Construction process of binary model of differentiation bank borrowers
Bank Loan Search Murray Z. Frank - Carlson School of ... · bank looks for a borrower, and at the...
Transcript of Bank Loan Search Murray Z. Frank - Carlson School of ... · bank looks for a borrower, and at the...
Bank Loan Search
Murray Z. Frank
ABSTRACT
This paper provides a search model of bank loans in which it is costly for firms and
banks to find each other. The negotiated loan interest rate must compensate both
parties for their search costs. In the model, if the original interest rate is low enough,
then an increase in the risk-free rate leads to an increase in the loan rate. But if the
original interest rate is high enough, then an increase in the risk-free rate leads to a
drop in the loan rate due to the impact on the present value of future profits. The
model provides a rationale for the sluggish adjustment of the aggregate volume of
bank loans. The main empirical puzzle relative to the model is why loan defaults
increase after the end of a recession, even as demand for new loans is increasing.
JEL classification: G21
Keywords: bank loan, search theory, financing constraint.
Helpful comments by Raj Singh and Pedram Nezafat are appreciate. I am responsible for any errors.
c©2011 Murray Z. Frank. All rights reserved. Pipper Jaffray Professor of Finance, Carlson School of
Management, University of Minnesota, Minneapolis, MN, USA 55455.
“Big banks in recent months eased standards on small-business lending for the first
time since late 2006, a Federal Reserve survey found, but customers of all sizes showed
little appetite for loans with the economy slowing. ... Indeed, bankers insist that they are
booking all the good loans they can find.” Wall Street Journal, August 17, 2010.
I. Introduction
When a bank extends a loan to a borrower, they sign a contract. A rich literature has
studied many aspects of bank lending in an effort to understand how the contractual
terms are determined. Theories have been developed based on risk-sharing, costly state
verification, screening, monitoring, managerial moral hazard, and credit rationing. Ob-
served contracts are often much simpler than predicted by such theories, which helped
stimulate interest in incomplete contracting models. There is also significant work (eg.
Bolton and Scharfstein (1990)) on the firm’s dynamic incentive to repay a bank loan that
has already been extended. The surveys by Gorton and Winton (2003) and Freixas and
Rochet (2008) provide valuable overviews of the extensive literature.
In this paper, the focus is on the impact of the logically prior problem: the borrower
and the lender must first find each other. Because the bank loan market is decentralized,
finding a new trading partner is neither free nor immediate. These up front costs must
be reflected in the market equilibrium loan terms. But this creates complexity because
it implies quasi-rents. Accordingly each loan that is actually observed must have been
expected to provide at least enough positive profits to offset the upfront search costs.
Exactly how the quasi-rents are expected to be split will in turn affect the still earlier
decisions of banks and firms to search.
The main contribution of this paper is to examine the effect of search on the bank loan
market equilibrium. Most previous studies implicitly assume that the bank loan market
is centralized and so there is no need to search. An important exception is Bizer and
DeMarzo (1992). They study an externality that arises when there is moral hazard and
borrowers borrow from more than one bank. Fresh lending reduces the chances that a
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previous loan will be repaid. They focus on the impact of such further borrowing. Duffie
and Manso (2007) and Duffie et al. (2009) analyze the effect of dynamic information
revelation with search – ‘percolation’. They find that this can also create an interesting
externality. In contrast the current paper assumes away such dynamic externality effects,
instead the analysis highlights the role of loan search costs on loan terms. In particular, the
current paper characterizes the steady state equilibrium interest rate, and the aggregate
quantity of loans.
A basic bank loan search/negotiate model is presented. This model is in the spirit of
Duffie et al. (2005) and Duffie et al. (2007) which in turn draws on the economics search
literature as in Diamond (1982), Mortensen and Pissarides (1999) and Rogerson et al.
(2005). In the model banks and firms engage in costly search for each other. Once a
partner has been found, loan terms must be negotiated. The lending relationship will
endure unless the borrower is hit by a very bad shock. A very bad shock causes the firm
to default on the bank loan and enter bankruptcy.
In a steady state equilibrium the flow of new matches must balance the flow of matches
that are ending. This implies that the firm failure rate is a crucial determinant of the
rate at which banks enter and the rate at which inactive firms start looking for a bank.
The loan terms are negotiated in a forward-looking manner. But the volume of loans
can only adjust to a demand shock more slowly because it may take time to find a
good match. Default shocks have an immediate impact on the volume of loans.1 The
equilibrium interest rate on loans reflect several forces. As usual loan default risk and the
bank’s opportunity cost of funds are important. Beyond these familiar effects, the loan
rate also serves to split the present value of the expected surplus created by the loan.
This third effect means that loan interest rates can differ from traditional models.
In the model the impact of an increase in the risk-free rate depends on the level of
current interest rates. If the original risk free rate is low enough then an increase, results
in an increase in the bank loan rate. But if the risk free rate is high enough, then an
1In reality default on a bank loan is not always so abrupt. Missing a payment can lead to renegotiationsof the terms of the loan. Empirically non-performing loans, loan loss provisions, and charge-offs are highlycorrelated in the aggregate quarterly data.
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increase reduces the bank loan rate. This may help explain why empirically the spread
on a bank loan is not a simple monotonic function of the prime lending rate.
Suppose that more businesses start looking for a loan. The bank’s bargaining position
improves because it is easier for a bank to find an alternative borrower. Both in the model
and empirically, the negotiated loan spreads are higher when demand is higher. However,
looking does not mean finding immediately. Finding can take time. Thus there is no tight
connection between the demand for loans at a moment in time, and the volume of loans
at that same moment. Instead there is a lag.
When the loan failure rate is higher the interest rate on loans increase to reflect the
extra risk of loss. The bank faces an extra expected cost of looking for new borrowers.
Empirically when charge-offs are high, banks tend to reduce their lending standards but
charge a higher spread as befits the riskier environment.
