KR100500225B1 - Cdma communication system which selectively suppresses data transmissions during establishment of a communication channel - Google Patents

Abstract

The CDMA communication system, which blocks data transmission between communication nodes until the data communication radar required by the communication nodes in the system is completely set up, selectively suppresses 314 a confirmation tone sent by the receiving node to the originating node. Voice, facsimile or modem data transmission is blocked until the communication path is established at the required communication rate. This allows the system to reliably transmit encoded data at multiple data rates across a communication system that may lack accurate synchronization.

Description

CDMA COMMUNICATION SYSTEM WHICH SELECTIVELY SUPPRESSES DATA TRANSMISSIONS DURING ESTABLISHMENT OF A COMMUNICATION CHANNEL}

The present invention relates generally to wireless communication systems. More specifically, the present invention relates to a wireless digital CDMA communication system that selectively adjusts the data transfer rate according to the bandwidth required by the communication without loss of data during communication rate adjustment.

The communications industry has grown significantly in recent years with the use of wireless technologies, including cellular, satellite and microwave communications. As the popularity and use of wireless communication systems increase, the finite bandwidth allocated to each type of wireless communication is becoming increasingly valuable. Since additional bandwidth to support the growth of users is not expected to be allocated for existing applications, many advances in recent communication hardware and software have been able to reduce the transfer rate of data using the same or reduced bandwidth. It was to increase.

One of the problems associated with wireless communication of data is that a number of different types of communication nodes are currently in use, including computers, facsimile machines, automated calling and answering devices, and other forms of data networks. These nodes can communicate at a plurality of different data rates and must be properly synchronized to avoid data loss during the establishment or maintenance of the communication.

Setting up and synchronizing communications is currently being performed using a variety of different technologies. For example, the system disclosed in US Pat. No. 4,384,307 (Kuzmik et al.) Includes a communication adapter for connecting a transceiver over a communication line. This system requires bit level manipulation of the data to properly synchronize the two communication nodes. Reformatting data using this technique is computationally expensive and error prone.

Another type of system is disclosed in US Pat. No. 4,583,124 (Tsuji et al.), Which allows two nodes to store information associated with each communication node in memory to quickly establish synchronization at a desired communication rate. However, requiring the generating node to store information about each receiving node is impractical in today's communication environment.

Therefore, there is a need for a simple and effective technique for switching the data transmission rate of the communication network to the required rate while maintaining the integrity of the data transmitted between the two communication nodes.

1 is a schematic diagram of a code division multiple access communication system according to the present invention;

2 is a block diagram of the FIG. 1 communication system coupled to the originating and terminating node.

3 is a flow chart for establishing a communication channel between originating and terminating nodes in accordance with known techniques.

4 is a flowchart of establishing a communication channel between a generating node and an ending node in accordance with the present invention.

5 is a base station block diagram in accordance with the teachings of the present invention.

The present invention is to provide a CDMA communication system that prevents data transmission between communication nodes until the data communication rate required by the communication nodes is set completely throughout the system. This system selectively suppresses the confirmation tone that the receiving node sends to the originating node. Therefore, the transmission of voice, facsimile or modem data is prohibited until the communication path is set to the desired communication rate. This allows the system to reliably transmit data encoded at multiple data rates in a communication system that may lack accurate synchronization.

It is therefore an object of the present invention to provide a system and method for reliably transmitting encoded data by preventing data communication until the communication system achieves the data transfer rate required by the communication nodes. Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

Preferred embodiments of the present invention will be described with reference to the accompanying drawings.

A communication network 10 embodying the present invention is shown in FIG. This communication network 10 includes one or more base stations 14, each of which is in wireless communication with a plurality of fixed or mobile subscriber units 16. Each subscriber unit 16 communicates with a base station 14 or the nearest base station 14 that provides the strongest communication signal. Base stations 14 also communicate with base station controller 20, which coordinates communication between base stations 14. The communication network 10 may be connected to a public switched telephone network (PSTN) 22, and the base station controller 20 coordinates communication between the base station 14 and the PSTN 22. Each base station 14 preferably communicates with a base station controller 20 via a wireless link. Although the link between the base stations 14 and the base station controller 20 is shown as a wireless link, a person having ordinary skill in the art may provide a terrestrial communication line between the base station 14 and the base station 20. I will understand that. This may be especially true where base station 14 is in close proximity to base station controller 20.

