.3063%, engage in a cash-and-carry arbitrage.
Chapter 7 49
Financing Cost and Implied Repo Rate
We can also calculate the implied repo rate as follows:
tt
CS
F,0
0
,01
In our case the spot price is the price of the 167-day to maturity T-bill, so:
tC ,01611,953$
750,968$
015875.11 ,0 tC
The implied repo rate is the cost of holding the commodity for 77 days, between today and the time that the futures contract matures, assuming this is the only financing cost, it is also the cost of carry.
The implied repo rate (C) is 1.5875%
Chapter 7 50
Financing Cost and Implied Repo Rate
1. If the implied repo rate exceeds the financing cost, then exploit a cash-and-carry arbitrage opportunity
2. If the implied repo rate is less than the financing cost, then exploit a reverse cash-and-carry arbitrage.
Borrow funds Buy cash bond Sell futures
Hold bondDeliver against futures
Realize profit
Buy futures Sell bond short Invest proceeds until futures exp.
Take deliveryRepay short sale obligation
Realize profit
Chapter 7 51
Cost-of-Carry Model for T-Bond Futures
The cost of carry concepts for T-bill futures that we have just examined also apply to T-bond futures. However, the computation must be adjusted to reflect the coupon payment and accrued interests.
Chapter 7 52
Cost-of-Carry Model in Imperfect Markets
In this section, the borrowing and lending assumptions are relaxed, and the Cost-of-Carry Model is explored under the following assumption:
1. The borrowing rate exceeds the lending rate.
2. The financing cost is the only carrying charge.
3. Ignore the options that the seller may possess.
4. Ignore the differences between forward and futures prices.
Recall that allowing the borrowing and lending rates to differ leads to an arbitrage band around the futures price. Now assume that the borrowing rate is 25 basis points, or one-fourth of a percentage point, higher than the lending rate. Continuing to use our T-bill example.
Chapter 7 53
Cash-and-Carry Strategy
Instrument
Lending Rate
Borrowing Rate
77-day bill
7.3063
7.5563 167-day bill
10.0000
10.2500
Table 7.6 CashBandBCarry Transactions
with Unequal Borrowing and Lending Rates January 5 Borrow $953,611 for 77 days at the 77Bday borrowing rate of 7.5563. Buy 167Bday TBbill yielding 10% for $953,611. Sell one TBbill futures contract with a yield of 12.29% for $969,275. March 22 Deliver the originally purchased TBbill against the MAR futures contract and collect $969,275. Repay debt on 77Bday TBbill that matures today for $969,277. Profit: -$2 0
Notice that the entire arbitrage profit disappears when these differential borrowing and lending rates are considered.
Chapter 7 54
Reserve Cash-and-Carry Transaction
Table 7.7
Reverse CashBandBCarry Transactions with Unequal Borrowing and Lending Rates
January 5 Borrow $952,454 at the 167-day borrowing rate of 10.25%. Buy a 77-day T-bill yielding 7.3063% for $952,454. Buy 1 MAR futures contract with a futures yield of 12.97% for $967,575. March 22 Collect $967,575 from the maturing 77-day T-bill. Pay $967,575 and take delivery of a 90-day T-bill on the futures contract. June 20 Collect $1,000,000 from the maturing 90-day T-bill that was delivered on the futures contract. Pay $1,000,003 debt on the maturing 167-day T-bill. Profit: -$3 0
Again notice that the entire arbitrage profit disappears when these different borrowing and lending rates are considered.
Chapter 7 55
A Practical Survey of Interest Rate Futures Pricing
Recall from Chapter 3 that transaction costs lead to a no-arbitrage band of possible futures prices. In essence, transaction costs increase the no-arbitrage band just as unequal borrowing and lending rates do.
Impediments to short selling as a market imperfection would frustrate the reverse cash-and-carry arbitrage strategy.
From a practical perspective, restrictions on short selling are unimportant in interest rate futures pricing because:
– Supplies of deliverable Treasury securities are plentiful and government securities have little (or zero) convenience yield.
– Treasury securities are so widely held, many traders can simulate short selling by selling T-bills, T-notes, or T-bonds from inventory. Therefore, restrictions on short selling are unlikely to have any pricing effect.
Chapter 7 56
Speculating with Interest Rate Futures
There are several ways that you can speculate with interest rate futures:
1. Outright Position.
2. Intra-Commodity T-Bill Spread
3. A T-bill/Eurodollar (TED) Spread
4. Notes over Bonds (NOB)
Chapter 7 57
Speculating with Outright Position
Two ways to speculate with outright positions are:
1. Purchase an interest rate futures contract: a bet that interest rates will go down.
2. Sell an interest rate futures contract: a bet that interest rates will go up.
Suppose you think that interest rates will go up.
The transactions necessary to bet on your hunch are outlined in Table 7.80.
Table 7.8
Speculating with Eurodollar Futures Date
Futures Market
September 20 Sell 1 DEC 90 Eurodollar futures at 90.30.
September 25 Buy 1 DEC 90 Eurodollar futures at 90.12.
