National and Regional Economic Growth with Fiscal Policies: Congested Public Goods and Endogenous Labor Supply of a Small-Open Economy

doi:10.4236/me.2010.13020

Modern Economy, 2010, 1, 171-179

doi:10.4236/me.2010.13020 Published Online November 2010 (http://www.SciRP.org/journal/me)

National a n d R egional Eco nomic Growth with Fisca l

Policies: Congested Public Goods and Endogenous Labor

Supply of a Small-Open Economy

Wei-Bin Zhang

Ritsumeikan Asia Pacific University, 1-1 Jumonjibaru, Beppu-shi, Oita-ken, Japan

E-mail: wbz1@apu.ac.jp

Received August 12, 2010; revised September 16, 2010; accepted Sept em b er 20, 2010

Abstract

The purpose of this study is to build a two-regional growth model with capital accumulation, endogenous

time distribution between leisure and labor, and regional public goods with fiscal policies. We emphasize

dynamic interactions among capital accumulation, externalities, supply of public good with different fiscal

policies, congestion of public good, endogenous time, and economic geography. The economy consists of

two regions and each region consists of the industrial sector and public sector. First, we develop the

two-region growth model with public goods and fiscal policies. Second, we show how to find equilibrium

values of the dynamic system. Then, we simulate model with specified parameter values. Finally, we carry

out comparative statics analysis with regard to parameter changes in tax rates and congestion. Our compara-

tive statics analysis provides so me important insights. For instance, a main difference between the effects of

increasing the two regions’ tax rates on the output is that as region 1’s (2’s) tax rate on the industrial sector is

increased, the national industrial output, national capital employed by the economy, and the national wealth

are increased (reduced).

Keywords: Small-Open Economy, Interregional Economy, Capital Accumulation, Endogenous Leisure and

Work Time, Fiscal Policies, Public Goods

1. Introduction

Interactions between economic growth, public good sup-

ply and environmental changes have caused a great at-

tention from economists. Nevertheless, it is argued that a

few theoretical models have been proposed to deal with

these interactions within a interregional framework. As

argued by [1,2], a main obstacle to properly modeling

regional economic dynamics is that the traditional ap-

proaches to consumer behavior over time makes it ana-

lytically intractable to model interregional grow th on the

basis of profit- and utility-maximization. The productiv-

ity advantages of one region may be offset to some ex-

tent by the higher wages that must be paid in a system

where people are free to choose where they work and

live. Higher wages are often associated with some kinds

of disamenities (such as noise, pollutants, and densely

populated neighborhood) and high living costs. Labor

and capital are easily mobile between regions in indus-

trialized economies. As capital mobility becomes high

and costs associated with capital movement among re-

gions become low, it is reasonable to assume that capital

movement tends to equalize marginal productivities of

capital among regions within a national economy. But

there are different principles for analyzing temporary

equilibrium conditions for labor movement in a dynamic

regional framework. In this study, we determine popula-

tion distribution by the condition of equalizing utility

level. This paper is a generalization of the two-region

growth model proposed by Zhang [3]. This paper gener-

alizes the previous model in introducing different fiscal

policies and endogenous time distribution between lei-

sure and work into the regional dynamic model. We also

take account of congestion into consideration. This paper

is organized as follows. Section 2 defines the two-region

model with capital accumulation, endogenous time dis-

tribution, and public goods. Section 3 shows how to de-

termine equilibrium of variables. Section 4 examines

effects of changes in some parameters upon long-term

national economic growth and economic geography.

172 W. B. ZHANG

Section 5 concludes the study.

2. The 2-Region Trade Model with Capital

Accumulation

This paper builds a dynamic one-commodity and

two-region trade model to examine interdependence be-

tween regional trades and national growth with regional

public goods and congestion. We analyze trade issues

within the framework of a simple international macro-

economic growth model with perfect capital mobility.

This model is influenced by the neoclassical trade theory

with capital accumulation. Many one-commodity trade

models with capital accumulation have been proposed,

for instance, by [4-10]. It is assumed that the regions

produce a homogenous commodity and public goods. It

is assumed that there is only one (durable) good in the

national economy under consideration. Households own

assets of the economy and distribute their incomes to

consume and save. Industrial sectors or firms use capital

and labor. Exchanges take place in perfectly competitive

markets. Industrial sectors sell their product to house-

holds or to other sectors and households sell their labor

and assets to industrial sectors. Factor markets work well;

factors are inelastically supplied and the available factors

are fully utilized at every moment. Saving is undertaken

only by households, which implies that all earnings of

firms are distributed in the form of payments to factors

of production. We omit the possibility of hoarding of

output in the form of non-productive inventories held by

households. All savings volunteered by households are

absorbed by firms. We require saving and investment to

be equal at any point of time.

