RSVP provides real-time and reliable services through the use of virtual circuits. It is a resource reservation setup protocol designed for the Integrated Services model [6, 7] and has a number of attributes that have led it to be adopted as an Internet standard approved by Internet Engineering Task Force (IETF). RSVP is not a routing protocol but a control protocol, which allows Internet real-time and reliable applications to reserve resources before they start transmitting data. When an application uses RSVP to request a specific QoS link for a data stream, RSVP selects a data path relying on the underlying routing protocols, and then reserves resources along the path according to the QoS. Since RSVP is receiver-oriented, each receiver is responsible for reserving resources to guarantee the QoS. Thus, the receiver sends an RESV message to reserve resources on all the nodes along the delivery path to the sender.

RSVP provides receiver-oriented setups of resource reservations for multicast or unicast data flows and adapts dynamically to changing group membership and routes. RSVP reserves resources for simplex flows, that is, it requests resources in only one direction. Two types of messages, PATH and RESV, are used in RSVP to set up resource reservation states on the nodes along the path between a sender and a receiver. Each PATH message sent by the source is associated with a specific data flow. When a PATH message traverse the path to the destination, it is intercepted by RSVP-enable IP routers on the path. The routers set up soft path states for the data flow. The path state includes the previous and next hops of the flow and its traffic characteristics. As the PATH message reaches the intended receiver, the receiver replies with an RESV message if it wants to make a reservation for the specific flow. The RESV message traverses the path back to the sender. If the required resources are available, a soft-state reservation is established in the router. Otherwise, an RESVErr message will be replied to the receiver.

With the growth of prevalent mobile wireless services, researches in wireless network have been increasing. Wang and Kuo [8] proposed an adaptive reservation mechanism for the next generation mobile communication systems. However, they do not apply it for heterogeneous wireless networks. Following this research, more QoS mechanisms for heterogeneous wireless networks have been proposed. Shenoy and Montalvo [9] proposed a global mobility management framework to support seamless roaming across heterogeneous wireless networks. Hasib and Fapojuwo [10] analyzed a radio resource management scheme for end-to-end QoS support in multi-service heterogeneous wireless networks. Al-Karaki and Kamal [11] proposed a virtual grid architecture protocol (VGAP) for heterogeneous mobile ad hoc networks. Although heterogeneity in QoS schemes had been investigated, RSVP was not taken into consideration.

Many researches have addressed the resource reservation in a mobile IP environment. Huang and Chen [12] proposed the RSVP extensions for Hierarchical Mobile IPv6 (HMIPv6) using multicast and new reservation mechanisms. When a mobile node enters the cell, the mobile proxy will inform the adjacent mobile proxies to join the multicast group. The mobile proxy where the mobile node may access in the future will receive PATH messages and make predictive reservations. Kuo and Ko [13] proposed the dynamic RSVP (DRSVP) with dynamically adjusted bandwidth resources in networks. In the scheme, the resource utilization can be improved by DRSVP because it provides different video resolutions to different receiver nodes with different needed reserved resources. Huang et al. [14] proposed a DRSVP-based handoff scheme (DBHS) to support soft handoffs. In the proposed DBHS, the DRSVP tunnel is established as soon as possible to reduce handoff latency. Then, an optimal DRSVP tunnel may be established after a handoff to shorten the transmission delay.

Moreover, some researches have focused RSVP issue in heterogeneous wireless networks. Lee et al. [15] proposed a heterogeneous RSVP extension mechanism which allows mobile hosts to reach the required QoS service continuity while roaming across UMTS and WLAN networks. The RSVP mobility extension could acquire the required end-to-end QoS grades to maintain the service continuity of a mobile host. Chen et al. [16] proposed a seamless handoff for QoS connections in an 802.16/WLAN environment. The proposed dynamic bandwidth management scheme is to treat the layer 2 connection of 802.16 as a pipe that aggregates multiple layer 3 RSVP connections with the same class of service. The proposed scheme demonstrated a quite good performance in managing resources for RSVP connections in the 802.16/WLAN environment. However, this scheme had not investigated the selection of optimal routing path in the networks. Benoubira et al. [17] proposed the mobility and QoS management in heterogeneous wireless networks. With a HMIPv6 based architecture, the UMTS users can have a seamless roaming between networks without registration to GGSN/HA. In order to guarantee the QoS in a heterogeneous environment, Benoubira et al. also implemented MRSVP to make a resource pre-reservation before a handover from the WiMAX to UMTS.