The base station controller 20 performs various functions. First, base station controller 20 provides all overhead, administrative and maintenance (OA & M) signaling associated with establishing and maintaining all wireless communications between subscriber units 16, base stations 14, and base station controller 20. . The base station controller 20 also provides an interface between the wireless communication system 10 and the PSTN 22. This interface includes multiplexing and demultiplexing of a plurality of communication signals entering or exiting system 10 through base station controller 20. Although the wireless communication system 10 is shown using an antenna to transmit RF signals, one of ordinary skill in the art will understand that communications may be accomplished by microwave satellite uplinks.

In FIG. 2, communication system 10 is connected to originating nodes 40 and terminating nodes 44. In order to keep the bandwidth as wide as possible, the communication system 10 selectively allocates the bandwidth required to support the data transfer rate required by the originating and terminating nodes 40, 44. In this way the system 10 ensures that the bandwidth is used efficiently. Voice communication can be effectively transmitted over a 32 Kbs adaptive pulse code modulation (ADPCM) channel. However, high speed fax or data modem signals require at least 64 Kbs pulse code modulation (PCM) signals to reliably transmit communications. Many other types of modulation techniques or data transfer rates may also be used by the generating and terminating nodes 40, 44. Such a system 10 must be able to allocate bandwidth effectively and be able to switch dynamically between the required modulation scheme and data communication rate.

The communication system 10 provides a communication link between originating and terminating nodes 40, 44. These originating and terminating nodes 40, 44 may comprise a computer, a facsimile machine, an automatic calling and answering device, a data network, or any combination of such devices. For robust communication of data, it is essential to ensure that communication system 10 is switched to the data communication rate required by communication nodes 40, 44 before any data is sent.

Referring to FIG. 3, an exemplary process for establishing communications between originating nodes 40 and terminating nodes is shown. The generating node 40 periodically transmits a calling tone indicating that data communication (but not voice communication) is being transmitted (step 100). The ring tone sent from the originating node 40 to the terminating node 44 is detected by the terminating node 44 initiating various operations (step 102). First, the terminating node 44 prepares for data communication transmission (step 104). Next, to confirm that the end node 44 has received the ring tone, the end node 44 transmits an answer tone to the generating node 40 (step 106). Upon receiving this response (step 108), the originating node 40 starts transmitting data (step 110), which is received by the end node 44 (step 112). With the communication link set at that data transmission rate, the generating and terminating nodes 40, 44 transmit and receive data until the communication is terminated.

One problem with this process is that the transmission rate of communication system 10 is transparent to both originating and terminating nodes 40, 44. Changing the communication rate from a low rate (supporting voice communication) to a high rate (supporting encoded data communication) ensures that data is transmitted reliably and quickly over the communication channel. However, the new transmission rate must be set completely in the communication system 10 to prevent misinterpretation of the tones transmitted by the originating node 40. The generating node 40 may begin transmitting data at a high rate before the system 10 is fully switched from 32 Kbs ADPCM to 64 Kbs PCM, which results in loss of data.

In order to prevent the misbehavior of the resulting occurrence or termination nodes 40, 44 and to eliminate misinterpretation of the sound, the present invention, until the new data communication rate is set completely in the communication system 10, The transmission of the confirmation tone to the generating node 40 is blocked. This prevents reception of a response tone at the transmitting node 40 and ensures reliable transmission of encoded data at a higher rate across the communication system 10 that would otherwise lack the exact synchronization required.

The operation of the system 10 of the present invention will be described with reference to FIG. The communication system 10 facilitates communication between the originating node 40 and the terminating node 44. As shown, the operations of the originating node 40 (steps 202, 212 and 214) and the operations of the end node 44 (steps 206, 207, 208 and 218) are the same as in FIG. 3. Operation of communication system 10 is evident for both originating node 40 and terminating node 44.

In operation, the generating node periodically transmits a ring tone indicating data communication (step 202). The communication system 10 performs various operations in response to receiving the ring tone (step 204). First, the ring tone is received at 32 Kbs ADPCM, which is the standard communication setting for voice communications. The system 10 detects the ringing tone and starts switching to 64 Kbs PCM to handle high speed data transfer. This switching must be performed by the base station 14, the subscriber unit 16 and the base station controller 20. Although the system 10 immediately starts switching to the new data transfer rate, this process takes about 1500 msec to implement. Thus, system 10 sends a ring tone to end node 44 at 32 Kbs ADPCM.

End node 44 detects the ring tone (step 206) and prepares to send data communication (step 207). Subsequently, the end node 44 transmits a response tone (step 208), and when it is received by the originating node, causes the originating node 40 to begin transmitting data.

