KR101596571B1 - Method and system for utilizing smart antennas establishing a backhaul network - Google Patents

Abstract

A method and system for using a smart antenna to transmit a message between nodes is disclosed. The wireless communication system includes a plurality of nodes, and each node can be connected to each other. A smart antenna is provided that is configured to generate a plurality of directional beams in at least a portion of the nodes. Each node maintains a list of other nodes and beam configuration information to be used to send messages to other nodes. When the source node is required to transmit to the target node, the source node retrieves the beam configuration information and transmits it to the directional beam towards the target node.

Description

TECHNICAL FIELD [0001] The present invention relates to a method and system for setting up a backhaul network using a smart antenna,

The present invention relates to wireless communications. More particularly, the present invention is a method and system for using a smart antenna in establishing a backhaul network.

One of the most important issues in wireless communication systems is increasing the capacity of the system by reducing interference. An array antenna (also known as a smart antenna) has been developed to improve capacity and reduce interference. A smart antenna uses a plurality of antenna elements to generate a directional beam that emits signals only toward a specific direction of an azimuth angle, and selectively detects signals transmitted from a specific direction. In the case of a smart antenna, since the signals are emitted in a narrow region of the coverage area, the capacity of the wireless communication system can be increased and interference can be reduced. This increases the overall system capacity, since the transmitter can increase the transmit power level of the directional beam without causing excessive interference to other transmitters and receivers such as WTRUs and base stations.

A wireless communication system generally includes a plurality of nodes such as a base station and a radio network controller. The nodes are typically connected to each other by a wired connection, such as a mesh network or a cellular network. The nodes communicate with each other and send messages such as backhaul messages.

However, the wired connection is expensive, requires a lot of time, is not flexible to the modification or change of the network, and is disadvantageous for setting up the backhaul network. In particular, mesh networking requires nodes to be connected to each other. When a new node is added to the mesh network, it becomes a heavy burden (in terms of both cost and time) to establish a new connection to the new node for the backhaul.

Therefore, there is a need for a cost effective, less time consuming, flexible method and system for configuring a backhaul network.

The present invention is implemented in a wireless communication system comprising a plurality of nodes, wherein each node is connected to one another in a mesh network. At least a portion of the nodes are provided with one or more smart antennas configured to generate a plurality of directional beams. Each node with one or more smart antennas maintains a list of other nodes with smart antennas and beam direction and configuration information to be used to transmit messages to these other nodes. When a source node is required to send backhaul data to a target node, the source node retrieves the beam direction and configuration information for the target node and sends the message to the directional beam towards the target node.

The present invention enables cost effective, less time consuming, and flexible wireless communication methods and systems for setting up a backhaul network.

1 is a block diagram of a network of multiple nodes in accordance with the present invention.
Figure 2 is a block diagram of a node made in accordance with the present invention.
3 is a flow diagram of a process for using smart antennas to transmit messages between nodes in accordance with the present invention.
Figure 4 is a diagram of an example of a beam pattern generated by a node in accordance with the present invention.

The present invention is a method and system for using a smart antenna in establishing a backhaul network. The present invention relates to the use of a smart antenna internally to improve in-cell communication, increase throughput, and form at least a portion of a flexible backhaul network that delivers backhaul data. The present invention is implemented in a wireless communication system comprising a plurality of nodes, wherein each node is connected to one another in a mesh network. At least a portion of the nodes are provided with one or more smart antennas configured to generate a plurality of directional beams. Each node with one or more smart antennas maintains a list of other nodes with smart antennas and beam direction and configuration information to be used to transmit messages to these other nodes. When a source node is required to send backhaul data to a target node, the source node retrieves the beam direction and configuration information for the target node and sends the message to the directional beam towards the target node.

The present invention is applicable to time division duplex (TDMA) systems that are applied to Universal Mobile Telecommunications System (UMTS), CDMA2000, CDMA, Global System for Mobile Communications (GSM), General Packet Radio System (GPRS) But is not limited to, any wireless communication system including TDD, frequency division duplex (FDD), and time division synchronous code division multiple access (TD-SCDMA).

In the following, the term "WTRU" includes but is not limited to a user equipment, a mobile station, a fixed or mobile subscriber unit, a pager, or any other type of device capable of operating in a wireless environment. When referred to hereafter, the term "node " includes but is not limited to a base station, a Node-B, a site controller, an access point, or any other type of interfacing device in a wireless environment.

