Patent Document

FIELD OF THE INVENTION 
     This invention is concerned with trunked communication systems. 
     More particularly, this invention is concerned with efficient channel allocation and deallocation for data and voice in a trunked communication system. 
     BACKGROUND OF THE INVENTION 
     Trunked RF communication systems exist to effectively allocate limited channel resources among a plurality of subscriber units. This is accomplished by reusing the same set of available RF frequencies over many different subscriber groups. A central controlling computer, with knowledge of the currently available RF frequencies receives channel allocation requests from subscriber units on an RF control channel. This computer then assigns a voice channel on a predetermined basis to the requesting subscriber unit&#39;s group of users. 
     In a basic RF trunked system, there exists a high degree of flexibility to partition voice conversations between different groups so that no one group of users is specifically aware when another group of users makes use of the system. Typically, these groups are divided into subgroups so that calls may be made upon either a group, subgroup or individual basis depending upon the type of communication desired by an initiating subscriber. 
     To establish a voice communication between a group of subscriber units operating on a trunked system, a subscriber unit transmits a data packet called an ISW (Inbound Signalling Word) on a control channel that is maintained for such purposes. The ISW contains at least the requesting subscriber unit&#39;s unique ID code, which may contain or be used to obtain the requesting subscriber&#39;s current talk-group. The request is forwarded to a TCC (Trunked Central Controller, also known as a central controller), which decodes the request and transmits on the control channel a data packet called an OSW (Outbound Signalling Word) to all subscriber units, which continuously monitor the control channel when not participating in a voice conversation. The OSW is a channel grant that contains the talk-group code of the requesting subscriber unit and the voice channel number assigned for the conversation. The OSW causes the requesting subscriber unit to move to the voice channel and commence transmitting, while simultaneously causing all other subscriber units in the same talk-group to move to the voice channel as listening units. In this way, a group call is set up. If, however, all voice channels are in use when a subscriber unit transmits an ISW, the TCC typically sends the requesting subscriber a Busy OSW. 
     In addition to voice messages, it is desirable to send data information across a trunked radio channel. In some data systems, a subscriber obtains a trunked data communication channel via the same procedure used to obtain a voice channel. However, this practice is inefficient and spectrally wasteful, due to the time it takes for a requesting subscriber to transmit an ISW and receive a channel grant OSW from the TCC, and the time it takes to set up and terminate a call on a voice channel. At contemporary data transmission rates, it is anticipated that an entire typical data message would take substantially less time to transmit than the time required to obtain a channel (approximately 0.5 seconds). Thus, assigning a data channel pursuant to the same procedure as assigning a voice channel would be wasteful of spectrum and consume precious system time that could be better used to transmit data messages. 
     Other trunked communication systems desirous to accommodate data traffic have permanently dedicated one or more channels to handling data traffic. While this avoids the access time problem noted above, this technique is contrary to the basic principles of trunked communication systems, which strive to allocate channel resources across a plurality of users as required. Therefore, the practice of having dedicated data channels, permanently removed from the channel allocation pool of frequencies, is wasteful of spectral resources and leads to inefficient system operation. Moreover, dedicated data channel systems lack the capacity to dynamically redistribute or allocate the data traffic load across the available data channels. Such systems typically permanently assign a subscriber unit to a data channel, thereby building in future problems as the number of data subscribers increases on a particular channel. 
     Placing a fixed timer on the data channel, thereby allotting a fixed amount of time for a data transmission, allows for the data channel to be deallocated (released) after a certain amount of time. The drawbacks of this method are that if the fixed time is too long, the channel will never be released, and if the fixed time is too short, important messages are likely to be truncated or lost. 
     Accordingly, there exists a need for a trunked communication system that can accommodate both voice and data message formats, and that operates in true trunked manner to efficiently utilize spectral resources. 
    
    
     BRIEF DESCRIPTION OF THE DRAWINGS 
     FIG. 1 is a block diagram of a trunked radio system in accordance with the invention. 