In heterogeneous WLAN/WiMAX networks, when a mobile station (MS) move away from a base station (BS) the signal level degrades and the MS needs to switch to another BS or access point (AP). The AP of the WLAN is attached to the subscriber station (SS) of the WiMAX. The MS is equipped with multiple wireless interfaces, including any combination of WLAN and WiMAX interfaces. When a user wants to access a given service or application, there may be various connectivity alternatives to select, and hence the main question is how to detect availability of multiple alternatives and select the most suitable one for a given type of service [18].

In order to manage the mobility of MSs and make the resource reservations for users, we propose an RSVP extension scheme for seamless handoffs. Figure 1 illustrates a handoff scenario for a heterogeneous WLAN/WiMAX network. In the system model, a gateway/QoS manager (GW/QM) mechanism is needed. GW/QM forwards the packets transmitted by the sender to an MS via a conventional reservation link. The arrow from the MS shows the direction it is moving in. SS/AP is the subscriber station of the WiMAX and the AP of the WLAN, respectively. No matter what the network is, all access the IP network through this gateway.

Figure 1.

A handoff scenario for a heterogeneous WLAN/WiMAX network.

(0.08MB).

In Figure 1, MS1 moves from the scope of SS1/AP1 to the scope of SS2/AP2, the related APs and gateways need to cooperate with MS1 to select a network for sustaining services. In the system model, a reserve status report mechanism and a QM have been added. There are QMs in the gateway of a site which intercepts all incoming packets and changes route from regional care-of-address (RCoA) to local care-of-address (LCoA) of MSs according to the mapping table. Then, the intermediate routers forward the packets to MSs via LCoA. By means of this mechanism, BSi or SSi/APi periodically broadcast the Reserve Requirement Vector (RSRV) messages to change and collect all the related information.

Before starting, some QoS parameters which will influence the determination policies are obtained by interacting with MS1. Other information needed includes: neighboring BSi or SSi/APi, characteristic parameters of link states such as residual bandwidth, round trip time, and resource RSRVs.

The proposed scheme includes a handoff decision process and a network selection process. The network selection is also called a pre-handoff. Besides, it needs a data structure RSRV, which is a multi-parameter vector defined as follows: RSRV={S, Ch, LPR}, where

• •

  S is the information about the received signal strength (RSS) of MS1 from BSi or SSi/APi. According to the value of S, the distance between them can be estimated to make a resource reservation decision.

• •

  Ch=(RB, DT) is the QoS resource parameter of a relay node to its neighboring nodes, where RB is the residual bandwidth and DT is the delay time from it to its neighboring nodes. By periodically broadcasting RSRV messages, BSi or SSi/APi exchange and collect all the related information to update their routing tables accordingly. CH can be taken as the measurement when establishing the resource reservation path.

• •

  LPR is the lost packet rate. A handoff will happen when LPRi>LPRth, where LPRth is a predefined threshold value for LPR. MS1 knows the status of the neighboring SSi/APi and BSi via the RSRV. MS1 then chooses either BSi or SSi/APi, the one which satisfies the requirements, and sends the notification information to set up the resource reservation path.

The resource reservation for MS1 is decided according to the RSS of MS1 from BSi or SSi/APi. As shown in Figure 2, the RSS is divided into two threshold values applied to decide how to tackle the situation. In Figure 2, the tracks of the MS1 are consistent with the changing RSS and network status.

Figure 2.

