fIgure 6.9 A network of time server

fIgure 6.9 A network of time servers used in NTP. The top-level devices (stratum 0) have the highest precision.

The stratum 1 computers act as time servers for the computers belonging to the next level (i.e., stratum 2). In general, stratum i computers act as time servers for the stratum (i + 1) computers. NTP synchronizes clocks on the Internet despite occasional loss of connectivity, failure of some of the time servers, and malicious timing inputs from untrusted sources. Figure 6.9 shows the hierarchy with three stratum 0 nodes.
A computer will try to synchronize its clock with several servers and accept the best results to set its time. Accordingly, the synchronization subnet is dynamic. The quality of a time service depends on several factors, like the stratum of the server, the round-trip delay, and the consistency of the network transit times. In a sense, NTP is a refinement of Cristian’s method. NTP provides time service using the following three mechanisms:
Multicasting: The time server periodically multicasts the current time to the client machines. All messages are delivered via UDP. This is the simplest method and perhaps the least accurate. The readings are not compensated for signal delays.
Procedure call: The client processes send requests to the time server, and the server responds by providing the current time. Using Cristian’s method, each client can compensate for the propagation delay by using an estimate of the round-trip delay. The resulting accuracy is better than that obtained using multicasting.
P2P communication: NTP allows a time server to synchronize its clock with another time server operating at the same stratum. The P2P mode is used by master servers at lower strata, and it enables them to provide a more accurate time service to the client computers. This leads to the highest accuracy compared to the previous two methods.
As an example of this mode, consider the exchange of a pair of messages between two time servers P and Q as shown Figure 6.10. Server P sends a probe at time T1, which is received by server Q at its local time T2. Server Q responds to this query at its local time T3, which is received by server P at its local time T4. Define the offset between two servers P and Q as the difference between their clock values. Let TPQ and TQP be the message propagation delays from P to Q and Q to P, respectively. Without loss of generality, assume that server Q’s time is ahead of server P’s time by an offset δ.