A. Synchronization FrameworkFig. 1

A. Synchronization Framework
Fig. 1 represents a synchronization framework using asynchronization server in a mobile business environment.
The whole framework consists of a server-side database, synchronization server (AnySyn) and multiple mobile
deviceswith internal mobile databases.

The server-side database maintains all of the data requiredfor business, and the mobile database downloads copies
ofdata the user needs from the server-side database. Thesynchronization server is located between the two databases
tosynchronize the data and manage additional informationrequired for synchronization. The AnySyn
synchronization server performs synchronization based on the SAMDalgorithm. The synchronization policy is
established in AnySyn, and the load caused by accessing the server-sidedatabase is minimized by operating a
connection pool. Everymobile device uses a separate toolkit to access the AnySyn server over a wired network to
perform synchronization.
B. Rows Inconsistency
An inconsistency refers to a state in which the publisheddata in the server-side database and the subscribed data
inthe mobile database carry different values due to a changeat either side. The two databases add, delete and
modifydata independently, which makes inconsistency inevitable.TABLE I displays every case for an inconsistency
for asingle row.Among the 16 cases indicated in TABLE I, Cases 6, 7, 8,10 and 14 include the ADD operation,
which cannot occurfor a single row. For example, in Case 7 the row added atthe server side is different from the row
modified at theclient; therefore, it cannot be considered an inconsistency.Case 7 is equivalent to Case 3 and Case 5

C. Message Digest
Message digest consists of a unidirectional hash functionthat maps a message of a random length to a fixedlength
hashvalue. Message digest h is created by the hash function H,which can be expressed as follows:h = H(M)M
is a message of a random length and H(M) is a fixedlengthmessage digest. Even a single bit changed in themessage
causes a change of message digest value [9]. Fig. 2demonstrates how this message digest mechanism can beapplied
to a relational database to examine data identitybetween rows of two tables.Data in two rows are identical if two
rows in Tables Aand B have identical message digest values. If the twovalues are different, it means that the two
rows have one ormore different column values. Accordingly, this method canbe useful in detecting inconsistency
between two rows.Once a row with an inconsistency is detected, the row iscopied using the primary key in the
direction ofsynchronization according to the synchronization policy.This synchronization algorithm identifies a
modified rowwithout relying on the database's internal functions, logs ormetadata to enable synchronization that is
independent ofthe database vender.

MOBILE DATABASE SYNCHRONIZZATION
In the literature, some schemes have been proposed for Mobile computing has become a reality thanks to the
convergence of two technologies: the appearance of powerful portable computers and the development of fast
reliable networks. In the mobile wireless computing environment of the future massive number of low powered
computer machines will query databases over the wireless communication channels. In , the author presents a novel
synchronization mechanism for multifield programmable gate array (multiFPGA) simulation accelerators with timemultiplexed
interconnection are presented. The proposed event-based synchronization mechanism reduces
synchronization time among multiple FPGAs. A mobile e-business client application may intentionally operate in