The system consists of two regions, indexed by

Each region has industrial and public sectors,

indexed by i and respectively. Perfect competi-

tion is assumed to prevail in good markets both within

each region and between the regions, and commodity is

traded without any barriers such as transport costs or

tariffs. The labor markets are perfectly competitive

within each region and between the regions. Let prices

be measured in terms of the commodity and the price of

the commodity be unity. We denote wage and interest

rates by and respectively, in the th

region. The interest rate is equal throughout the national

economy, i.e., j where is the rate of in-

terest fixed in the international economy. We assume a

homogenous population,

1, 2.j,p

(

j

*

r

()

j

wt ),rt

,

j

()rt *

r

,N in the economy. A person

is free to choose his residential location within the coun-

try. We assume that any person chooses the same region

where he works and lives. Each region has fixed land.

Land quality, climates, and environment are homogenous

within each region, but they may vary among the regions.

We neglect transportation cost of commodities between

and within regions. As amenity and land are immobile,

wage rates and land rent may vary between the regions.

Let





j

Nt and





j

Nt stand for respectively the

population and (qualified) labor force of region We

introduce ,

ij

.j



,

rj



and wj



to stand for, respectively,

the fixed tax rates on the industrial output, interest in-

come and wage income in region Let

.j( )

mj

K

t

and mj

(),

mj

Nt ( )

F

t

,.mip

stand for the capital stocks, (quali-

fied) labor force employed by, and output level of region

’s sector

j.m



2.1. Behavior of Producers

We assume that each firm chooses two productive fac-

tors, capital, j( ),

K

t and labor, j at each point

of time to maximize its profit, with the level of public

goods in the region as given. The production functions

are given by



,Nt







 

1,

ii

j ij

i

tN









,

1,

t

j,0,

j



2

ij i

i

tK





ii

Ft



(1)

where





jt



is a function of externalities, public ser-

vice and congestion. We specify as follows



jt



 



,,

ij

A,

c

p

Kt



 ,

e



0

c

p

j

F



e

pjij

Kt



pj

ij

Kt

ji

tA











where



p

pj

F

t



measures the effect of public service on

the region’s productivity,



e

ij

K

t



the effect of external-

ities, and

 





/c

pj ij

K

tKt



the effect of congestion of

public goods. Similar to [11], we interpret that when

ec

0,





 there is no congestion and no externality.

The nonrival and nonexcludable public service is avail-

able equally to each agent, independent of the usage of

others. Obviously this is a limited case as most of public

services are subject to some degree of congestion. We

take account of congestion effects by the term,

 





c

t



r

/K,

*,

pj ij implying that for a fixed level of

public capital, a rise in the private capital tends to reduce

the efficiency of public services. There are different

ways of describing congestion (see [12]). Here we ne-

glect possible congestion effects due to the region’s

population and consumption activities.

Kt

Markets are competitive; thus labor and capital earn

their marginal products, and firms earn zero profits. The

rate of interest, and wage rates, are de-

termined by markets. Hence, for any individual firm

and



,wt

j*

r





t

j are given at each point of time. According

to the neoclassical growth theory as in the Solow model

[1], the marginal conditions are given by

w

*,

iij ijiij ij

kj

ij ij

F

rw

KN

 



 (2)

W. B. ZHANG

173

where k



is the depreciation rate of ph ysical cap ital and

1.

ij ij





2.2. Behavior of Consumers

Each worker may get income from land ownership,

wealth ownership and wages. In order to define incomes,

it is necessary to determine land ownership structure. It

can be seen that land properties may be distributed in

multiple ways under various institutions. This study as-

sumes the absentee land ownership. Land is owned by

absentee landlords who spend their land incomes outside

the economic system. This study uses the approach to

consumers’ behavior proposed by Zhang in the early

1990s [see, 1,2]. Let



j

kt stand for the per capita

wealth in region Let h stand for the level of hu-

man capital and the work time in region

Each consumer of region obtains income

.j

j

T



t.j

j

 





*,1,

jrjjwjjj

ytrkthTtwtj



 2 (3)

from the interest payment, *,

rj j

rk



and the wage

payment, ,

wjj j

hTw



where 1

rj rj



 and

1

wjwj .