As observed by Santos and Winton (2008) bank lending standards do change signifi-
cantly over the business cycle. The standards tend to peak during recessions and fall back
during recoveries. The lending standards can be viewed as a proxy for the bank’s bar-
gaining power.2 A bank with a great deal of bargaining power can charge a high spread.
Consistent with this perspective, there is a strong positive correlation between the loan
spreads and lending standards.
Much of the prior literature focuses on cross sectional differences across banks. The
current paper focuses on aggregate fluctuations in loan volume and loan terms across time.
In the model the quantity of bank loans is adjusted both by extending new credit as well
as by canceling existing credit. This distinctions is, of course well known. Dell’Ariccia and
Garibaldi (2005) observed that there is a great deal of reshuffling of credit between banks.
As a result there is more volatility at the individual bank level and more persistence in the
volume of bank loans at the aggregate level. Craig and Haubrich (2006) make interesting
comparisons between the bank loan market and the job market. Loans exhibit much less
seasonality than do jobs.
2An alternative interpretation is provided by Dell’Ariccia and Marquez (2006). They suppose thatbanks have private information about the creditworthiness of the borrowers. The current paper assumessymmetric information about creditworthiness.
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Variation in bank lending over the business cycle has been studied by Santos and
Winton (2008) and Santos and Winton (2010). In contrast to the current paper’s focus
on aggregate fluctuations, they are more interested in cross sectional differences. In Santos
and Winton (2008) the focus is on the rates charged to bank dependent borrowers relative
to less dependent borrowers over the business cycle. Firms with access to public bond
markets are less susceptible to exploitation by their bankers when the credit markets
are soft. In Santos and Winton (2010) the focus is on the capital position of the banks
extending the loans.
II. The Model
In the model there are banks and firms. The firms have real investment opportunities,
but no money to make use of them. The banks have money but no direct access to real
investment opportunities.3 If the bank does not find a firm, then the money can be left
on deposit with the Central Bank earning a risk-free rate of return, ρ. The number of
banks is determined by free-entry, while the number of firms is fixed.
Time is continuous and denoted by t. The time horizon is infinite. The order of events
is that searching for a business partner must come before the negotiations. So first the
bank looks for a borrower, and at the same time the borrowers look for banks. When a
borrower is matched to a bank, they bargain over the terms of the loan. If they agree,
then a loan is extended and the money is put into production. Production produces
revenue continuously from which the agreed interest is paid to the bank continuously.
This continues until something bad happens to the firm.
When something bad happens to the firm it is bankrupt and loan is defaulted. When
a bankruptcy takes place, the bank replenishes capital from the owner. If it is profitable
to do so, the bank looks for a new borrower.
Two bankruptcy codes are considered. If bankruptcy is ‘terminal’, a new firm joins
the pool of unmatched firms when an existing firm is bankrupt. If bankruptcy is ‘fresh
3For a study of the impact of bank capital heterogeneity see Santos and Winton (2010).
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start’ then the bankrupt firm joins the pool of unmatched firms. The main results are
the same under either bankruptcy code.
A. Matching Flows
The requirements for a steady state flow equilibrium are essentially the same as in any
other search/matching model. There is a matching function that takes the current flows
of firms and banks and creates matches. Since matches are mutually beneficial, matches
result in deals. So the basic structure can be described before spelling out the details of
the firm and the bank’s Bellman equations.
Suppose that over a short period of time δt there are fδt firms that are looking for
a loan, and bδt banks looking for borrowers. Since the transition rate for an unmatched
firm is a, the total flow of firms getting a loan is afδt.
The matching function between firms and banks is µ = µ(f, b). Here µ is the number of
matches. Accordingly µ = af . This function is assumed to be continuous, differentiable,
with positive first and negative second derivatives, and have constant returns to scale.
It is conventional to define the ‘tightness’ of the bank loan market as θ = bf. When
θ gets large (a ‘loose credit market’) there are many banks and few firms looking. Firms
easily find banks, but banks have trouble finding firms. When θ gets small (a ‘tight
credit market’) there are few banks and many firms looking. Banks easily find firms, but
firms have trouble finding banks. Because banks have free entry, in an equilibrium θ is a
constant.
Let m(θ) denote the rate at which a bank that is looking for a borrower finds one.
The total loan flow is bm(θ). A loan requires both a lender and a borrower, so
af = bm(θ). (1)
As a result m = µ/b. The rate at which a bank finds a firm is,
m = m(θ) = µ(f
b, 1) = µ(θ−1, 1). (2)
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The rate at which a firm finds a bank is
a = µ(1,b
f) = θm(θ). (3)
Assume that µ takes the Cobb-Douglas form, µ(bt, ft) = m0b1−αfα, where, m0 > 0,
and 0 < α < 1. Since m = µ/b,
m(θ) = m0θ−α. (4)
At times it is more convenient to think about the mass of firms without a loan (f),
while at other times it is more convenient to think about the mass of firms that have a
loan (l). Due to loan size being fixed, this is also the total mass of bank loans. Because
the number of firms is fixed, it can be normalized to 1, and then write 1 = f + l.
The mass of loans evolves according to
dltdt
= θm(θ)(1− l)− sl. (5)
The first term on the right hand side is the increase in loans that is due to previously
unmatched firms finding a bank. The second term is the loss of loans due to bankruptcies
at existing firms that had a loan.
Much of the analysis focuses on the steady state. In a steady state dltdt
= 0. Thus the
steady state volume of loans must be
l =θm(θ)
s+ θm(θ)=
m0θ1−α
s+m0θ1−α. (6)
Condition 6 is the first key condition that is required for the analysis of a steady state
equilibrium.
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In the short run there may be many reasons not to be in the steady state. In that
case 5 needs to be solved using a given initial condition, denoted by l(0) = l0. Using the
initial condition, the solution of 5 is
l(t) =θm(θ)
s+ θm(θ)+ (l0 −
θm(θ)
s+ θm(θ))e−(s+θm(θ))t. (7)
Notice that if the initial condition is at the steady state, then the system stays there. The
rate at which departures from the steady state vanish depends in a simple manner on the
matching rate and the shock rate.