Changing of network status with different RSS thresholds.

(0.03MB).

Assume that MS1 moves from the WLAN to WiMAX network coverage area. If the RSS of MS1 from the WLAN is less than threshold S2, QM will make a pre-reservation for MS1. To allocate resources of the WiMAX, QM notifies the corresponding active BSi to make a pre-reservation for MS1. If the RSS drops below threshold S1, QM switches the data flow to an active reservation path for MS1. On the other hand, if the RSS from either the old SSi/APi or the new one is less than threshold S1, the corresponding link is released immediately.

Contrarily, assume that MS1 moves from the WiMAX to WLAN network coverage area. If the RSS of MS1 from the WLAN is higher than threshold S1, MS1 sends a notification message to QM to notify the corresponding active SSi/APi to make a pre-reservation for MS1. If the RSS is higher than threshold S2, QM switches the old reservation path to the new one by performing a seamless handoff and sends a message to request deleting the BSi reservation path. In a horizontal handoff, MS1 sends a notification message to QM to notify target BSi or SSi/APi to make a pre-reservation when it receives the RSS higher than threshold S1. On the other hand, if MS1 receives the RSS higher than threshold S2, QM switches the data flow to the active reservation path.

A handoff for an MS move from the WLAN to WLAN/WiMAX area, as shown in Figure 3, is described in detail as follows:

Figure 3.

A handoff for an MS move from the WLAN to WLAN/WiMAX area.

(0.1MB).

• 1.

  The RSS received by MS1 from BSi or SSi/APi is so weak that it is lower than signalth.

• 2.

  Ch=(RB, DT) is the QoS resource parameter, where RB and DT are employed as QoS metrics for feasible path computation. Initially, MS1 is in SS1/AP1. When MS1 moves to SS2/AP2, there are four paths to choose: P1={SS2/AP2, BS2, R2, GW/QM}, P2={SS2/AP2, BS2, R2, R1, GW/QM}, P3={BS2, R2, GW/QM}, and P4={BS2, R2, R1, GW/QM}. The QoS resource parameters of the four paths are shown as Table 1. In this scheme, the MS selects the path with maximum RB. If the conditions are the same, then MS selects the one with minimum DT. With the maximum RB and minimum DT, P4 is selected consequently.

  Table 1.

  The QoS resource parameters of the four paths.

  Path	CH of each node	RB (Mps)	DT (second)
  P1	{(3, 3), (5, 2), (2, 4)}	2	9
  P2	{(3, 3), (5, 2), (4, 2), (3, 1)}	3	8
  P3	{(5, 2), (2, 4)}	2	6
  P4	{(5, 2), (4, 2), (3, 1)}	3	5
• 3.

  A notification message is sent from MS1 to SS1/AP1 to notify GW/QM of the visiting location and mobile profile.

• 4.

  When receiving the notification message, SS1/AP1 forwards it to BS2 and subsequently BS2 forwards it to GW/QM along P4.

• 5.

  After receiving the notification message, GW/QM terminates the message.

• 6.

  A DSA-REQ message is sent from GW/QM to SS2/AP2 along P2.

• 7.

  When receiving the DSA-REQ message, SS2/AP2 forwards the PATH message to MS1. Besides, SS2/AP2 forwards the DSA-RSP message to GW/QM along P2 as well.

• 8.

  An RESV message is sent from MS1 to SS2/AP2.

• 9.

  Finally, the newly established path is SS2/AP2– BS2–R2–R1–GW/QM. Therefore, the RSVP tunnel from sender to MS1 is {GW/QM, R1, R2, BS2, SS2/AP2}.

The handoff decision process is illustrated as in Figure 4. The network selection is based on an RSRV message which denotes the reservation results and comes from neighboring SSi/APi or BSi. If a better network for the current MS1 is not available, the network selection or handoff will be rejected. In this situation, a new call admission will be blocked and the mobile handoff call will be dropped.

Figure 4.

Handoff decision process.

(0.08MB).