Figure 1 is a block diagram of a network 100 of multiple nodes 102a-n in accordance with the present invention. At least one of the nodes (shown schematically as 102n) is connected to the core network 110. [ The operation of the core network of a wireless communication system is well known to those skilled in the art and is not central to the present invention. Therefore, the core network 110 will not be described in detail.

Each node 102a-n serves one or more WTRUs (not shown) located within the coverage area of nodes 102a-n. The network 100 may be a mesh network or a cellular network. In the context of the present invention, both the mesh network and the cellular network transmit backhaul information, but there is a fundamental difference. A cellular network typically has a fixed network infrastructure and backhaul connections. These connections are typically point-to-point and they do not change. One node sends backhaul data only to that location to another node in another location in the network.

In the case of a mesh network, the inter-node connectivity changes, so that backhaul data can be sent to different nodes at different times for different routing. In particular, in the case of a mesh network, it is important to adjust the smart antennas so that connections to different nodes can be made without creating undue interference to other nodes, since backhaul connections can change over time.

At least one of the nodes 102a-n is provided with at least one smart antenna (to be described below) and is adapted to transmit backhaul data to other nodes 102a-n in addition to the normal download transmissions to the WTRU Using a smart antenna and uploading the receipt from the WTRU. These nodes 102a-n can generate multiple directional beams and steer the beam in any direction at azimuth angle.

The network 100 is expected to include nodes that make wired connections as well as nodes that use wireless antennas that use smart antennas. Connections established using smart antennas are reconfigured to point to different nodes, thus increasing the flexibility of the system. However, at least one of the nodes will make a wired connection to the core network 110 and a wireless connection to other nodes to provide connectivity between the group of wireless nodes and the core network, which is essentially a wired network. At least some of the nodes 102a-n may also be provided with the ability to transmit backhaul information via a wired or dedicated connection. A node (denoted as node 102n, hereinafter referred to as a hybrid node) that makes a wired and wireless backhaul connection will be a connection to the wired core network 110. In other words, since the nodes wirelessly transmit backhaul information with the aid of a smart antenna, such backhaul information will eventually be routed through the hybrid node 102n to the core network 110. [ Thus, the hybrid node 102n can receive backhaul information and transmit it to the nodes that are making wireless backhaul connections, while receiving the backhaul information and transmit it to the core network 110, thereby forming a bridge can do.

In one embodiment, nodes 102a-n have multiple predetermined beams 109a-h as shown in FIG. 4, and one of multiple beams 109a-h to direct transmission or reception . Figure 4 illustrates the azimuthal representation of the eight beams that may be generated by each node 102a-n. The beams shown in FIG. 4 are provided by way of example only and any number of beams, beam patterns, or any type of pattern may be implemented.

In an alternative embodiment, each beam 109a-h may be generated and directed in real time rather than selected from a given set of locations.

The nodes 102a-n dynamically select a beam 109a-h direction that provides the best performance in terms of system capacity, data throughput, interference, or the like, or select from among a plurality of available locations. The nodes 102a-n are generally fixed at a specific location. Therefore, once the configuration between the two nodes 102a-n and the beams 109a-h are set, the direction and configuration can be stored and used thereafter without change. Each node 102a-n may provide more than one beam 109a-h to connect to other nodes 102a-n because the radio environment and traffic load may change over time. Thus, each node 102a-n monitors signals received from other nodes 102a-n to determine the radio environment and dynamically adjusts the beam direction and signal configuration to optimize the performance of the system.

An example of the operation of the system is as follows: a first selected node, such as node 102a, generates a beam and steers it toward another selected node, such as node 102b. This can be done by adjusting the complex weights applied to the antenna array elements, which is typically done with beam forming antenna arrays. At the same time, node 102a measures the quality of link A to node 102b. The quality of the link (A) can be measured with a signal-to-noise ratio, a bit or frame error rate, or some other measurable quality indicator. The transmitting node 102a finds the best antenna beam direction, in this case the best weight combination to maximize link quality, and stores both the link quality measurements and the corresponding beam direction (weight). The transmitting node 102a does this for all nearby nodes and stores the corresponding quality and beam information.