This subsection provides the steady state mass of loans. It also shows that if for some
reason the mass of loans is not at the steady state value, then it gradually returns to
the steady state. This depends on the fact that θ is kept constant by bank free entry.
In a more general setting, in which θ itself fluctuated, richer loan dynamics might be
observed.4
B. Firm Problem
A firm either has a lender or else it does not. If the firm does not have a lender, it can
look for one, or it can decide not to bother looking. Looking is costly. Getting a suitable
loan is beneficial since it permits production. Let Vfu be the expected present value of a
firm that is unmatched to a lender. Let Vfm,t be the expected present value of a firm that
is matched to a lender as of t.
Consider a short time interval δt. Over the short time interval δt the firm incurs a
search cost (‘hunt’) of −hδt and gets a loan at rate aδt. If the firm does not search then
4A potentially interesting extra feature to consider is the fact that the loan money may not be usedfully at the moment that the agreement is reached. Thus many firms have unused loan commitments atbanks. Using a loan commitment is crucially different from using a new loans. A loan commitment canbe drawn down immediately. A new loan which requires finding a lender which takes time. Interestinganalysis of lines of credit is provided by Sufi (2009) and by Acharya et al. (2010). Incorporating linesof credit into a loan search model is potentially quite interesting, but goes well beyond the scope of thecurrent paper. Figure 1 shows that loans continue to fall even after the end of a recession. To what extentis this do to finally recognizing poor performance? TO what extent is this due to ‘excessive’ drawingdown of lines of credit during the recession?
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a = 0. If the firm does search then a > 0. Because search is costly −h < 0. If a bank
is found during δt then the firm can negotiate a loan and get Vfm,t+δt. Or, the firm can
keep looking and get Vfu,t+δt. If no bank is found then the firm gets Vfu,t+δt.
First consider an unmatched firm. The Bellman equation is,
Vfu,t =−hδt
1 + ρδt+ aδt
max{Vfm,t+δt, Vfu,t+δt}1 + ρδt
+ (1− aδt)Vfu,t+δt1 + ρδt
(8)
This can be rewritten as
ρVfu,t = −h+ a(max{Vfm,t+δt, Vfu,t+δt} − Vfu,t+δt) +Vfu,t+δt − Vfu,t
δt. (9)
Take the limit as δt→ 0, and drop the time subscripts,
ρVfu = −h+ a(max{Vfm, Vfu} − Vfu) +dVfudt
. (10)
If the firm is in a steady state,dVfudt
= 0.
There will be surplus to be split between a firm and a bank that are matched. The
negotiation over loan terms are solved using generalized Nash bargaining. This means
that the surplus will be captured. Accordingly Vfm > Vfu, and so
ρVfu = −h+ a(Vfm − Vfu). (11)
Next consider a matched firm. A matched firm borrows M from the bank which is
immediately put into production, and agrees to pay ongoing interest rate r. As long as
nothing bad happens to the firm, over a short time period δt the production generates a
revenue flow of AMδt , and the firm uses the revenue to honor its loan agreement with
the bank. With probability s (‘shock’) something very bad happens, and so the firm is
bankrupt. Since bankruptcy is forever the firm gets zero from then on.
The derivation of the Bellman equation for a matched firm follows the same steps as
for an unmatched firm. Thus,
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ρVfm = (1− s)M(A− 1− r). (12)
At times it is useful to rewrite the flow conditions in present value form as,
Vfu =−h+m0θ
1−αVfmρ+m0θ1−α
(13)
Vfm =(1− s)M(A− 1− r)
ρ. (14)
C. Bank Problem
A bank is in one of three conditions: inactive, unmatched and looking for a borrower,
matched with a borrower. The present value of being an unmatched bank is denoted Vbu.
The present value of being a bank that is matched with a borrower is Vbm. Each bank
has M dollars and will make either no loans or one loan to a firm. Any profits or losses
are absorbed by the owner on an ongoing basis to maintain M . This gets rid of the need
to keep track of the bank’s capital position.5
Following the same procedure as for the firm, the bank’s payoffs can be written in flow
form. For an unmatched bank that is looking for a borrower, the Bellman equation is,
ρVbu = −k +Mρ+m(θ)(Vbm − Vbu). (15a)
For a matched bank, the Bellman equation is,
ρVbm = −M + (1− s)M(1 + r) + s(Vbu − Vbm). (16)
The left hand side give the flow of gains to the bank according to the state. An
unmatched bank with no borrower (state Vbu) is spending money to search, and leaving
money on deposit earning the risk-free rate. With probability m this bank will transition
from the current state to state Vbm which gives a gain of Vbm − Vbu.5Since everyone is risk-neutral, keeping track of the gains or losses would not affect the inferences. All
banks make the same decisions. It would simply add extra notation.
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An inactive bank invests M at the risk-free rate. Thus the inactive bank has a present
value of M .
A bank with a borrower (state Vbm) has the money loaned out to a firm. As long as
nothing bad happens to the firm, the bank receives a flow of interest payments. However,
if something bad happens to the firm (probability s), then both the principal and the
interest are lost. The bank transitions back to state Vbu.
The bank conditions can also be expressed in present value form
Vbm =−M + (1− s)M(1 + r) + sVbu
ρ+ s(17)
Vbu =−k +Mρ+m(θ)Vbm
ρ+m(θ). (18)
D. Free Entry of Banks
The next step is examine the aggregate willingness of banks to supply loans. This is
determined by free entry. There are an infinite number of inactive banks that all deposit
their money with the Federal Reserve earning the risk-free rate. An inactive bank may
choose to become active by looking for a borrower. Since there are more potential banks
than firms, free entry limits the number of banks. By free entry, any entry date must give
the same expected payoff, and this value must be M , and so
Vbu = M. (19)
Free entry together with the first flow conditions gives,
Vbm =k
m(θ)+M (20)
This says that the value of being a matched bank is given by the value of the capital
plus the cost of search divided by the matching probability. Notice that the matching
probability will adjust in order to maintain this condition.