 The disposable income is given by

 

ˆ.

jjj

ytyt kt At each point of time, a con-

sumer distributes the total available budget among hous-

ing, saving,



,

j

lt ( ),

j

s

t consumption of goods,

The budget constraint is given by ()

j

ct

.

*

ˆ

j

jjjjrjjwjjj

Rlc syrkhTw k





j

where is land rent in region Let 0 stand

for the (fixed) available time for work and leisure. The

time constraint is expressed by .

( )

j

Rt .j

T

0

T

 

Tt t

jhj

Substituting this function into the budget constraint

yields

*0

j

jwjhjjjj

rj jwjjj

RlhT wcsy

rkhTwk







 

j



(4)

We assume that utility level that the consumers obtain

is dependent on the lot size, the leisure time,



,

j

lt





,

hj

Tt the consumption level of commodity,





,

j

ct

and the saving,



.

j

s

t



,

j

Ut

v

The utility level of the consumer

in region is specified as follows

,j

  

,

,,,, 0

hhhhh

jj

pjjhjjj

hhhhh

UttFltTtc ts t

v













(5)

in which

,

h

v,

hh

,





and h



are a typical person’s

elasticity of utility with regard to lot size, commodity

and savings in region We call

.j,

hh

,





and h



propensities to consume lot size, to consume goods, and

to hold wealth (save), respectively. We assume that

households would like to have more public goods with

the other things fixed, that is, In (5),

0.

h

v





jt



is

called region ’s amenity level. In this study, we spec-

ify j

j



by









,

b

jjj

tNt



 where (0)

j



 and

are parameters. We don’t specify the sign of as the

population may have either positive or negative effects

on regional attractiveness.

b

Maximizing





j

Ut subject to the budget constraints

(4) yields











 





  

,,

,

jjj wjhjjj

jj

Rt ythTtwtt

yt styt







jj

lt

ct

y



(6)

in which

,,,,

h

1

hhh

hhhh

















According to the definitions of



,

j

s

t the wealth

accumulation of the representative person in region

is given by j

 

jjj

kt stkt

 (7)

As households are assumed to be freely mobile be-

tween the regions, the utility level of people should be

equal, irrespective of in which region they live, i.e.,









.Ut

1

Ut2

The public sector maximizes the level

of public services by choosing capital,





,

pj

K

t labor

force,





,

pj

Nt

as follows



pj

Ft

 

00 00

,,,

pp

pj pjpjpppj

AK tN tA



0



 (8)

Let





pj

Yt stand for government ’s tax income.

Then we have j











 





*

pjijijrjj jwjj j

tNYF trktNtwt

 

 t(9)

where ,

ij ij

F



*

rjjj

rkN



and wj jj

wN



are respectively

the tax incomes from the production sector’s output, the

households’ interest payments and the households’ wage

incomes.

The public sector in region is faced with the fol-

lowing budget constraint j















*()

jpjk pjpj

wtNtrK tY



 



t

(10)

Maximization of public services under the budget con-

straint yields





*,

kpjppjjpj

rKYwN



 

ppj

Y



(11)

in which

00

0000

,

pp

p

pp



p









The total capital stock employed by the economy,

(),

K

t is equal to the total capitals employed by all the

regions. That is

W. B. ZHANG

174

2

1

 





2

1

ij pjj

jj

K

tKtKtK







t



(12)

where

 





.

jij pj

K

tKtKt The assumption that

labor force and land are fully employed is represented by

 

2

1,,

jjjj

j

NtNltNtL j





1,2 (13)

where

j

L is the given (residential) area of region

We also have

.j

 





ijpjjj j

NtN tNthTtNt (14)

The total wealth of the national economy is the sum of

the wealth owned by all the households

 

2

1jj

j

K

tktN



t (15)

We introduce as the value of the economy’s

net foreign assets at The income from the net foreign

assets,



Bt

.t





,Et which may be either positive, zero, or

negative, is equal to According to the defini-

tions of the national wealth, the capital stocks employed

by the economy and the net foreign assets, we have



*.rBt

 

.

K

tKt



0,



Bt



0,

Bt

0,

A country’s current balance at

time is the change in the value of its net claims over

the rest of the world – the change in its net foreign assets.

If the economy as a whole is lending (in this

case we say that the current account balance is in sur-

plus); if the economy as a whole is borrow-

ing (the current account balance is in deficit); and if

the economy as a whole is neither borr owing

nor lending (the current account balance is in balance).