Profit: 90.30 B 90.12 = .18 Total Gain: 18 basis points $25 = $450
Chapter 7 58
Speculating with Outright Position
Interest rates have gone up as you predicted. Your profit (based on $25 per basis point contract) is:
Profit = (Sell Rate – Buy Rate)($25)
Profit = (90.30 – 90.12) = 0.18
0.18 is 18 basis points, each of which implies a $25 change in contract value so:
Profit = (Basis Points)(Value per Basis Point)
Profit = (18)($25) = $450
Chapter 7 59
Intra-Commodity T-Bill Spread
If you don’t know if rates will rise or fall, but do think that the shape of the yield curve will change, (that is the relationship between short term interest rates and long term interest rates will change) you might engage in an Intra-commodity T-bill spread.
If you think that the spread will narrow (the yield curve will become flatter) you would buy the longer term contract and sell the shorter term contract.
If you think that the spread will widen (the yield curve will become steeper), you would buy the shorter term contract and sell the longer term contract.
Chapter 7 60
Intra-Commodity T-Bill Spread
Suppose you have the following information (Table 7.9) regarding T-bills and T-bill futures contracts for March 20. The left 2 columns are T-bills, and the right 3 columns are futures contracts. You think that the yield curve will flatten and wish to trade to make a profit.
Table 7.9
Spot and Futures Eurodollar Rates for March 20 Time to Maturity or Fu-tures Expiration
Add-on Yield
Futures Contract
Futures
Yield
IMM In-
dex 3 months
10.00%
JUN
12.00%
88.00
6
10.85
SEP
12.50
87.50 9
11.17
DEC
13.50
86.50
12
11.47
Chapter 7 61
Intra-Commodity T-Bill Spread
Notice that the T-bills exhibit an upward sloping yield curve.
Notice that the futures contract yields also exhibit and upward sloping yield curve.
If the yield curve flattens, the yield spread between subsequent maturing futures contracts must narrow. That is, the difference between the yield on the December contract and on the September contract must narrow.
Since you think that the spread will narrow (the yield curve will become flatter) you would buy the longer term contract and sell the shorter term contract, as it is demonstrated in Table 7.10.
Chapter 7 62
Intra-Commodity T-Bill Spread
Table 7.10
Speculation on Eurodollar Futures Date
Futures Market
March 20
Buy the DEC Eurodollar futures at 86.50. Sell the SEP Eurodollar futures at 87.50.
April 30
Sell the DEC Eurodollar futures at 88.14. Buy the SEP Eurodollar futures at 89.02.
Profits: DEC
88.14
B86.50 1.64
SEP
87.50 B89.02 B 1.52
Total Gain: 12 basis points $25 = $300
Gain in Basis Points
Change in December Contract 1.64Change in September Contract -1.52
Net Change in Positions 12 basis points
Each Basis Point is worth $25
Profit
Net Change in Positions 12Basis Point Value $25Profit $300
Chapter 7 63
T-Bill/Eurodollar (TED) Spread
The TED spread is the spread between Treasury bill contracts and Eurodollar contracts.
In theory, Treasury bills should always have a lower yield than Eurodollar deposits.
T-bills are backed by the full taxing authority of the U.S. government.
Eurodollar deposits are generally not backed by the respective governments.
Thus, T-bills are a safer investment and as such, should pay a lower interest rate. Eurodollars are riskier and should pay a higher rate of interest.
How much lower/higher?
The amount of the difference depends upon world events. To the extent that the world situation is considered safe, the difference should be low. To the extent that the world situation is unsafe, the difference should be high.
Table 7.11 shows the transactions necessary to engage in a TED spread when you wish to bet that the spread will widen.
Chapter 7 64
T-Bill/Eurodollar (TED) Spread
Table 7.11
InterBCommodity Spread in ShortBTerm Rates Date
Futures Market
February 17
Sell one DEC Eurodollar futures contract with an IMM Index value of 90.29. Buy one DEC TBbill futures contract yielding 8.82% with an IMM Index value of 91.18.
October 14 Buy one DEC Eurodollar futures contract with an IMM Index value of 89.91. Sell one DEC TBbill futures contract yielding 8.93% with an IMM Index value of 91.07.
Profits:
Eurodollar 90.29 B89.91 .38
TBbill
91.07
B91.18 B .11
Total Profit: 27 basis points $25 = $675
Notice that the spread widened as the trader expected, allowing him/her to earn a $675 profit.
Chapter 7 65
Notes over Bonds (NOB)
The NOB is a speculative strategy for trading T-note futures against T-bond futures.
NOB spreads exploit the fact that T-bonds underlying the T-bond futures contract have a longer duration than the T-notes underlying the T-note futures contract. A given change in yields will cause a greater price reaction for the T-bond futures contract.
Thus, the NOB spread is an attempt to take advantage of either changing levels of yields or a changing yield curve by using an inter-market spread.
Chapter 7 66
Hedging with Interest Rate Futures
There are several ways that you can hedge with interest rate futures, including:
1. Long Hedges
2. Short Hedges
3. Cross-Hedges
Chapter 7 67
Hedging with Interest Rate Futures
Recall that the goal of a hedger is to reduce risk, not to generate profits.