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From free entry and the second flow condition,
Vbm =Mr(1− s)ρ+ s
. (21)
The using this condition together with (Vbu = M) and the first flow condition gives
r(1− s)− (ρ+ s)− k(ρ+ s)
m(θ)M= 0. (22)
This says that the probability of a match is in effect pinned down by the bank’s entry
decision.
Condition 22 is the second key condition that is required to solve for the steady state
equilibrium. The number of banks, or equivalently the volume of bank loans is controlled
by the entry decisions. Since m is a function of θ, 22 can also be viewed as a loan supply
relationship between θ and r, r = s+ρ1−s + k(s+ρ)θα
(1−s)Mm0. This version of the loan supply curve
in θ− r space has an intercept of s+ρ1−s . The slope is positive and the curve is concave, with
the degree of concavity controlled by α. As α increases towards 1, the curve gets flatter.
Bank willingness to lend depends on the interest it expects to be able to earn. If r is
greater, then more banks enter the loan market causing θ to increase. At times it may
also be convenient to reexpress 22 as θ = ( (r(1−s)−(ρ+s))Mk(ρ+s)
)1/α. For this to have an interior
solution requires r(1− s)− (ρ+ s) > 0. The following proposition follows from taking the
appropriate partial derivatives.
Proposition 1 Assume that r(1− s)− (ρ+ s) > 0, so that there at least some banks that
are trying to find borrowers. Then credit market tightness, θ is increasing in r, M , and
decreasing in s, ρ, k. If r is low enough (r(1 − s) − s − ρ − 1 < 0), then θ is increasing
in α, but if r is high enough (r(1− s)− s− ρ− 1 > 0), then θ is decreasing in α.
In the bank problem it is assumed that there are a suitable measure of infinitessimal
banks, each of which are making a single loan. As long as nothing else is changed,
the model could have banks with multiple loans. In that case it would still need to
be assumed that the banks are infinitessimal, that there are no economies in search,
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bargaining, operations, etc. As long as such conditions are satisfied, nothing important
changes in the equilibrium if banks have more capital and make more loans.
E. Bargaining
When there is a match, the two parties bargain over the terms of the loan. For
simplicity the size of the loan is fixed at M . The only thing left to negotiate is the loan
interest rate. The outcome of the bargaining depends on the relative bargaining strengths
of the bank and the firm. A generalized Nash bargaining solution is assumed to hold.
The bank’s bargaining power is denoted β, and the firm’s bargaining power is (1− β).
When a bank and a firm are matched they must agree on the terms of the loan, i.e.
the interest rate. In order for there to be anything to negotiate, both parties must agree
to participate. The bank’s participation constraint is
Vbm − Vbu ≥ 0. (23)
If this were not true, the bank could simply refuse to make the loan. Using 21, and the fact
that Vbu = M , this provides a lower bound on the interest rate, r ≥ s+ρ1−s . This constraint
shows that, quite naturally, the lower bound increases when the risk-free interest rate (ρ)
increases, and also when the risk of bankruptcy (s) increases.
The firm’s participation constraint is
Vfm − Vfu ≥ 0. (24)
Using 14 and 13, this provides an upper bound on the interest rate, r ≤ A− 1 + h(1−s)M .
Accordingly any negotiated interest rate must satisfy
s+ ρ
1− s≤ r ≤ A− 1 +
h
(1− s)M. (25)
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If the parameters are such that these cannot hold simultaneously then there is no mutually
satisfactory negotiated loan deal that is feasible. In what follows it is assumed that the
parameters satisfy this restriction. High productivity (A) and low risk-free rate (ρ), and
low risk of bankruptcy (s) are helpful to making a mutually beneficial deal feasible.
Assume that bargaining satisfies the generalized Nash bargaining solution. The bank’s
bargaining power is denoted β. The bargaining problem is
rN = arg max(Vbm − Vbu)β(Vfm − Vfu)1−β. (26)
In the model the size of the loan is taken to be exogenous. There are several plausible
ways to endogenize the loan size. The easiest is to let it also be chosen by the Nash
bargaining. In that case instead of one first order condition from the negotiation, there
are two. This complicates the algebra without enough extra insight to be worth it.6
To solve this problem note that this problem assumes that the bargaining is a con-
tinuous process. In this case Vbu and Vfu reflect the payoff that would be obtainable by
leaving the match. Clearly these do not depend on the value of r. Accordingly neither
Vbu nor Vfu are functions of the current interest rate.7
The first order condition can be written as
Vfm − Vfu =(1− β)(ρ+ s)
ρβ(Vbm −M) (27)
Then using 20
Vfm − Vfu =k(1− β)(s+ ρ)
ρm(θ)β. (28)
6An alternative approach is to allow the loan size to be pinned down by liquidity constrains in themanner of Holmstrom and Tirole (2011). This is being examined in a separate paper. A key implicationis that because search is costly, the search process can interact with the firm’s liquidity. This can resultin firms searching for a bank at first, but giving up after a while. They might no longer have enoughliquidity even if they find a bank – a discouraged entrepreneur effect.
7The first order condition is
β(Vbm − Vbu)β−1 ∂Vbm∂r
(Vfm − Vfu)1−β + (Vbm − Vbu)β(1− β)(Vfm − Vfu)−β∂Vfm∂r
= 0.
Note that∂Vfm∂r = −M(1−s)
ρ and, ∂Vbm∂r = M(1−s)
s+ρ .
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Using the firm’s participation constraint, the negotiated interest rate on a loan is
rN = A− 1 +h
M(1− s)− k(1− β)(s+ ρ)(ρ+ θm(θ))
ρm(θ)βM(1− s), (29)
This is the third key component need to compute the steady state equilibrium. The
properties of this condition are collected as follows.
