HUT58172A - Synchronizing process for wireless systems - Google Patents

Abstract

A distributed synchronization method for a wireless fast packet communication system (100) is disclosed. The distributed synchronization method, according to the invention, provides for the combination of both voice and data in a single switch using a common packet structure. It allows for the dynamic synchronization of packets. This includes not only bandwidth within the voice or data areas of the frame, but also between the voice and data portions.

Description

The present invention relates to a distributed synchronization method for wireless fast packet switching systems, preferably for voice / data packet switches.

In practice, many types of voice and data switches are known. Also known as packet switching elements. In the past, for audio / data packet switches, the control of the switch for transmitting and receiving information packet signals, and for switching between packets, is used. synchronizing these was a serious problem. This problem is primarily due to the dynamic assignment of packet bandwidth between different peripheral systems, i.e., peripherals that have voice or audio bandwidth. data information were connected to the system. Another factor to consider when designing was the switch network interface architecture. The network interface architecture of the previously known switches used the same bus for data transmission and control. If it was supplemented with dynamic bandwidth assignment on the bus, the network interface architecture only enabled the use of a switch with low switching speed and low throughput. This is because the data had to be switched from byte to byte. For packet switches, the processor is a high-performance processor. Transmission problems have become particularly important in modern fast packet protocols. Here, it is first and foremost desirable to have a switch whose advanced architecture enables the transmission of both voice and data packets. The design of such a packet switch into an architecture · · · · ······················

- 3 is the key to properly synchronize packets transmitted between different nodes and user terminals. If this is not implemented properly, it means, for example, a reception coherence, which is the difference between the carrier frequencies, the control signal difference between the control signals, or the control signal. the phase difference is caused by the modulated signal.

The present invention relates to an architecture which can be used in wireless packet switched communication systems. It is an object of the present invention to provide a method for properly synchronizing packet data transmission between various nodes and user terminals in the system.

The invention thus provides a distributed synchronization method for wireless fast packet switched communication systems, wherein the ~ system comprises a master unit for transmitting a frame synchronous packet in each of its frames.

The essence of the method according to the invention is to indicate the frame time in the packet signal at the transmitter, transmit it and measure it by counting the bytes from the first byte of the network interface data area to the first byte following the end of the packet synchronous sequence, subtracting the transmission signaling time at the receiver and comparing this time with the reception time stamp and the reception time stamp with the reception time of the respective packet, adjusting the delay appropriately, determining if there is a significant error, and then determining the network interface data area set it to sync as soon as possible

Μ,

- Make it 4.

The present invention also relates to a distributed synchronized wireless fast packet communication system, wherein each frame has a master unit for transmitting the frame synchronous packet.

The essence of this arrangement is that the synchronization unit comprises at the transmitter a data transmission time frame in each packet, where it calculates data transmission in bytes from the start of the data interface area of the network interface to the first byte after the end of the packet synchronization sequence. includes an element that subtracts the transmission signaling time, an element that compares this time with the receive timestamp, wherein the receive time stamp is proportional to the receive time in a given packet, includes an element configured to set the propagation delay , an element to determine if there is a significant error, and an element to synchronize the network interface in the shortest possible time.

The invention will now be exemplified below. Embodiments thereof are illustrated in more detail in the accompanying drawings.

Figure 1 shows an exemplary embodiment of a wireless fast packet switched communication system according to the present invention, and frames thereof in Figure 2, and voice / fixed within this frame signal in Figure 3.

Figure 5 shows a topology of a typical network in the first embodiment, Figure 6 shows a first synchronization time diagram of the embodiment shown in Figure 1, FIG. 2 is a view showing a second synchronization timing diagram for the embodiment of FIG. 1, and the accompanying Table A shows a program for the synchronization process of the present invention.

1 illustrates an example of a wireless fast packet switched system 100 according to the present invention. A block diagram of an embodiment of the present invention. Figure 1 shows the node 103 and the user terminal 101. It will also be apparent to one skilled in the art that several user terminals 101 could be used, but in Figure 1, for convenience, only one is marked.