We have thus built the model with endogenous capital

accumulation and regional capital and labor distribution.

We now examine spatial equilibrium and effects of

changes in different conditions upon the economic geog-

raphy.

t

Bt







Bt





3. Economic Equilibrium

As it is difficult to conduct dynamic analysis, we are

only concerned with steady states. In equilibrium the

change rates of all the variables are equal to zero. By (7),

we have

j

s

k at steady state. From this equation and

,

j

s

y



 we have /.

jj

yk



 From (2) and (11), we

solve //,

p

jij pjij

K

KNN



where /.

p

iip











From this equation,

j

ij pj

NNN and jij

KK





,

p

j

K

we solve

,,

,

11

jj

ijpj j

j

jj

ij pj

jj

Nk

NN

kk

KkK

KK

kk













j

N







.



(16)

where /

j

pj ij

kKK

 From the definition of





,

jt

(8) and (16), we can express the production functions as

follows



1

jj j j

ij

jj

Ak KN

Fkk

















(17)

where

1

101 101 10

10

,,

,pi

p

p cppi epp

ippjijpj

AAA





 

 

 

 

From (1), (16) and (17), we have





1

*

1

*

,

1

iij jjjj

k

j

kjij

j

ij j

Ak KN

rkk

rk

wNk

 

j

K











 

















(18)

From the marginal conditions for capital in (18), we

have 2,

K1

K



where



1/ 1

111 122

1

222 21

1.

1

i

K

i

Ak Nkk

k

Ak Nk































 





From the definition of

j

y and /,

jj

yk



 we get

,

j

jj

wk



where





*0

1/ 1/.

jrjwj

From rhT





j

jj

w



k and the marginal conditions in labor market

in (18), we get



1

iijjjjj

j

jj j

Ak KN

kkk







 













(19)

From

j

jj

NhTN in (14) and we

have 0,

jhj

TT T





0

/

j

jh

NNhTT

j

. From /,

hjjj wj

Tywh







/

jj

yk



 and ,

j

jj

wk



 we get

hj j

j

wj

Ta h



 





We thus determined the time distribution. Inserting

/.

hjj wj

Th



 



in



0

/

jj hj

NNhTT



, we have

,

j

jj

NaN where



0

1// .

j

jwj

ahT



 Insert

/

j

jj

lLaN

j



, /,

jj

ck





 and

j

s

k in the util-

ity function

0

00

00 1

1

hhhhh

hph

h

hp hp

hphp hh

vb

bv

pjj jjj

jj

vv

vv j

jj

AL aa

UN

K

kk

 





















 

 



 





(20)

From (19), (20) and 1

UU

2



, we have 21N

NN



,

W. B. ZHANG

175

where



000 0

000 00

1/1

2

12

1

/1

1

2

ˆ

,

hp hp

hphp hp

vv

N

vvv

k

kk k

k











 





























00

0

/1

11111222

11

222 2 21

0

0000

ˆ,

,

1

1/1

hp

hhhh

v

vb

pi

vb

i

p

hh

hp hhp

ALaa A

A

ALaa

bv v





 











 





















 



From 12

NNN,

j

jj

, and NaNN

21N

N



,

we solve

12

12 12

,N

N

NN

aa aa





 

(21)

We see that the labor distribution is uniquely deter-

mined as functions of 1 and From the definition

of k

2.k



K

 and (21), we have

 



1/ 1

111 22

12

1

222 1

1

,1

i

K

iN

Ak kk

kk k

Ak k

































 







From 21K

K

K and 12 ,

K

KK



 we have

12

,

11

K

KK





 (22)

We see that the capital distribution is uniquely deter-

mined as functions of and

1

From (11) and (1 6), we have

k

2.k





*

1.

pj

j

pj

kj

k

K

Y

rk











 (23)

From the definition of we have

,

pj

Y



*

ij j

p

jjrj

iij j

Yar

k

 

 













wjjjj

kN





(24)

where we use /,

ijjiji ij

FwN





 ,

j

jj

wk





,

j

jj

NaN and the equation for ij in (16). From

the marginal conditions for labor markets in (18) and

N

,

j

jj

wk



 we obtain



*

1

kji

j

ij jj

rk

kNk

 

 







j

K

(25)

Substituting this equation and (23) and (25) into (24)

yields

1

**

ij jj

jjrjwj jj rjwj j

iij p

kar ar

 

 

 

















(26)

The above equations determine the equilibrium values

of .

j

k

 The following lemma describes a procedure to

determine the equilibrium values of all the variables.