Proposition 2 The negotiated loan interest rate, rN , is increasing in A, h, m, β and
decreasing in k. The effect of ρ is given by ∂rN
∂ρ=
(1−β)(smF−ρ2)k(1−s)Mβρ2m
and so it has the
same sign as smF − ρ2. The effect of an increase in the separation rate is given by
∂rN
∂s= hmβρ−k(1+ρ)(ρ+mθ)(1−β)
(s−1)2Mmβρ, which will be negative if k (1 + ρ) (ρ+mθ) (1− β) > hmβρ,
and positive in the reverse case. The impact of credit market tightness is ∂rN
∂θ=
(β−1)(θm0+αρθα)(s+ρ)k(1−s)Mθβρm0
< 0, and ∂2rN
∂θ2= (β−1)(α−1)(s+ρ)(θα)kα
(1−s)Mθ2βm0> 0
The more costly it is for the firm to search, the higher the interest rate that the bank
can charge. The more costly it is for the bank to search, the lower the interest rate that
the bank will be able to charge since everyone knows that the bank’s implicit threat to
walk away is less attractive.
It is interesting that the matching probabilities, the bargaining power, and the risk free
rate all operate through the impact on the compensation for the bank’s cost of search.
If it does not cost the bank anything to search, then the bank is able to claim all of
A− 1 + hM(1−s) .
The impact of an increase in the separation rate depends on, among other things, the
relative search costs of the two parties. If the bank’s search cost (k) is high, then an
increase in the separation rate tends to have a negative impact on the loan interest rate.
If the firm’s search cost is high (h) then an increase in the separation rate tends to have
a positive impact on the loan interest rate.
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F. Steady State Equilibrium
The steady state equilibrium is a solution for θ, r, l. Collecting the crucial conditions
l =m0θ
1−α
s+m0θ1−α
r =s+ ρ
1− s+
k (s+ ρ) θα
(1− s)Mm0
r = A− 1 +h
M(1− s)− k(1− β)(s+ ρ)(ρ+m0θ
1−α)
ρm0θ−αβM(1− s)
The equivalent to setting loan supply equal to loan demand is to simultaneously solve 22
and 29 to find θ∗. Hence,
s+ ρ
1− s+
k (s+ ρ) θα
(1− s)Mm0
= A− 1 +h
M(1− s)− k(1− β)(s+ ρ)(ρ+ θm0θ
−α))
ρm0θ−αβM(1− s)
This simplifies to s + ρ + k(s+ρ)θα
Mm0= (1 − s)(A − 1) + h
M− k(1−β)(s+ρ)(ρ+θm0θ−α))
ρm0θ−αβM. This
equation is easily solved numerically when there are specific parameter values. If θ = 1/2
it also has a closed form solution.8
Consider plotting with θ on the x-axis, and r on the y-axis. Then the free entry (loan
creation) condition is an increasing function that is concave down. The loan interest rate
condition is a decreasing function that is convex. The intersection of these two curves
solves for θ and r. Then the value of θ is substituted into the loan market steady state
condition to get the steady state volume of loans.
With the notable exception of firm productivity (A) many of the parameters affect
both the free entry condition and the loan interest rate condition. Thus the impact of
8(s+ ρ)M + k(s+ρ)θα
m0= M(1− s)(A− 1) + h− k(1−β)(s+ρ)(ρ+θm0θ
−α))ρm0θ−αβ
((s+ ρ)M −M(1− s)(A− 1)− h)ρm0θ−1/2β = ρβk (s+ ρ)− k(1− β)(s+ ρ)(ρ+m0θ
1−1/2)Define, a1 = ((s + ρ)M − M(1 − s)(A − 1) − h)ρm0β, a2 = ρβk (s+ ρ), a3 = k(1 − β)(s +
ρ). Then write, a1θ(−1/2) = a2 − a3(ρ + m0θ
1/2). The solution is given by, θ = ± a1a3m0
−1
a23m20
(−a2 + ρa3)(
12a2 −
12ρa3 + 1
2
√−2ρa2a3 − 4a1a3m0 + a22 + ρ2a23
)Clearly only the positive solution for θ makes economic sense.
15
most shocks will depend on which of the curves is affected more strongly, and in which
direction they move.
The traditional real business cycle models interpret cycles as shocks to productivity.
A recession is then a drop in A. That will result in a drop in θ, and a drop in r. The
drop in θ will also translate into a drop in l since ∂l∂θ> 0. A recovery is an increase in A.
This will have the reverse effects.
III. Numerical Example
Consider the following set of parameter values: s = 0.05, ρ = 0.04, k = 0.25, m0 =
0.50, M = 1, α = 0.50, A = 5, h = 0.25, β = 0.50.
Then the bank loan creation/free entry curve is an increasing function with a small
amount of curvature close to the origin. However it is actually fairly flat at about 0.13.
The loan interest rate is essentially a straight line with a negative slope. If A shifts
around, there will be a great deal of movement in the tightness of the credit market, but
almost no change in the rates charged on loans.
IV. Fresh Start Bankruptcy
Bankruptcy is sometimes said to provide an insolvent borrower an escape from the
debt burden in order to have a ‘fresh start.’ The borrower loses the assets, but is able to
start again without any debt overhang. In contrast to terminal bankruptcy, is not stuck
with a payoff of zero for ever after. The purpose of this subsection is to trace out the
equilibrium impact of this extra benefit to a borrower in the case of a bad event.
The bank’s problem is not changed. The bank still gets paid if and only if the borrower
is solvent. The bank is only affected in equilibrium if the agreed upon interest rate is
affected.
16
The firm’s problem does change. The firm’s flow payoff conditions are now
ρVfu = −h+m(θ)(Vfm − Vfu) (30)
ρVfm = (1− s)M(A− 1− r) + s(Vfu − Vfm) (31)
In the event of bankruptcy the firm gets to start again in state Vfu. This shows up in the
flow payoff when a loan is obtained. There is an extra term +s(Vfu − Vfm).
The present value conditions are
Vfu =−h+ θm(θ)Vfmθm(θ) + ρ
Vfm =(1− s)M(A− 1− r) + sVfu
ρ+ s
The only change is to the expression for Vfm.