Node 103 will now be described in the case where the PSTN transmits the audio signal from the public switched telephone network via the radio frequency channel 111 to the user terminal 101. The input signal from the PSTN public switched telephone network is routed to the terminal 133, which is properly compassed and filtered by a telephone interface 135 and transmitted to a 137 A / D converter where the incoming analogue signals are digitized.

- 6 happen. From there, the signal is carried as audio-signal packets to a storage 139, which is the local storage of a master processor 140, and from there the signal is fed through a FIFO 121 to the local storage 141, which belongs to the slave processor 143. The slave processor 143 forwards the signal packet to the LAN co-processor 145, by means of which it generates the serial data line 149 which is routed to the RF equipment 147. Thus, in practice, the LAN co-processor 145 generates the 149 serial data series. The RF equipment 147 itself includes a receiver, transmitter, and antenna arrangement and generates radio frequency signals which are then transmitted via the antenna 151 to the user terminal 101.

The LAN co-processor software 145 and master processor software 140 are so designed and written to perform the above operations.

Figure 1 also shows a user terminal 101 having an antenna 105 which receives and transmits signals on the radio frequency channel 111 to a telephone 129. The user terminal 101 itself includes an RF device 107 that includes a transmitter, receiver and antenna adapter. The power supply and control signals of this RF device 107 are provided through the connector 109. The RF device 107 transmits the signal received over the channel 111 and received by the antenna 105 as a serial data signal through the data connector 113 to a LAN co-processor 115. LAN co-processor 115 is connected to a slave processor 117 and local memory 119 • ·

7, and the arrangement is configured to convert the signals received by the LAN co-processor 115 into voice packets into the local memory 119. The slave processor 117 then transmits these voice packets via the FIFO repository 121 that belongs to the master processor of the user terminal 101 to the memory of this master processor 123 and then converts the audio signal so that the software in the master processor 125 D / Use the converter. The output of the D / A converter 125 is then routed to the telephone interface 127, which also compands and filters if necessary, and the telephone 127 interface output is connected to the telephone 129. Simultaneously, the ringing and calling of the telephone 129 can be accomplished on the fast packet switched system by storing data in the memory of the master processor 123 and transmitting the ringing signal from the memory 123 via port 131 1/0 to the telephone 127. interface and from here to 129 phones.

The arrangement includes a repeating frame, which is periodically transmitted and includes bidirectional signaling and data packets, the signaling and data packets needed for the proper functioning of the system. Such a signal is shown in Figure 2. Figure 2 illustrates a frame 200 within which audio and data signals are located, respectively. a voice transmission disconnected portion and a data transmission disconnected portion; furthermore, there are a plurality of A-H time slots assigned to the recorded data and voice transmission, which may be transmitted without station collision. Each data area

- 8 is available to the radio at any time, and this section is also used to indicate a potential collision.

Figure 3 shows an example of the voice / recorded data area 300.

4 illustrates the packet data area 400. THE

Figures 3 and 4 are as follows:

SYNC sync signal

DATA data signal

HEADER - header

TRAILER - data end

Each transmission within the frame 200 may be decoded so as to increase the accuracy of the received data. If the original data is repeated several times in the code, the arrival times of the same packets may be different. In this case, the algorithm in the software compensates for different arrival times.

The system allows the spectrum to be used with maximum efficiency by assigning the desired bandwidth to each user on a common communication path. As we mentioned earlier, previously known systems did not assign bandwidth according to need, but bandwidth was already assigned when the system was built. The system according to the invention thus has the advantage of being used as a fast packet switched system and allowing the establishment of circuit and other non-circuit connections using the same system.

Figure 5 illustrates the system according to the invention.

A possible implementation of 9 topological layouts is shown. Several N ^ ... N _n nodes and Tj .. • T _n user terminals are displayed. The Νι · ..Ν _η nodes communicate with each other and the Τι · ..Τ _η terminals through a shared network through a fast packet switching mechanism that controls the packet switching mechanism to prevent collision between different units, between them which are available from this common line of communication.