Lemma 1

For a given rate of interest in the global market, the na-

tional economy has a unique equilibrium point. The

equilibrium values of all the variables are given by the

following procedure:

j

k

 (26) →

j

N by (21) →

and ij

N

p

j

N by (16) →

j

jj

→ hj j

NaNTa



 →

0hj j

TTT



 →

j

K

by the marginal conditions for

capital in (18) → 21

K

KK



 →

j

w by (18) →

ij

K

and

p

j

K

by (16) →

j

k by (25) →

p

j by (24)

→ Y

ij

F

by (17) →

p

j

F

by (8) →

j

y by (4) →

/

j

lL j

N→

K

by (15) → BKK →

/

j

jj

ylR





→

j

c and

j

s

by (6) →

j

jj

NCc

and

j

jj

SsN →

j

U by (5).

Lemma 1 shows how to determine the values of all the

variables in equilibrium. As the expressions are compli-

cated, it is difficult to explicitly interpret the eq uilibrium

conditions. For illustration, we specify the parameter

values as follows

*00

12

12 12

12

11 12 22

0.05, 1,0.3,0.3,0.4,

0.05,0.04, 0.03,1.2,1,

1.1,1,0.1, 3,4,

0.09,0.3,0.05,0.05,0.09,

0.8, 10,3,4,

0.04,0.03.

ipp

cpeii

pp

hhhkh

h

irwirw

rh

AA

AAb

v

NLL

 





 



 













 



(27)

The rate of interest is fixed at 5 percent in interna-

tional market. The total population is 10 with human

capital level being unit. The produ ctivity para meter, 1i

A

,

is higher than region 2, the produ ctivity parameter of the

public sector in region 1 is higher than that in region 2.

We consider that region 1 is technologically more ad-

vanced than region 2. Region 1’ and 2’ amenity parame-

ters, 1



and 2,



are different, the value in region 1

being lower than region 2. Region 1’s land for housing is

less than Region 2’ land. The marginal propensity to

consume public goods is lower than the propensity

to consume the industrial goods,

,

h

v,

h



and th e propen sity

to consume the lot size, .

h



The tax rates on the output

level, the income from wealth and wage income are the

same within each region and the tax rates in region 1 are

higher than the tax rates region 2. The externality and

congestion parameters, e



and ,

c



are positive. It

176 W. B. ZHANG

should be remarked that although the specified values are

not based on empirical observations, the choice does not

seem to be unrealistic. For instance, some empirical

studies on the US economy demonstrate that the value of

the parameter, ,



in the Cobb-Douglas production is

approximately equal to 0.3 (for instance, [13]). With re-

gard to the technological parameters, what are important

in our interregional study are their relative values. The

presumed productivity differences between the regions

are not very large. This similarly holds for the specified

differences in the amenity parameters between the re-

gions.

Following the procedure in Lemma 1, we calculate the

equilibrium values of all the variables. We list the simu-

lation results as follo ws

12

4.64,14.79, 18.09,3.30,

2.07,1.55,

FK K B

kk

 



121

1.581.62 8.46

1.49 ,1.55 ,7.59,

0.100.07 0.86

ii i

pp p

NNK

  

 

  

 



  

 

  

 

  

1

22

2

21

1

22

2

4.93 2.64

6.34 5.07 2.01

5.88 ,,,

0.68 0.41

0.49 0.68 0.29

i

ip

h

pp

h

F

N

KF

N

KF

T

KF

T



 



 



 



 



 

 



 



 



 



 



  

 

 













111

222

111

222

0.531.19 0.23

0.400.88 0.17

,,

0.040.38 0.61

0.020.22 0.80

i

p

fwc

yRl

  

 

  

 

  

 



  

 

  

 



 

 



(28)

In (28), the variables, ij

f

and

p

j, are respectively

the output level per worker and th e exp end iture on pub lic

goods per resident in region defined as

y

j

/,

ijij ij

f

FN /,

p

jpjj

y

YN Less than half

of the national population but more than half of the total

capital are located in region 1. The per-capita levels of

wealth and consumption and wage rate in region 1 are

much higher than the corresponding variables in regions

2. The lot size of region 2 is larger than in region 1. The

consumption level per capita in region 1 is higher than in

region 2. We see that although workers can earn more

money in the advanced region than in the other region,

they have to pay much higher rent for housing than the

households in the other region. Expectably, the typical

household in the advanced region consumes more goods

and lives in a smaller house than the typical household in

region 2.