Solving these simultaneously gives
Vfm =(1− s)M(A− 1− r)(ρ+ θm(θ))− hs
ρ(ρ+ s+ θm(θ))
Vfu =(1− s)M(A− 1− r)θm(θ)− h(ρ+ s)
ρ(ρ+ s+ θm(θ))
The negotiation problem has the same structure as in the terminal bankruptcy problem.
The bargaining problem is
rN = arg maxr
(Vbm − Vbu)β(Vfm − Vfu)1−β. (32)
The bank’s problem is unchanged, and so Vbm − Vbu is the same as before. The firm’s
participation constraint simplifies to
Vfm − Vfu =(1− s)M(A− 1− r) + h
(ρ+ s+ θm(θ))≥ 0.
The denominator does differ from the terminal bankruptcy expression. However, in both
cases the denominator is positive. Thus the critical issue is the numerator. The numerator
17
is the same as in the terminal bankruptcy case. Since this is key for participation, it turns
out that the upper bound on the interest rate is
r = A− 1 +h
(1− s)M.
This is exactly the same as the upper bound on the interest rate as in the terminal
bankruptcy case. Using the same steps as for terminal bankruptcy, the next proposition
is readily derived.
Proposition 3 The steady state equilibrium interest rate with fresh start bankruptcy
(rN = A − 1 + hM(1−s) −
k(1−β)(s+ρ)(ρ+θm(θ))ρm(θ)βM(1−s) ) is exactly the same as under terminal
bankruptcy.
Since the bank’s problem is unchanged, and the equilibrium interest rate is unchanged,
so too is the overall bank loan market equilibrium.
V. Bank Loan Market Facts
The data is all aggregate quarterly US data. As described in the Appendix, the main
source of the data is from the Federal Reserve. Lending standards and loan spreads
data are from the Survey of Senior Loan Officers that is carried out by the Federal Re-
serve Board (http://www.federalreserve.gov/boarddocs/snloansurvey/). This is a survey
of about 60 large domestic banks and 24 branches of foreign banks. Accordingly it is
weighted towards the larger banks.
Some data series such as the total volume of business loans, have been collected from
the start of 1947 (255 quarters). Other data series such as the number of new businesses
formed are only available since the 1990s (67 quarters). All the data ends as of the 3rd
quarter of 2010. For consistency with the macroeconomic literature the data is filtered
using the usual Hodrick-Prescott filter. The use of the filter seems to reduce the volatility,
but otherwise does not cause major changes to the inferences.
18
As illustrated in Figure 1. the volume of business loans is strongly nonstationary. So
it is first differenced before the usual Hodrick-Prescott filter is applied.9 In the raw data
two fact jump out. First, as expected business loans peak during recessions. Second, the
decline persists even after the economy comes out of the recession. In other words, the
volume of business loans lags the cycle. The average quarterly growth in business loans
from April 1947 to July 2010 was 1.88% a bit below the 2.2% for all loans and leases.
Figure 2 shows the typical loan rate spread above the bank’s cost of funds. Like the
total volume of loans, the spread peak during recessions. Unlike the volume of business
loans, the spreads seem to start dropping earlier, perhaps even before the recession has
fully ended. The lending standards behave similarly to the spreads as depicted in Figure
3.
There are several closely related measures available for troubled loans. A commercial
loan that worries the bank induce an addition to the loan loss reserve, or it can already be
nonperforming, or finally the bank can take a charge-off. These stages of trouble are high
correlated empirically, and it makes little difference for current purposes, which is used.
The charge-offs seem to be the most closely related to the search model, and so that is the
focus here. However, in a more refined analysis, these three stages of loan trouble could
be distinguished. The charge-offs are depicted in Figure 4. The charge-offs help explain
the total loan volume. In particular charge-offs seem to peak after a recession is already
over. Similar patterns are found in the other measures of problem loans. Apparently this
pattern does not depend too much on exactly how problem loans are measured. There
are lingering effects of a recession on existing loans.
To examine whether there are significant dynamics, Table 1 reports the results from
running an AR-1 model separately on each series. All of the series are highly auto-
correlated even after being filtered. This differs from the individual bank level results
reported by Craig and Haubrich (2006). At the individual bank level they report much
less autocorrelation.
9The use of first differencing makes only small differences to the inference to be drawn from the data.
19
To see whether there are cross lagged effects a VAR with one lag in each series was
run. Many of the cross effects are reasonably small. Mostly they seem fairly easy to
understand. Apart form the lagged own effects, the following cross effects were observed:
• DLoan: negative impact from lagged standards.
• Standards: positive effect from lagged spreads, negative effect from lagged DS&P
500.
• Spreads: nothing significant.
• Prime Rate: negative effect from lagged DLoans, positive effect from lagged demand.
• Demand: positive effect from lagged DLoans, negative effect from lagged prime rate,
positive effect from lagged DS&P 500.
• DS&P 500: nothing significant.
• Charge-offs: positive effect from lagged spreads, fairly strong negative effect from
lagged demand, positive effect from lagged non-performing loans.
• Non-performing: negative effect from lagged DLoans, positive effect from lagged
spreads.
Individually each of the cross effects can be interpreted in terms of the search model.
But effect by effect verbal interpretations does not easily capture the consistency of ex-
planations. Hence, these observations are recorded here, but not interpreted for now.
Table 2. reports the pairwise correlations. Several of the correlations are quite strong.
Lending standards and loan spreads are highly positively correlated as illustrated in Figure
5. Both are involved in clearing the loan market. They play a complementary role. If
standards can be correctly interpreted as a measure of bank bargaining power, this is
saying, quite reasonably, that when the bank has more bargaining power, it charges a
higher mark-up. When there is an increase in the stock market (DS&P500) there is a
reduction in the bank’s bargaining power. When bank standards are high, loan demand
is low.
20
Troubled loans do have rather strong correlations with other aspects of the market.
Many of these are independent of which measure of troubled loans is used. When there
are more charge-offs, the volume of loans falls. This is almost mechanical. For this not
to be true would require extra effort on the part of banks to very rapidly replace the
failed loans. When charge-offs are high, the prime rate tends to be low. Presumably this
reflects a policy response function by the Federal Reserve. When the economy is weak,
charge-offs will tend to be high, and loan demand will tend to be low. When the economy
is weak, the Federal Reserve will commonly try to reduce interest rates in an effort to
stimulate the economy. This will show-up in the data as a low prime lending rate.