The basic procedure for implementing frame synchronization between the two NI network interfaces is extremely simple. To begin with, assume that one unit is the master and that it transfers exactly one frame synchronous packet in each frame. This packet must contain a frame time that is transmitted and is given in bytes from the start of the NI network interface data to the first byte of the header, that is, the first byte that is the synchronous sequence (SYNC). follows. The approximate position of this packet in the frame at the receiver must be known in order to meet the requirement of absolute stability at the start of the sequence. In addition, there is one more important requirement, namely, the procedure for using the initial synchronization acquisition to account for interferences that may be caused by the receiver's command signals in the NI network interface controller memory.

The receiver's operation and reaction are also extremely simple. · · · · · · · · · · · · · · · · · · · · · · · · · · · · · ··· ·

- 10 times, because the transmission time described above has to be subtracted and compared with the reception time of the area occupied by the NI network interface, and then the delay has to be set in the storage and communication equipment. For example, if you encounter a major error, you will need to determine the appropriate direction in which the network interface should be shifted to synchronize in the shortest time possible. This match is usually a negative or positive 1/2 frame.

The total error is then divided by a stability factor, such as 16, so that stability can be maintained even when a signal is connected to several other unsynchronized devices. Further checks are made to account for boundaries and to fit across the entire window, as is customary for network interfaces.

Thus, the above arrangement allows the exact conditions required for synchronization to be determined, and determines (relatively slowly) the loss of synchronization. This is done by creating a generic variable insync. This variable decreases by one (lower limit zero) for each frame start signal interrupt, and increases by 16 (upper limit depends on system size, but usually 400) each time the synchronous packet signal is processed and the frame time is adjusted and set there is no need. In this way, each frame synchronization time is precisely determined. If "in-sync" is zero, the system will be out of sync. The above algo9 · • 9 · · · · · «·«

- Table 11 shows the program created with 11 rhythms in mind.

The remaining and necessary issues to achieve proper synchronization are the re-enable command signals that the receiver needs to check if the synchronous packet signal is faulty. The receiver enable command sequence has been designed to enable packet reception only during the packet time. To achieve this, it was necessary to ensure that each frame contained a receiver-enable sequence that contained the following commands:

- everyone can cancel the bus,

- customer authorization,

- antenna selection,

- configure NI Network Interface to be the bus destination,

- Set the radio to be the source of the bus.

If the packet sync flag is wrong, it will reset if it detects an incorrect sequence or if the NI network interface notices that it has processed a data string that is not provided with a valid header, that is, when the header is a CRC checker error.

This problem is shown in Figure 6. The phenomenon itself occurs when the first synchronous packet (SYNC-PACKET) is decoded from the NODE and the clock of the receiver (RECEIVING DEVICE) is faster than the clock of the node. Of course, this is true even if it's half the packet time. When fitting the receiver, the frame • ·

- Slide 12 to the left to move the control sequence (CONTROL SEQUENCE) to the right until the next received synchronous command signal. This packet then disappears and the normal drift shifts the next receiver frame to the right until the control frequency appears after the packet. Then it receives another synchronous packet signal, shifts to the left, and repeats the sequence. As a result of the network, the control sequence is aligned with the synchronous packet rather than the frames in a row.

The solution is simple, the control frequency has to be shifted by exactly half the period of time at which the synchronous packet signal should arrive.

In this case, the first packet may not be received. However, the relative frame time shifts shortly, and virtually no matter what direction the relative position of the receiver moves, the first packet is received by properly moving or adjusting the control sequence and packet relative to each other, since this is definitely the smallest it will move in the direction of change.

If a frame synchronous signal is required, the control sequence will of course be removed and replaced with the respective useful frame signal.