1,2 .j

4. Parameter Changes and Economic

Geography

It is important to ask questions such as how one region

may affect the national economy as its technology or

amenity is improved; or how the regional trade patterns

may be affected as the propensity or the total population

to save is increased. This section examines impact of

changes in some parameters on the national economy

and regional economic structures. As we have explicitly

provided the procedure to simulate the motion, it is

straightforward to make comparative analysis. First, we

examine effects of change in the total productivity of

region 2’s industrial sector, 2.

i

A

We increase 2i

A

from 1 to 1.1, keeping all the other parameter values as

specified in (27). The simulation results are given in

(29).

2:1 1.1,6.12,5.99,6.19,

i

AFKK

12

7.05,0.67,16.29,Bk k 

12

7.29 7.10

7.29 ,7.10 ,

7.29 7.10

ii

pp

NN

 

 

 

 

 1

1

i

p

K



 

 

 

 

 

 

 

1

22

21

22

7.29

7.91 24.557.10

7.91 ,24.55,,

0

7.91 24.550

i

h

p

h

N

KN

KT











 







 



 



 





 



 



 

 





11

22

11

22

7.91 0.67

24.55 16.29

,,

5.35 0.67

9.78 16.29

ii

pp

Ff

Fy

 







 





 





 







 



 





 







11

22

11

22

0.67 0.67

16.29 16.29

,

7.91 7.87

24.55 6.63

wc

Rl



 



 

 



 

 



 

 





 





 



(29)

where



stands for the change rate of the variable in

percentage due to changes in parameter value. As region

2’s total productivity is increased, the national output,

wealth and capital are increased. The trade balance is

also improved. Hence, the national economy is improved

as a whole. However, there are interregional differences

in the impact due to the technological ch ange. The region

whose technology is improved attracts more households

to the region. Region 2’s rate is increased and the region

becomes more attractive. People immigrate to region 2

from region 1. The redistribution leads to fall in region

W. B. ZHANG

177

1’s land rent and rise a region 2’s land rent. The region

experiencing the technological change will increase its

wage rate, while the wage rate in the other region falls.

As the work time is not affected by the technological

change, the changes in the national labor supply are due

to regional reallocation of the households. As region 2

has more population, its lot size per household faces. We

thus see that as region 2 increases its technology, at a

new equilibrium its household will get more wage per

work hour and increase the consumption and wealth, but

the household will live in a smaller space.

In our dynamic system each region may conduct dif-

ferent fiscal policies. It is important to compare effects of

change in different taxes upon the economic system.

First, we increase the tax rate on region 1’s output from

0.04 to 0.05. The national output and wealth are in-

creased. The capital stock employed by the country is

increased. The trade balance is deteriorated. As region

1’s tax rate is increased, the expenditure on public good

is increased (given all the other conditions). The im-

proved infrastructure makes the region more attractive.

The region’s population is increased and produ ctivity per

work hour is increased. Region 1’s wage rate and con-

sumption are increased in association of rise in land rent;

region 2’s wage rate and consumption are reduced in

association of fall in land rent.

1

12

:0.040.05,0.23, 0.46, 0.12,

1.41, 0.10,0.05,

iFK K

Bkk







12

0.60 0.58

0.26 ,0.58,

13.89 0.55

ii

pp

NN

  



 

  

 



  

 

  



 

  

1

i

p

K



1

22

21

22

0.60

1.280.63 0.58

0.17,0.63,,

0

14.000.63 0

i

h

p

h

N

KN

KT









 









 



 



 





 







 

 





11

22

11

22

0.88 0.28

0.63 0.05

,,

9.56 13.32

0.42 0.05

ii

pp

Ff

Fy

 



 

 

 





 

 



 

 



 

 

 





 

 







11

22

11

22

0.10 0.10

0.050.05

,

0.70 0.60

0.63 0.59

wc

Rl

 



 

 

 





 

 



 

 





 

 

 





 

 







(30)

We now increase the tax rate on region 1’s wage from

0.04 to 0.05. Different from the increase in the tax rate

on output, the national output and the capital stock em-

ployed by the country are reduced. The trade balance is

improved and wealth is increased. As region 1’s tax rate

on the wage rate is increased, the expenditure on public

good is increased and work time is reduced (g iven all the

other conditions). The improved infrastructure makes the

region more attractive. Although the population of region

1 is increased, its labor force

The region’s population is increased and productivity

per work hour is increased. Region 1’s wage rate and

consumption are increased in association of rise in land

rent; region 2’s wage rate and consumption are reduced

in association of fall in land rent. As the tax rate on wage

is increased, the national supply of labor is reduced. Al-

though more peop le immigrate to more productive r egion,

the national output is still reduced. Because the output

and wage are reduced in region 2, the regional public

service and per capita expenditure on public good are

reduced.