Using interest rate futures to hedge involves taking a futures position that will generate a gain to offset a potential loss in the cash market.
This also implies that a hedger takes a futures position that will generate a loss to offset a potential gain in the cash market.
Chapter 7 68
Long Hedges
On December 15, a portfolio manager learns that he will have $970,000 to invest in 90-day T-bills six months from now, on June 15. Current yields on T-bills stand at 12% and the yield curve is flat, so forward rates are all 12% as well. The manager finds the 12% rate attractive and decides to lock it in by going long in a T-bill futures contract maturing on June 15, exactly when the funds come available for investment as Table 7.12 shows:
Table 7.12
A Long Hedge with TBBill Futures Date
Cash Market
Futures Market
December 15
A portfolio manager learns he will receive $970,000 in six months to invest in TBbills. Market Yield: 12% Expected face value of bills to purchase $1,000,000.
The manager buys one TBbill futures contract to mature in six months. Futures price: $970,000
June 15
Manager receives $970,000 to invest. Market yield: 10% $1,000,000 face value of TBbills now costs $975,000.
The manager sells one TBbill futures contract maturing immediately. Futures yield: 10% Futures price: $975,000
Loss = -$5,000
Profit = $5,000
Net wealth change = 0
Chapter 7 69
Long Hedges
With current and forward yields on T-bills at 12 percent, the portfolio manager expects to be able to buy $1,000,000 face -value of T-bills for $970,000 because:
360
))((Price Bill
DTMValue FaceDYValue Face
360
)90)(000,000,1($12.0000,000,1$Price Bill
On June 15, the 90-day T-bill yield has fallen to 10%. Thus, the price of a 90 day T-bill is:
360
)90)(000,000,1($10.0000,000,1$Price Bill
000,975$Price Bill
000,970$Price Bill
Thus, if the manager were to purchase the T-bill in the market, he would be $5,000 short.
360
))((Price Bill
DTMValue FaceDYValue Face
Chapter 7 70
Long Hedges
The futures profit exactly offsets the cash market loss for a zero change in wealth. With the receipt of the $970,000 that was to be invested, plus the $5,000 futures profit, the original plan may be executed, and the portfolio manager purchases $1,000,000 face value in 90-day T-bills.
Insert Figure 7.7 here
The idealized yield Curve Shit for the long Hedge.
Chapter 7 71
Short Hedge
Table 7.13
Hedging a Bank=s Cost of Funds Using Interest Rate Futures
Date
Cash Market
Futures Market
March
Bank makes nine-month fixed rate loan financed by a six-month CD at 3.0 percent and rolled over for three months at an expected rate of 3.5 percent.
Establish a short position in SEP Eurodollar futures at 96.5 reflecting a 3.5 percent futures yield.
September
Three-month LIBOR is now at 4.5 percent. The bank=s cost of funds are one percent above its expected cost of funds of 3.5 percent. The additional cost equals $2,500, i.e., 90/360 x .01 x $1 million..
Offset one SEP Eurodollar futures contract at 95.5 reflecting a 4.5 percent futures yield. This produces a profit of $2,500 = 100 basis points x $25 per basis point x 1 contract.
Total Additional Cost of Funds: $2,500
Futures Profit: $2,500
Net Interest Expense After Hedge: 0
Banks may wish to hedge their interest rate positions to lock in profits. Table 7.13 demonstrates how a bank that makes a one million dollar fixed rate loan for 9 months, and can only finance the loan with 6-month CDs, can hedged its position.
Because the bank hedged, its profits were not affected by a change in interest rates.
Chapter 7 72
Cross-Hedge
Recall that a cross-hedge occurs when the hedged and hedging instruments differ with respect to:
1. Risk level
2. Coupon
3. Maturity
4. Or the time span covered by the instrument being hedged and the instrument deliverable against the futures contract.
To illustrate how a cross-hedge is conducted, assume that a large furniture manufacturer has decided to issue one billion 90-day commercial paper in 3 months. Table 7.14 illustrate the cross-hedge.
Chapter 7 73
Cross-Hedge
Table 7.14
A CrossBHedge Between T-bill Futures and Commercial Paper
Date
Cash Market
Futures Market
Time = 0
The Financial V.P. plans to sell 90Bday commercial paper in 3 months in the amount of $1 billion, at an expected yield of 17%, which should net the firm $957,500,000.
The V.P. sells 1,000 TBbill futures contracts to mature in 3 months with a futures yield of 16%, a futures price per con-tract of $960,000, and a total futures price of $960,000,000.
Time = 3 mos. The spot commercial paper rate is now 18%, the usual 2% above the spot TBbill rate. Consequently, the sale of the $1 billion of commercial paper nets $955,000,000, not the expected $957,500,000.
The TBbill futures contract is about to mature, so the TBbill futures rate = spot rate = 16%. The futures price is still $960,000 per contract, so there is no gain or loss.
Opportunity loss = ?
Gain/loss = 0
Net wealth change = ?