     FIGS. 2A and 2B depict a flowchart illustrating the steps executed to efficiently allocate channels in accordance with the invention. 
    
    
     DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT 
     The preferred embodiment of the invention resides in the TDC (Trunked Data Controller), such as a TDC3000 available from Motorola, Inc. The TDC (101) is located in the memory of a personal computer, such as a PC386 available from IBM, as shown in FIG. 1. The TDC controls the seizing of a specified base station (111), such as an MSF5000 available from Motorola, Inc., for data operation, the release of the same, and the release of the associated trunking channel. The seize and release of the station is accomplished via commands from the TDC to the NCP, Network Control Processor (103), such as an NCP3000 available from Motorola, Inc., then transparently to the GCC, General Communication Controller (105), such as a GCC480 available from Motorola, Inc. The deallocation of the channel is handled via a command to the TCC, Trunked Central Controller (107), such as a T5184 with console interface option D431 available from Motorola, Inc. These operations are triggered by channel allocation grants from the TCC, inbound data messages from the mobile KDT, Keyboard Display Terminal (109), acknowledges to outbound data messages to the KDT(s), data messages to/from the GCC, and internal timed events. The TDC is connected to the system user&#39;s host computer (113), RS232 compatible. 
     In the preferred embodiment of the invention, the subscriber unit is a KDT, such as a KDT480C available from Motorola, Inc. attached to a trunked mobile, such as a Smartnet MaxTrac Mobile with data option available from Motorola, Inc. This mobile KDT pair will be referred to as a terminal in the preferred embodiment. The convention defining Inbound and Outbound messages shall be with respect to the fixed end (i.e., base station) of the system. For example, an Inbound message begins at the terminal and an Outbound message is destined for the terminal. 
     The preferred embodiment of the invention allocates channels in an RF trunked communication system to both voice and data message formats. The TDC uses the procedure described in the following paragraphs to mark the channel state as up, assigned as a data channel, or down, not assigned as a data channel. Here, a down channel may be assigned as a voice channel. An up channel need not have its base station keyed. 
     The TDC maintains in its memory two lists of terminal IDs, one for Inbound messages and one for Outbound messages. The Inbound queue has a timer associated with each terminal ID. The Outbound queue has a counter as well as a timer associated with each terminal ID. The TDC keeps an Inbound and Outbound queue, collectively called the channel queues, for each data capable channel in the system. 
     Processing for each channels queues occurs as follows. A terminal ID is added to the Inbound queue when the TDC receives an Individual Data Channel Grant, i.e. OSW, for that terminal. The TDC seizes the channel, if necessary, and starts a timer with the time that the specified channel will be maintained for that terminal to allow for long multisegment inbound data messages and unreliable transmission (i.e., 20 seconds). After an Inbound Message is received by the TDC, the timer for that terminal is changed to a much smaller value (i.e., 0 seconds) to allow the terminal to transmit multiple messages before the channel is taken down. Every time an Inbound Message is received, the timer is reset with the short value. If a Channel Registration Message (a message from a terminal to the TDC stating that the terminal has transmitted and is ready to receive) is received from a terminal, that terminal ID is removed from the Inbound queue and is added to the Outbound queue, and the number of currently outstanding messages are stored with the terminal ID. A terminal ID is removed from the Inbound queue whenever the terminal&#39;s associated timer expires. 
     On entering a terminal ID into the Outbound queue, the TDC maintains a message counter as well as a timer. The TDC starts a timer with the time that the specified channel will be maintained for that terminal to receive an outbound message and acknowledge during unreliable transmission (i.e., 20 seconds). While a terminal ID is listed on the Outbound queue, the TDC is allowed to forward outbound data messages to that terminal. The timer is reset on each transmission. When the counter reaches zero for a terminal, a Return to Voice message is sent to that terminal telling it to move back to the voice control channel and the timer is set to the hang time value for the channel (i.e., 1 second). Hang time is the period that the channel is allocated although nothing is being transmitted. A terminal ID is removed from the Outbound queue whenever the terminal&#39;s associated timer expires. 