1

12

: 0.040.05,0.75,0.16,

0.89,5.60,1.16,0.18,

wFK

KBkk







12

121

0.20 2.02

0.80 ,2.02 ,

9.07 2.02

ii

pp

NN

  

  

 

  

 1

1i

p

K



 

  

 

  



 

  



1

22

21

22

2.08

1.372.20 2.02

0.35,2.20,,

1.05

10.33 2.20 0

i

h

p

h

N

KN

KT























 



















 





11

22

11

22

0.35 1.69

2.20 0.18

,,

6.63 8.09

1,47 0.18

ii

pp

Ff

Fy

 





 

 

 





 

 



 

 



 

 

 





 

 







11

22

11

22

1.16 0.80

0.18 0.18

,

2.89 2.04

2.20 2.07

wc

Rl

 



 

 





 

 



 

 





 





 



(31)

We now study the impact of ch anges in the cong estion

parameter, c



． We increase the parameter value from

0.05 to 0.06. The effects are listed in (32). The time dis-

tribution is not affected. As the congestion effect of pub-

lic goods becomes stronger, most of the economic vari-

ables are negatively affected. It should be noted that al-

though region 1’s population is increased, the region’s

total capital and output are reduced. The economic loss

caused by the strengthened congestion dominates the

economic gain brought about by the labor increase.

178 W. B. ZHANG

12

: 0.050.06,3.41,3.40,

3.41, 3.43,3.23,3.71,

cFK

Bk k





  

K

12

0.23 0.22

0.23 ,0.22 ,

0.23 0.22

ii

pp

NN

 



 

 

 



 

 

 



 

 

1

i

p

K







1

22

21

22

0.23

3.013.92 0.22

3.01 ,3.92,,

0

3.01 3.920

i

h

p

h

N

KN

KT









 









 







 





 







 

 





11

22

11

22

3.01 3.23

3.92 3.71

,

0.823.3

1.28 3.71

ii

pp

Ff

Fy

 





 

 

 





 

 



 

 





 

 

 





 

 

,











11

22

11

22

3.23 3.23

3.71 3.71

,

3.01 0.23

3.92 0.22

wc

Rl



 



 

 

 





 

 



 

 





 

 

 





 

 







(32)

We increase the externality parameter value, ,

e



from 0.03 to 0.04. The effects are listed in (33). As posi-

tive externalities become stronger, the industrial output,

total capital employed by the economy, and the total

wealth are increased. Region 1’s population is increased.

As region 2 loses labor and the time distribution is not

affected, the region’s output and capital stocks are re-

duced. Although region 1’s output is increased, as its

change rate is low, the net effect on the national indus-

trial good falls. Also the labor of each sector in region 1

is increased. The wage rate, consumption level and

wealth per capita in the two regions are all reduced. The

lot size in region 1 is reduced and the region’s housing

rent is increased.

12

: 0.030.04,0.52,0.51,

0.52, 0.57, 0.18,1.14,

e

F

K

Bk k





 

K

12

0.50 0.49

0.50 ,0.49 ,

0.50 0.49

ii

pp

NN

 





 



 

 



 





 

1

i

p

K







1

22

21

22

0.50

0.331.62 0.49

0.33 ,1.62 ,,

0

0.33 1.620

i

h

p

h

N

KN

KT









 









 



 



 





 







 

 





11

22

11

22

0.33 0.18

1.62 1.14

,,

0.30 0.18

0.68 1.14

ii

pp

Ff

Fy

 





 

 





 



 





 





 

11

22

11

22

0.180.18

1.141.14

,

0.33 0.50

1.62 0.49

wc

Rl



 



 

 

 





 

 



 

 





 

 

 





 

 







(33)