Any node 102a-n may be flexibly and wirelessly connected or disconnected to other nodes 102a-n by selectively directing one or more beams to other nodes 102a-n. In Figure 1, a first node 102a transmits a message to a second node 102b using a directional beam A and a message to a fourth node 102d using a directional beam B. [ The directional beams A and B can be independently controlled and transmitted at the same time. Each directional beam A and B does not cause excessive interference to other nodes 102a-n or WTRUs because it is only emitted in a specific direction.

2 is a block diagram of a node 202 in accordance with the present invention. Node 202 includes a smart antenna 204, a controller 206, a memory 208, and an optional wired link 210. The wired link 210 may be a link to the core network 110 or another node. Node 202 performs signal processing algorithms to adapt to multipath along with user movement, changes in radio frequency environment, and inter-channel interference. The radio resource management (RRM) function performed by the controller 206 determines how radio resources are to be allocated at the node 202.

The smart antenna 204 may include a plurality of antenna elements (not shown) to generate a plurality of directional beams under the control of the controller 206. Each beam acts as a wireless connection between node 202 and other nodes. As described above, since the node 202 is typically fixed at a specific location, the beam direction and configuration between the two nodes can be predetermined and stored in the memory 208. [ The memory 208 maintains a list of other nodes and beam direction and configuration for each of these other nodes. When the node 202 is required to transmit a message, such as backhaul data, to another node, the controller 206 retrieves the corresponding beam direction and configuration information from the memory 208 and generates a directional beam steered in a particular direction , And transmits the messages using the beam.

In the case of the hybrid node 102n, this process is preceded in establishing a wireless connection to other nodes with the aid of the smart antenna 204. [ When the hybrid node 102n establishes a backhaul connection to the core network 110 or another node, there is no configuration information or beam selection since the wired link 210 will be physically fixed and will always provide connectivity between the same two nodes .

According to the present invention, the smart antenna 204 preferably has a multi-beam function, and each beam can be used independently. Node 202 may generate more directional beams to transmit backhaul data to multiple other nodes at the same time. Since the same frequency can be reused for more than one directional beam of the same coverage area, the system capacity is substantially increased.

Some nodes may be combined with some beams. This makes it convenient to change the connection and dynamically adapt to changes in the wireless environment. For example, two beams may be provided for connection between two nodes. If one beam experiences excessive interference, the nodes may switch to another beam for message transmission.

The use of a smart antenna enables flexible backhaul link formation between nodes. As each node is configured to generate a plurality of directional beams and can steer the directional beams in any direction in azimuth, when a new node is added to the network 100, By simply setting the beam direction and configuration, a new connection can be established to the new node. Further, when a conventional node is removed from the network 100, the nodes may simply delete the beam direction and configuration information for the removed node from the memory 208. [ The present invention eliminates unnecessary facilities for performing additional installations or establishing or removing connections between nodes. It should be understood that the present invention can be implemented in either a mesh network or a cellular network.

One of the strengths of mesh networking is the ability to create new links and delete other links between nodes that depend on a number of factors including traffic load, interference, and individual node performance. As shown in Figure 1, multiple nodes 102a-n are coupled together using smart antennas. The lines between nodes 102a-n in Figure 1 indicate possible links A-F. The control can be centralized such that at least one node functions as a control node to control or to distribute connections between nodes, where control is distributed across several nodes or all nodes. When one node is designated as a control node, the control node collects information on the traffic conditions and capabilities of each node, and determines the best traffic route to transmit a message from one node to another node .

Each node 102a-n preferably transmits one or more beacon signals in its one or more beams, which provides information useful for network operation. For example, beacon signals may transmit current power levels, traffic levels, interference levels, and other parameters. Beacon signals also include connection priority, security, identification, and other varying types of access control and security control information. Beacon signals are measured periodically or aperiodically, and parameters are utilized as a basis for coordinating connections between nodes to find the most efficient traffic route. The formation of at least some of the backhaul connections wirelessly using the smart antenna according to the present invention allows flexibility and reduces unnecessary cost and time in establishing and coordinating connections between nodes.

For example, as shown in FIG. 1, if the traffic load between the second node 102b and the fourth node 102d is very large, the other nodes may be connected to nodes 102b, d To recognize the traffic conditions between the two nodes 102b, d. If the first node 102a routes traffic to the fifth node 102e, it will avoid the second and fourth nodes 102b, d if possible, and alternatively, traffic through the Nth node 102n, I will route.