     Once the Inbound queue and the outbound queue for a channel reach a predetermined level (i.e., empty), the TDC releases and deallocates the associated channel. 
     FIGS. 2A and 2B represent a flowchart depicting the process of the preferred embodiment to efficiently allocate channels. The following describes some terms used in FIGS. 2A and 2B. DCG represents an Individual Data Channel Grant being received by the process for a particular terminal. IMR represents the reception of an inbound data message from a particular terminal. CRM represents the reception of a Channel Registration Message from a particular terminal. SOM represents the initiation of Sending an Outbound Message to a particular terminal. LOM represents the initiation of sending the Last Outbound Message to a particular terminal. TEX represents a queue entry Timer Expiration for a particular terminal in a particular queue. T1 is the time value to wait for the first inbound terminal message. T2 is the time value to hang the channel after the first inbound message has been received. T3 is the time value to wait While transmitting an outbound message. T4 is the time value to hang the channel after the last, or final, outbound message has been sent. T1, T2, T3, and T4 represent the predetermined selection of timer values for the TDC. In the preferred embodiment of the invention, the timer values are T1=20 seconds, T2=0 seconds, T3=20 seconds, and T4=1 second. These timer values can be dynamically alterable. 
     FIGS. 2A and 2B show the specific tasks performed by the TDC in the preferred embodiment. Initially, the TDC waits (201) for one of six distinct significant events to occur: DCG, IMR, CRM, SOM, LOM, and TEX, as described in the previous paragraph. The occurrence of each event causes an applicable report, with the same name as the event it represents, to be sent to the TDC. When the report is received, it is evaluated (203) for type and passed to the appropriate process as described in the following paragraphs. 
     When a DCG event is received for a terminal, the terminal ID is checked (205) to see if it is on another channel&#39;s queue. If it is, the queue entry timer for that terminal on the other channel is set (207) to zero. That terminal ID is added (209) to this channel&#39;s Inbound queue, and the Inbound queue entry timer is set (211) to T1. The channel is marked (213) as up (i.e., seized), Inbound communications from the terminal begin (215), and the TDC returns to the wait state (201). 
     Receipt of an IMR event causes the TDC to examine (217) the channel state. If the channel is down, an error is posted (219) and the TDC returns to the wait state (201). If up, the Inbound queue entry timer is set (221) to T2, and the TDC returns to the wait state (201). 
     Receipt of a CRM event causes the TDC to examine (223) the channel state. If the channel is down, an error is posted (225) and the TDC returns to the wait state (201). If the channel is up, that terminal ID is deleted (227) from the Inbound queue. The terminal ID is added (229) to the Outbound queue and the Outbound queue entry timer is set (231) to T3. Outbound communications to the terminal begin (233), and the TDC returns to the wait state (201). 
     Receipt of an SOM event causes the TDC to examine (235) the channel state. If the channel is down, an error is posted (237) and the TDC returns to the wait state (201). If the channel is up, the Outbound queue entry timer is set (239) to T3, and the TDC returns to the wait state (201 ). 
     Receipt of an LOM event causes the TDC to examine (241) the channel state. If the channel is down, an error is posted (243) and the TDC returns to the wait state (201). If the channel is up, the Outbound queue entry timer is set (245) to T4 and the TDC returns to the wait state (201). 
     Receipt of a TEX event causes the TDC to examine (247) the channel state. If the channel is down, an error is posted (249) and the TDC returns to the wait state (201). If the channel is up, the TDC deletes (251) the terminal ID from the indicated queue. The TDC analyzes (253) the channel queues to see if they indicate sufficient utilization. If the level is achieved, the TDC returns to the wait state (201). Otherwise it releases (255) the channel, marks (257) the channel as down, and the TDC returns to the wait state (201).

Technology Category: 5