5. Conclusions

This paper proposed a two-region growth model with

capital accumulation, amenity and regional public goods

under assumptions of profit maximization, utility maxi-

mization, and perfect competition. We emphasize effects

of congestion and various fiscal policies on long-term

economic growth and economic geography. As the

model is structurally general, it is possible to deal with

various national as well as regional issues. Given the

contemporary literature on (spaceless) economic growth,

we may extend and generalize the model in different

ways. We may analyze behavior of the model with other

forms of production or utility functions. Other important

extensions in clude incorpor ating transportatio n costs and

endogenous population growth into the model. We may

also refine our model by dividing public expenditures on

capital into maintenance and new investment. As em-

pirically demonstrated in [14,15], maintenance expendi-

tures on public capital can account to 2 to 3 percent of

GDP in some economies like USA and Canada. As in

[16] in which the composition of public capital expendi-

tures under congestion is an important factor for optimal

fiscal policies, we may consider possible effects of pub-

lic maintenance expenditures on the depreciation of pub-

lic capital.

6. Acknowledgements

The author is grateful to an anonymous referee for the

constructive comments. Financial support under “the

Grant-in-Aid for Scientific Research (C), Project No.:

21530246, Japan Society for the Promotion of Science”

and “APU Academic Research Subsidy”, is gratefully

acknowledged. The usual disclaimer applies.

7. References

[1] W. B. Zhang, “Economic Growth Theory. Hampshire:

Ashgate,” 2005.

W. B. ZHANG

179

[2] W. B. Zhang, “International Trade Theory: Capital,

Knowledge, Economic Structure, Money and Prices over

Time and Space,” Springer, Berlin, 2008.

[3] W. B. Zhang, “A Multi-Region Model with Capital Ac-

cumulation and Endogenous Amenities,” Environment

and Planning A, Vol. 39, No. 9, 2007, pp. 2248-2270.

[4] H. Oniki and H. Uzawa, “Patterns of Trade and Invest-

ment in a Dynamic Model of International Trade,” Re-

view of Economic Studies, Vol. 32, 1965, pp. 15-38.

[5] A. V. Deardorff, “The Gains from Trade in and out of

Steady State Growth,” Oxford Economic Papers, Vol. 25,

No. 2, 1973, pp. 173-191.

[6] R. J. Ruffin, “Growth and the Long-Run Theory of Inter-

national Capital Movements,” American Economic Re-

view, Vol. 69, No. 5, 1979, pp. 832-842.

[7] R. Findlay, “Growth and Development in Trade Models,”

In: R. W. Jones and R. B. Kenen, Eds., Handbook of In-

ternational Economics, Amsterdam, North-Holland,

1984.

[8] J. Eaton, “A Dynamic Specific-Factors Model of Interna-

tional Trade,” Review of Economic Studies, Vol. 54, No.

2, 1987, pp. 325-338.

[9] R. A. Brecher, Z. Q. Chen and E. U. Choudhri, “Absolute

and Comparative Advantage, Reconsidered: the Pattern

of International Trade with Optimal Saving,” Review of

International Economics, Vol. 10, No. 4, 2002, pp. 645-

656.

[10] G. Sorger, “On the Multi-Country Version of the So-

low-Swan Model,” The Japanese Economic Review, Vol.

54, No. 2, 2002, pp. 146-164.

[11] T. Eicher and S. Turnovsky, “Scale, Congestion and

Growth,” Economica, Vol. 67, No. 267, 2000, pp. 325-

346.

[12] M. A. Gómez, “Fiscal Policy, Congestion, and Endoge-

nous Growth,” Journal of Public Economic Theory, Vol.

10, No. 4, 2008, pp. 595-622.

[13] A. B. Abel and B. S. Bernanke, “Macroeconomics,” 3rd

Edition, Addison-Wesley, New York, 1998.

[14] E. McGrattan and J. Schmitz, “Maintenance and Repair:

Too Big to Ignore,” Federal Reserve Bank of Minneapo-

lis Quarterly Review, Vol. 23, No. 4, 1999, pp. 2-13.

[15] P. Kalaitzidakis and S. Kalyvitis, “Financing ‘New’ Pub-

lic Investment and/or Maintenance in Public Capital for

Growth? The Canadian Experience,” Economic Inquiry,

Vol. 43, 2005, pp. 586-600.

[16] E. V. Dioikitopoulos and S. Kalyvitis, “Public capital

Maintenance and Congestion: Long-Run Growth and

Fiscal Policies,” Journal of Economic Dynamics & Con-

trol, Vol. 32, No. 12, 2008, pp. 3760-3779.

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