In the event that all frames received a synchronous signal from all devices, each device belonging to the system, each node user terminal and network interface would synchronize to the average clock, which includes its own clock. This setting means • ·

The result is that we can create a timing that is satisfactory in every respect, so that it is possible to have the smallest possible safety interval between the signals provided by each of its elements. For example, if the chain is made up of four nodes, the difference in frame time between the first and last may be 6 bytes, but the average difference depends on the relative frequency of the free running clock of the fourth network interface, and worst case scenario.

A further advantage of the averaging process is that the average difference is kept at zero.

A further feature is the backlog, which always occurs in the event of some error. For example, if the system consists of three nodes and the second node serves the first one, h.TrTiends the second, what happens if the second i fails. If the synchronous control signal has priority, then this malfunction must be indicated, the priority being properly matched if we do not want the system to fall out of sync. However, the averaging system automatically matches each node.

For example, if the clock signals have a frequency of 5 ppm, then the frame size is 3.750 bytes, which means that the maximum offset is x 5 χ 10 ^-6 x 3750 = 0.0375 bytes / frame for two clock signals as far apart as possible (one at the very beginning and the other at the very end), this means that the worst thing to do is to fit a word, and in the above case only all · · · · · · · · · · · · · · · ·

Frame 27 is needed.

There are several known ways of performing initial synchronization of nodes in different large systems. The simplest is probably to specify a priority order and ensure that each node can only transfer if it has already established a connection to one of the units above it. The advantage of this solution is that it is very easy to design, but it requires each node to know which unit is above the system. Here, however, the problem with proper operation is that there is no unit above it. This makes it extremely difficult to report the error.

Alternatively, each node has a frame phase signal and an absolute frame rate signal, the frame size can be varied within wide limits, and there is no need to fix this rate to the system speed as long as each sync signal is received. Properly selected random-numbered frames and phase signals allow the system to be properly initialized as long as the random number generator has different numbers at different nodes to prevent the same operation from starting at the same starting point, in the event of a main power supply failure can occur when you turn it back on. This requirement requires that each unit be assigned an electronic serial number.

If a frame, for example, each node frame sends a synchronous packet signal, in the same domain. This means every node / sector every fourth sync signal. This is a terminal and

and in each frame, frame provides the ability for every 24 frames in the local area network to evaluate only the local antenna selection in the frame, i.e., every 48 ms, and at worst, only means that the frame synchronous timing in each 24 , which is inside, as we have already pointed out, in the 27th frame.

Reducing the frame sync signal packet in this way allows for a much better design of the entire frame, especially the software, since here the change to the fixed data part of the network in-terface storage is only done at the end of the frame. In this way, it may be advantageous to implement node transmissions at the end of the frame, while transmissions between the user interface module and the network interface module at the beginning of the frame, thereby simplifying the timing conditions in the software.

Various embodiments may be provided for distributed, synchronized data transmission in wireless packet switched communication systems of the present invention, but in each case the essence of the invention may be made identical.

Claims (2)

A distributed synchronization method for wireless fast packet switched communication systems, wherein the system comprises a master unit for transmitting a frame synchronous packet in each of its frames, characterized by transmitting and measuring the frame time in the packet signal at the transmitter. calculating in bits the first byte of the data area of the network interface data area to the first byte following the end of the packet synchronous sequence, comparing the time at the receiver with the transmission signal, comparing this time with the reception time stamp and the reception time stamp with that packet's reception time, adjusting the delay properly, determining whether there is a significant error, and adjusting the network interface data area to find the sync signal within the shortest possible time. 2. A distributed synchronized wireless fast packet switched communication system, comprising a master unit for transmitting a frame synchronous packet in each frame, characterized in that the synchronization unit comprises at the transmitter one data transmission frame time indicator in each packet, wherein the data transmission counts in bytes from the start of the data interface area of the network interface to the first byte after the end of the packet synchronous frequency, and contains at the receiver an element that: · ♦ ···· · ············································································································································ · · which is trained to set the propagation delay, an element that can determine if there is a significant error, and an element to synchronize with the network interface in the shortest possible time.