In the survey data the loan demand variable requires a bit of care. In a search model
there is a distinction between many searchers and many matches. Either could be what the
Loan officers have in mind. These are likely to be correlated. But they do have somewhat
different interpretations for the connection between the model and the empirical data.
The connection between demand and both spreads and standards will be discussed at
greater length in relation to the numerical results.Numerical Results
To calibrate the model requires taking a stand on parameter values. For some of these
parameters appropriate values are fairly clear. For other parameters it is less clear.
The total number of firms in the USA is about 6 million. The total number
of banks is about 8000 currently, and falling. So somehow I guess that I need to
standardize. Similarly I suppose we standardize at loan size of M = 1. For a
quarterly risk-free interest rate about 0.013. For the bargaining power start with
β=0.5 One source for firm survival there is no accepted number. Some data is here:
http://www.bls.gov/bdm/us age naics 00 table7.txt. So it seems that maybe 6% of firms
fail each year. So maybe 1.5% per quarter fail. Other data on firm birth and death is
here: http://www.sba.gov/advo/research/dyn us tot.pdf. I do not have any strong idea
about the values of h and k. Maybe 10% of the size of the loan I suppose. (This is a very
wild guess. Presumably it is higher for the firm than it is for the bank – at least for small
firms.) The value of A must be bigger than the costs or else there will not be an interior
loan solution. I guess 25% might be a number to start with. Most likely that will prove
to be too high eventually.
21
VI. Implications for the Bank Loan Market
In the model each bank has the same amount of capital and is looking to make (or
has made) a single bank loan. As long as there are constant returns to scale, no search
economies, and each bank remains small relative to the market this is innocuous. Suppose
that the government suddenly gave each operating bank an extra M dollars. Each bank
would pass the extra cash back to the owner leaving the original loan market equilibrium
unchanged.
Suppose that the government recognized this, and so passed a law forbidding an op-
erating bank from passing back the extra cash. Entry of new banks would cease. If it
caused the credit market tightness to become excessively loose, then that would enhance
the bargaining power of the existing borrowers, and so the interest rates on existing loans
would drop. But that requires that the banks spend extra cash looking for the (suddenly
unprofitable) borrowers. A sensible bank would not spend the money hunting for such
a borrower. Instead they would deposit the extra cash back with the Federal Reserve,
leaving θ unchanged.
The implication is that within this kind of search model context, giving each bank
extra cash would benefit the bank shareholders, lead to extra cash on deposit at the
Federal Reserve, and leave the loan market equilibrium unchanged.
Suppose that the government wants to encourage banks to make more good loans.
Within the context of the model such a policy needs to focus on equation 22 and proposi-
tion 1. The natural place to focus is on k the cost of searching for borrowers. For example
The government could in effect provide a tax subsidy to cover those costs. That would
increase the number of banks looking to place loans. Of course, proposition 2 warns that
there are further equilibrium effects to consider. Decreasing the bank’s search cost will
also translate into a windfall for existing borrowers as the interest rates on existing loans
will also tend to drop.
This highlights a general policy issue that goes well beyond the specifics of the current
model. Attempts to change the quantities of loans are likely to have important implica-
tions for the terms of other existing loans. Exactly how this works out will depend on the
22
specifics of a particular model. This creates a concern that the secondary effects can be
quantitatively more significant, and much harder to predict, than the intended primary
effect of a policy.
The bank loan literature (eg. Gorton and Winton (2003), Freixas and Rochet (2008))
has paid a great deal of attention to both adverse selection and moral hazard in the loan
making process, see Petersen and Rajan (1995), and, Diamond (1991). Acharya et al.
(2010) consider the impact of aggregate risk. The search friction considered in this paper
is complementary to the usual incentive effects as in Diamond (1984), Rajan (1992).
The potential importance of search is already suggested by the importance of distance
in lending that was documented by Petersen and Rajan (2002).
Weil and Wasmer (2004) and Petrosky-Nadeau and Wasmer (2010) study Diamond-
Mortensen-Pissarides style models models with two frictions, one in the financing, and
the other in the labor market. In contrast to the current paper, their main interest is in
the impact of a financial friction on the labor market. A stylized financing search friction
is used to address puzzles about the job market.
The history of the Senior Loan Officer survey is described by Schreft and Owens (1991).
The survey goes back to late 1964, and the questions asked have changed somewhat
over the years. They observe that: credit standards and willingness to lend are very
closely connected, banks are less willing to lend during recessions, the Loan Officers report
increasing standards, but rarely report a lowering of standards.
Lown and Morgan (2006) use a VAR analysis to show that credit standards as reported
in the Senior Loan Officer survey dominates loan interest rates in terms of the ability
to explain the variation in business loans outstanding, and overall output. It is well
understood that loan contracts are multidimensional, and so in general ‘tightening’ could
refer to adjustments on a variety of alternative loan contractual terms. Lown and Morgan
(2006) suggest that ‘tightening’ and ‘unwillingness to lend’ be interpreted in terms of
informational frictions.
23
VII. Conclusion
The analysis in this paper may provide a start on consideration of the corporate finance
implications of search. But the lack of centralized loan markets is a broad topic, with
many aspects that go far beyond the analysis in this paper. For example recently there
has been some surprise in policy circles at the relative non-response of bank loans to the
increases in bank liquidity engineered by the Federal Reserve. From a search perspective
this is not surprising. Part of the impact would be on the entry and exit decisions of
banks, and empirically we are observing some banks shutting down. Part of the impact
would be on the bank’s own savings behavior which also seem to have taken place. The
marginal impact on actual bank lending could easily be zero or close to zero in a natural
equilibrium search model.