The communication system 10 receives a response tone from the end node 44. However, system 10 does not transmit a response tone to originating node 40 until switching to 64 Kbs PCM is set in system 10. After confirming that the switch to 64 Kbs PCM has been achieved, the system 10 allows the response to pass to the originating node 40 receiving the response (step 212). In response to this answering tone, the originating node 40 starts transmitting data (step 214). The system 10 receives the data and begins the transfer of data to the end node 44 at the new data transfer rate (64 Kbs PCM) (step 216), which end node 44 receives the data (step 218). ). Since the communication channel has been established, the originating and terminating nodes 40, 44 continue to communicate through the system 10 in this manner until the communication ends (steps 214, 216 and 218).

5, a more detailed block diagram of a base station controller 20 is shown. Base station controller 20 controls at least a portion of a communication link between two communication nodes 40, 44. Such a link is a communication path 300 from the first communication node to the base station controller 20, a communication path 302 within the base station controller 20, and a communication path 304 from the base station controller 20 to the second communication node. ). Communication path 300 to base station controller and communication path 304 from base station controller may include subscriber units 16 and a plurality of base stations 14 controlled by base station controller 20.

It will be appreciated that the communication channel establishment between communication nodes 40, 44 is a complex process comprising a plurality of tasks performed by base station 14, subscriber unit 16, and base station controller 20. This detailed description of the whole process is not within the scope of the present invention. Therefore only parts of the procedure for establishing a communication channel related to the present invention will be described below.

Communication between originating node 40 and terminating node 44 is transmitted over a virtual channel, as is well known to those skilled in the art. Since the entire spectrum is used by the CDMA communication system 10, communication from the originating node 40 to the terminating node 44 is via the same frequency band as the communications from the terminating node 44 to the originating node 40. Is sent. After the virtual channel is established, the originating and terminating nodes 40, 44 can be freely communicated.

The base station controller 20 includes a ring tone detector 310, a microprocessor 312 and a response tone blocker 314. The ring tone detector 310 monitors the communication channel established for detecting the ring tone. When a ring tone is sent from the originating node 40, the ring tone detector 310 detects a ring tone that causes the base station controller 20 to start switching to a higher data transfer rate. Microprocessor 312 subsequently notifies any other base stations 14 or subscriber units 16 (hereinafter referred to as communication equipment) to which the communication should be routed to switch to a higher data transfer rate.

Microprocessor 312 activates a response tone blocker 314 that prevents a response tone from being transmitted through system 10. Each of the communications equipment 14, 16, 20 sends an acknowledgment to the microprocessor 312 of the base station controller 20 when a higher data transfer rate is achieved. This microprocessor 312 subsequently deactivates the answering tone blocker 314 so that the answering sound can be sent to the originating node 40. Communication nodes 40, 44 begin data communication through communication system 10 at a higher data communication rate.

Although partially described in connection with the preferred embodiment of the present invention, such details are instructive rather than limiting. For example, the functions performed by the base station controller 20 shown in FIG. 5 may be performed by the base station 14 in conjunction with any of the originating or terminating nodes 40 in an alternative embodiment. The functions of base station 14 may be coupled to base station controller 20 to form a master base station. In addition, different data rates and modulation schemes may be used. Those skilled in the art will understand that modes and structures of operation may be modified without departing from the spirit and scope of the invention as disclosed in the teachings herein.

Claims (21)