The present invention not only has the advantage of providing a flexible, wireless mesh network, but also backhaul information (typically transmitted over a wired line) can now be transmitted over the same flexible links through a smart antenna. Implementing this type of public smart antenna scheme in accordance with the present invention provides significant advantages over current wireless communication systems.

3 is a flow diagram of a process 300 of using smart antennas for message transmission between nodes in accordance with the present invention. At least some of the nodes are provided with at least one smart antenna, which is configured to generate a plurality of directional beams and then steer independently in azimuth (step 302). Each beam is used as a wireless connection to other nodes in addition to the normal traffic of downloading from the WTRU and uploading from the WTRU. Each node maintains a list of other nodes and beam direction and configuration information used for transmission to the remaining nodes. Steps 302 and 304 are typically performed by setting up the system or reconfiguring the system to accept or delete nodes, and typically need not be formed during normal operation. When the source node needs to transmit to the target node, the source node retrieves the beam direction and configuration information for the target node from the memory and generates the directional beam using the beam direction and configuration information (step 306). When a node is selected for transmission of backhaul data, based on other considerations such as link quality and traffic density, the transmitting node selects the beam direction (weight) from the list and applies it to the antenna.

The process of measuring the quality of the link and storing the relevant information needs to be done periodically, as the environment may change and beam direction adjustment may be required. The source node transmits the generated directional beam to the target node (step 308).

At an optional step, a change in the network can occur, whereby a new node can be added to the network, a conventional node can be removed from the network, or radio frequency or other conditions can change. In response to the change, other nodes update the list of beam direction and configuration information to reflect the change (step 310).

Although the features and elements of the present invention are described in terms of specific combinations of preferred embodiments, each feature or element may be used alone or in combination with other features and elements of the present invention, And can be used in various combinations.

Claims (11)

A node configured to serve one or more wireless transmit and receive units (WTRUs)
A wired connection to the core network configured to exchange backhaul information with the core network for exchanging backhaul information with the core network and a second node, the second node configured to serve one or more WTRUs;
And to transmit the received backhaul information for the second node to the second node using an antenna array and to select an antenna radiation pattern for transmission of backhaul data for the second node, A controller; And
And an antenna array configured to transmit backhaul data for the second node to the second node using the selected antenna radiation pattern. 2. The method of claim 1 wherein backhaul data for the second node is transmitted at least at a first frequency and the controller is further configured to transmit data to a third node in a second antenna radiation pattern on the first frequency In node. 3. The node of claim 2, wherein the data transmitted to the third node is backhaul data for the third node. 2. The node of claim 1, wherein the antenna radiation pattern is dynamically selected in response to channel conditions. 2. The method of claim 1 wherein the controller is further configured to receive load information from at least a third node and to schedule the transmission of backhaul data for the second node in response to the received load information , Node. In the method,
Exchanging backhaul information with a core network by a network node, via a wired connection, and exchanging backhaul information for the second node with the core network, wherein each of the network node and the second node comprises one Exchanging the backhaul information and the backhaul information for the second node with the core network, wherein the backhaul information and the wireless transmit and receive units (WTRUs) are served by the core network;
Transmitting, by the network node, received backhaul information for the second node to the second node using an antenna array, the controller in the network node selecting an antenna radiation pattern , Said transmitting; And
And transmitting, by the network node, backhaul data for the second node using the selected antenna radiation pattern. 7. The method of claim 6 wherein backhaul data for the second node is transmitted at least at a first frequency and the network node transmits data to a third node in a second antenna radiation pattern on the first frequency, And sending one or more WTRUs to the serving. 8. The method of claim 7, wherein the data transmitted to the third node is backhaul data for the third node. 7. The method of claim 6, wherein the antenna radiation pattern is dynamically selected in response to a channel condition. 7. The method of claim 6, further comprising: receiving load information from at least a third node by the network node; scheduling transmission of backhaul data for the second node in response to the received load information by the network node; ≪ / RTI > A wireless node configured to serve one or more wireless transmit and receive units (WTRUs)
An antenna array configured to receive backhaul data transmitted from a network node using a selected antenna radiation pattern from the antenna array; And
And a controller configured to transmit data to the third node through the antenna array using the selected antenna radiation pattern.

Images