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In this chapter, we introduced a collision model of a DS-CDMA network using random spreading sequences, where a collision is said to occur if there is no proper power control scheme for achieving a desired SINR at receivers. We derived and simulated the collision probabilities, assuming matched filter receivers.

A queueing analysis with the saturated slotted ALOHA model was conducted to study the MAC-layer throughput performance for systems equipped with enhanced packet reception capabilities, an example being the proposed collision model. Under a general physical reception model, the stability region for saturated slotted ALOHA for two transmitter—receiver pairs is explicitly characterized. Then we discussed throughput under a symmetric multipacket reception model, as a special case of the general reception model, and under the proposed collision model, as a special case of the symmetric multipacket reception model.

In this chapter, we introduced a collision model of a DS-CDMA network using random spreading sequences, where a collision is said to occur if there is no proper power control scheme for achieving a desired SINR at receivers. We derived and simulated the collision probabilities, assuming matched filter receivers.

A queueing analysis with the saturated slotted ALOHA model was conducted to study the MAC-layer throughput performance for systems equipped with enhanced packet reception capabilities, an example being the proposed collision model. Under a general physical reception model, the stability region for saturated slotted ALOHA for two transmitter—receiver pairs is explicitly characterized. Then we discussed throughput under a symmetric multipacket reception model, as a special case of the general reception model, and under the proposed collision model, as a special case of the symmetric multipacket reception model.

In this chapter, we introduced a collision model of a DS-CDMA network using random spreading sequences, where a collision is said to occur if there is no proper power control scheme for achieving a desired SINR at receivers. We derived and simulated the collision probabilities, assuming matched filter receivers.

A queueing analysis with the saturated slotted ALOHA model was conducted to study the MAC-layer throughput performance for systems equipped with enhanced packet reception capabilities, an example being the proposed collision model. Under a general physical reception model, the stability region for saturated slotted ALOHA for two transmitter—receiver pairs is explicitly characterized. Then we discussed throughput under a symmetric multipacket reception model, as a special case of the general reception model, and under the proposed collision model, as a special case of the symmetric multipacket reception model.

In this chapter, we introduced a collision model of a DS-CDMA network using random spreading sequences, where a collision is said to occur if there is no proper power control scheme for achieving a desired SINR at receivers. We derived and simulated the collision probabilities, assuming matched filter receivers.

A queueing analysis with the saturated slotted ALOHA model was conducted to study the MAC-layer throughput performance for systems equipped with enhanced packet reception capabilities, an example being the proposed collision model. Under a general physical reception model, the stability region for saturated slotted ALOHA for two transmitter—receiver pairs is explicitly characterized. Then we discussed throughput under a symmetric multipacket reception model, as a special case of the general reception model, and under the proposed collision model, as a special case of the symmetric multipacket reception model.

In this chapter, we introduced a collision model of a DS-CDMA network using random spreading sequences, where a collision is said to occur if there is no proper power control scheme for achieving a desired SINR at receivers. We derived and simulated the collision probabilities, assuming matched filter receivers.

A queueing analysis with the saturated slotted ALOHA model was conducted to study the MAC-layer throughput performance for systems equipped with enhanced packet reception capabilities, an example being the proposed collision model. Under a general physical reception model, the stability region for saturated slotted ALOHA for two transmitter—receiver pairs is explicitly characterized. Then we discussed throughput under a symmetric multipacket reception model, as a special case of the general reception model, and under the proposed collision model, as a special case of the symmetric multipacket reception model.

In this chapter, we introduced a collision model of a DS-CDMA network using random spreading sequences, where a collision is said to occur if there is no proper power control scheme for achieving a desired SINR at receivers. We derived and simulated the collision probabilities, assuming matched filter receivers.

A queueing analysis with the saturated slotted ALOHA model was conducted to study the MAC-layer throughput performance for systems equipped with enhanced packet reception capabilities, an example being the proposed collision model. Under a general physical reception model, the stability region for saturated slotted ALOHA for two transmitter—receiver pairs is explicitly characterized. Then we discussed throughput under a symmetric multipacket reception model, as a special case of the general reception model, and under the proposed collision model, as a special case of the symmetric multipacket reception model.