There are potentially extremely interesting potential interaction effects between or-
dinary bank loans and other forms of corporate financing. Presumably search implies a
greater need for a firm to hold cash reserves. But what is the mix between actual cash
holdings and lines of credit? How do each of these respond to aggregate shocks? How
does the use of equity affect the theory? If some equity is publicly traded how does
this cross over to the terms in the debt market. Presumably effects akin to those in
Duffie and Manso (2007) will arise. But how do they interact with more familiar tax
and bankruptcy cost considerations? Clearly there is a great range of potential corporate
finance implications that stem from the need to find willing investors. There is much to
do.
24
VIII. Appendix: Data Sources
The source of data is FRED: http://research.stlouisfed.org/fred2/, except where noted
below. All data from that source was extracted at quarterly frequency. The following
series were extracted:
• Loans. BUSLOANS (Commercial and Industrial Loans at All Commercial Banks).
The data was extracted at quarterly frequency with units ‘billions of dollars’.
LOANS (Total Loans and Leases at Commercial Banks).
• Standards. DRTSCILM (Net Percentage of Domestic Respondents Tightening Stan-
dards for Commercial and Industrial Loans Large and Medium Firms). Quarterly,
Percentage.
• Spread. DRISCFLM (Net Percentage of Domestic Respondents Increasing Spreads
of Loans Rates over Banks’ Cost of Funds Large and Medium Firms). Quarterly,
Percentage.
• Prime. MPRIME (Bank Prime Loan Rate), Quareterly, Percentage.
• Demand. DRSDCILM (Net Percentage of Domestic Respondents Reporting
Stronger Demand for Commercial and Industrial Loans Large and Medium Firms).
• New Firms. Quarterly data on the births and deaths of establishment is taken from
http://www.bls.gov/web/cewbd/table9 1.txt. It starts in Septmber 1992 and ends
in December 2009.Related data is available at annual frequency up to 2005 here:
http://www.ces.census.gov/index.php/bds/bds database list. Further links can be
found at: http://www.sba.gov/advo/research/data.html.
• Market. SP500 (S&P 500 Index), Quarterly, Index Level.NFCPATAX (Nonfinancial
Corporate Business: Profits After Tax), MVEONWMVBSNNCB (Market Value of
Equities Outstanding - Net Worth (Market Value) - Balance Sheet of Nonfarm
Nonfinancial Corporate Business).
25
• Charge-offs. NCOCMC (Commercial Net Loan Charge-offs), Quarterly, Ratio.
USLSTL (Net Loan Losses / Average Total Loans for all U.S. Banks), NPCMCM
(Nonperforming Commercial Loans), NPTLTL (Nonperforming Total Loans), NCO-
TOT (Total Net Loan Charge-offs).
In each case the first listed data series is taken to be the main definition. The remaining
series were extracted for use as robustness checks.
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Bizer, D.S., and P.M. DeMarzo, 1992, Sequential banking, Journal of Political Economy100, 41–61.
Bolton, P., and D.S. Scharfstein, 1990, A theory of predation based on agency problemsin financial contracting, The American Economic Review 80, 93–106.
Craig, B., and J.G. Haubrich, 2006, Gross loan flows, Federal Reserve Bank of Cleveland06–04.
Dell’Ariccia, G., and P. Garibaldi, 2005, Gross credit flows, Review of Economic Studies72, 665–685.
Dell’Ariccia, G., and R. Marquez, 2006, Lending booms and lending standards, Journalof Finance 61, 2511–2546.
Diamond, D.W., 1984, Financial intermediation and delegated monitoring, Review ofEconomic Studies 51-166, 393–414.
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27
Tab
le1.
Sum
mar
ySta
tist
ics.
The
num
ber
ofob
serv
atio
ns
vari
esdue
todiff
eren
tst
arti
ng
dat
es.
All
dat
aen
ds
wit
hth
e3r
dquar
ter
of20
10.
HP
Filte
red.
All
ofth
em
eans
are
esse
nti
ally
zero
.T
he
sourc
esof
all
dat
ait
ems
isdes
crib
edin
the
app
endix
.D
Loa
ns
Loa
ns
Sta
ndar
ds
Spre
adP
rim
eD
eman
dS&
P50
0D
S&
P50
0C
har
ge-o
ffN
onP
erf
Num
ber
Obs
254
255
8282
247
7621
521
490
90Sta
ndar
dD
ev17
.52
45.9
717
.61
29.1
41.
3420
.28
80.4
739
.62
0.32
0.42
AR
-10.
730.
970.
820.
860.
840.
740.
880.
350.
830.
93Z
-sco
re44
.14
105.
214
.213
.11
33.4
68.
2846
.48
8.09
13.0
431
.65
28
Tab
le2.
Pai
rwis
eC
orre
lati
ons.
HP
filt
ered
.DL
oans
isco
nst
ruct
edby
takin
gth
efirs
tdiff
eren
ceof
Loa
ns
pri
orto
the
HP
filt
erin
g.D
S&
P50
0is
const
ruct
edby
takin
gth
efirs
tdiff
eren
ceof
S&
P50
0pri
orto
HP
filt
erin
g.A
*in
dic
ates
sign
ifica
ntl
ydiff
eren
tfr
omze
roat
.01
leve
l.
DL
oans
Loa
ns
Sta
ndar
ds
Spre
adP
rim
eD
eman
dS&
P50
0D
S&
P50
0C
har
ge-O
ffN
onP
erf
DL
oans
1L
oans
.27*
1Sta
ndar
ds
.02
.85*
1Spre
ad-.
14.7
7*.8
2*1
Pri
me
.31*
.20*
.03
-.19
1D
eman
d.3
8*-.
41*
-.51
*-.
49*
.11
1S&
P50
0.5
0*.1
3-.
20-.
21.2
8*.3
1*1
DS&
P50
0-.
36*
-.42
*-.
50*
-.35
*-.
02.1
2.2
5*1
Char
ge-O
ff-.
64*
-.23
-.00
-.24
-.60
*-.
44*
-.40
*0.
161
Non
Per
for
-.65
*-.
43*
-.23
.07
-.57
*-.
20-.
29*
0.20
0.81
*1
29