|
| VHO Decision Metric | VHO algorithm | Main aspects | Performance |
|
| RSS | Ayyappan and Dananjayan [7] | This technique considers both hard and soft MCHO version between WLAN and CDMA networks. The RSS parameter is monitored against unwanted power level fluctuations. | Throughput |
| | |
| Inzerilli and Vegni [8] | This approach is an MCHO technique between WLAN and CDMA networks. It focuses on the minimization of ping-pong effect by channel estimation techniques and waiting time parameter. | Throughput and handover frequency |
| | |
| Xie and Wu [9] | The algorithm makes handoff decisions after analyzing the signal strength fluctuation caused by slow fading through FFT. The method strongly reduces the number of handovers. It can be applied to both horizontal and vertical handovers. | Handover frequency and delay |
|
| SINR | Yang et al. [10] | This technique results in a QoS oriented VHO, since the SINR factor is strictly affecting the QoS level. | Throughput |
| | |
| Vegni et al. [11] | It is an MCHO technique between WLAN and CDMA networks. The goal is to limit the ping-pong effect by preventive vertical handovers. Since the SINR factor is combined with RSS parameter, the technique results in combined-metric based VHO approach for preventing unnecessary VHOs. | Throughput and handover frequency |
|
| QoS | Vegni et al. [12] | In this technique the QoS parameters are both subjective and objective. This approach is an MCHO and network-assisted VHO technique between WLAN and UMTS networks, in an IEEE 802.21 network architecture. | Seamless connectivity |
| | |
| Jesus et al. [13] | The handover technique is QoS-oriented and is based on context-aware information coming from both the network and the user. The handover decision is negotiated by both the MT and the network (i.e., UMTS and WLAN) in an IEEE 802.21* network architecture. | Maximum allowed number of active users |
|
| Speed | Vegni and Esposito [14] | This technique is a vehicle-controlled VHO, based on speed and handover delay. It addresses on VANETs. | Throughput and handover frequency |
| | |
| Esposito et al. [15] | This approach results in a vehicle-controlled VHO for improving QoS metrics. | Throughput, jitter, delay and handover frequency |
| | |
| Chen et al. [23] | This is a novel network mobility management protocol for VANETs, by exploiting traditional vehicle-to-vehicle communications. | Handoff delay and packet loss rate |
|
| Location | Wang et al. [16] | This technique is limited on a horizontal handover approach, for both hard and soft versions. The MT’s location is exploited for adaptive handovers. | Dropped calls and outage probability |
| | |
| Kibria et al. [24] | It is an MT controlled VHO technique, based on MT’s location information to predict handovers. | Hysteresis margins |
| | |
| Inzerilli et al. [18] | This method is driven by MT’s location in order to prevent vertical handovers between WLAN and UMTS networks. The limitation of ping-pong effect is acted by the use of the waiting time parameter. | Throughput and number of vertical handovers |
|