A system for suppressing selective communications during a bearer rate change of a communication network 10 for communication between a first communication node 40 and a second communication node 44, wherein The communication network 10 is located between the first communication node and the second communication node, and a communication channel in the network 10 between the first communication node 40 and the second communication node 44. Means (14) for setting 302 to a first data rate, the system being located within the communication network (10), Means (310) for detecting transmission from the first node (40) over the channel (302), Means (312) for determining if the transmission requires a change to a second data rate; Switch means 14 for switching the communication channel 302 at the second data rate in response to the determining means 312, and In response to the determining means 312 during the bearer rate change of the communication network, comprising blocking means 314 for blocking transmissions from the second node 44 until the second data rate is set. System to Suppress Selective Communications The method according to claim 1, wherein said detecting means (310) detects tones at a plurality of optional frequencies, said tones suppressing selective communications during a bearer rate change of a communication network, initiating a change to said second data rate. System for 3. A system according to claim 2, wherein said switch means (14) switches said first data rate to said higher second data rate. 4. The system of claim 3, wherein the first data rate is 32 kb / s and the second data rate is 64 kb / s. 5. The system of claim 4, wherein the first data rate uses pulse code modulation and the second data rate uses adaptive pulse code modulation. 2. The switching means (14) according to claim 1, wherein the switch means (14) switches the set channel (302) to one of a plurality of optional channels (302) in accordance with the required data rate and modulation type in response to the determining means (312). And system for suppressing selective communications during bearer rate change of the communications network. The communication channel (302) of claim 1, wherein the communication channel (302) is a first communication path from the first node (40) to the second node (44) and from the second node (44) to the first node (40). A second communication path, The determining means 312 monitor the transmission for a signal, the signal indicating a request for transmission rate adjustment, The switch means 14 is for adjusting the communication rate of the communication channel 302 in response to the detection means 310, The blocking means 314, in response to the detecting means 310, for suppressing communications on the second communication path until the desired communication rate is set, for selective communications during the bearer rate change of the communication network. System for containment. 8. A system according to claim 7, wherein said determining means (312) detects signals with selective frequencies indicative of a demand for an increased data transmission rate. The method of claim 8, wherein the switch means 10 inhibits selective communications during a bearer rate change of a communication network, switching the communication channel 302 to the second communication channel 302 having a higher data transfer rate. System for doing so. 10. The method of claim 9, wherein the communication channel 302 has a data rate of 32 kb / s and the second communication channel 302 has a data rate of 64 kb / s. System for containment. The method of claim 10, wherein the communication channel 302 uses pulse code modulation and the second communication channel 302 uses adaptive pulse code modulation to suppress selective communications during a bearer rate change of a communication network. system. 12. The signal according to claim 11, wherein the signal is indicative of the required data rate and modulation form, and the switch means 14 responds to the determining means 312 to one of a plurality of optional channels in accordance with the requested data rate and modulation. A system for inhibiting selective communications during a bearer rate change of a communications network that switches the channel (302). A method for changing the data transfer rate of a communication network 10, The communication network is for communication between the originating node 40 and the terminating node 44 and is located between the originating node 40 and the terminating node 44. Receiving, by the communication network 10, a first communication from the originating node 40 at a first data communication rate; Detecting by the communication network 10 a request for changing the data communication rate; Initiating a change to the requested data communication rate in the communication network 10 by the communication network 10; Sending the first communication to an end node 44 at the first data rate; Receiving a second communication from the terminating node 44; Suppressing the answering tone from within the communication network 10 until the change is completed; Completing the change; Transmitting the second communication to the originating node (40). The method of claim 1, The communication channel 302 is a first dual communication channel 302 between a first communication node 40 and a second communication node 44 comprising a transmit (Tx) portion and a receive (Rx) portion, and the first Channel 302 has a first data communication rate and modulation form, The detecting means 310 is for detecting the transmission from the first node 40 on the Tx portion, The determining means 312 is for determining whether the transmission requires a change to a second dual communication channel 302 having a second data communication rate and modulation form, The switching means 14 is for switching the first communication channel 302 to the second communication channel 302 in response to the determining means 312, The blocking means 314 is in response to the determining means 312 to block transmissions on the Rx portion until the second communication channel 302 is established, during the bearer rate change of the communication network. System to suppress them. 15. The selective communication during the bearer rate change of the communication network according to claim 14, wherein said detecting means (310) detects selectively transmitted frequencies on said Tx portion indicating a request for change to said second communication channel (302). System to suppress them. 16. The system of claim 15, wherein the second communication channel (302) has a data rate faster than the first communication rate. 17. The system of claim 16, wherein the first data communication rate is 32 kb / s and the second data communication rate is 64 kb / s. 18. The method of claim 17, wherein the first data communication channel 302 uses pulse code modulation and the second communication channel 302 uses adaptive pulse code modulation to perform selective communications during a bearer rate change of a communication network. System for containment. 15. The communication network of claim 14, wherein the switch means 14 switches the established channel 302 to one of a plurality of optional channels in accordance with the requested data rate and modulation in response to the determining means 312. A system for suppressing selective communications during bearer rate change. The method of claim 1, The determining means 312 is for determining whether the transmission requires changing the data rate and modulation form to a second data rate and a second modulation form, The switch means 14 is for switching the communication channel 302 to the second data rate and the second modulation form in response to the determining means 312, The blocking means 314 is for blocking the transmissions from the second node 44 until the second data rate is set in response to the determining means 312 during the bearer rate change of the communication network. System for suppressing selective communications. The method of claim 13, wherein the detecting step includes detecting a data rate and a modulation type required to support the first communication, And said starting step comprises initiating a change to said required data rate and modulation type.