Multiplex communications – Generalized orthogonal or special mathematical techniques – Fourier transform
Reexamination Certificate
1998-04-20
2001-09-25
Ton, Dang (Department: 2661)
Multiplex communications
Generalized orthogonal or special mathematical techniques
Fourier transform
C370S203000
Reexamination Certificate
active
06295272
ABSTRACT:
TECHINAL FIELD
The invention pertains to the field of increasing the capacity of local area networks, bidirectional CATV systems or other systems where there is more bandwidth available in the media than is consumed by the communication protocol in use. The invention finds application also in CPU—peripheral interconnections in very large systems which may or may not be distributed by adding an out of band subchannel. Most typically the invention finds useful application in large systems having servers connected to large disk arrays where huge volumes of data must be moved and managed.
BACKGROUND ART
In many large computer systems such as are found in banks, at credit card transaction processing centers, etc., huge amounts of data must be moved and stored. Typically, very large disk arrays are used to store the data and these disk arrays are connected to file servers. These type systems require of the server/disk connection high reliability, high speed, large throughput and large bandwidth since huge amounts of information are being processed and a system shutdown or slowdown adversely impacts customers (and possibly safety in the case of large air traffic control computer systems). Because these systems can be spread out over several buildings or even if all the servers and disk arrays are within the same building, the easiest way to interconnect all the servers and disk drives for maximum redundancy is through a local area network usually with a hub having drop lines connected to all servers, disk drives and other units. Because disks fail frequently and must be replaced by redundant disks, there is a large amount of management and control traffic that must go back and forth over the server/disk array connections and through the hub to the management and control process. This management and control traffic is necessary to determine which disks are on-line, where those disks are on the network, operational disk status, how many fans are still running (because when a fan fails, the disk it cools will probably be next), what servers are still operational, network fault status, network traffic conditions and statistics, etc.
Out of band management topologies get management data to and from the hub easily enough on separate network segments, which has its own set of problems described below. However, getting management and control data to and from the disk arrays in-band is more difficult. The management and control data sits in registers on a board in the disk array. In order to get this low speed, low priority data onto the high speed data path, special circuitry must be built in each disk array which interfaces these registers to the high speed data path. This circuitry functions to collect and format the management and control data into the type of data packets used in the high speed data path and to transmit these packets with the correct communication protocol to the hub. Since the management and control data does not consume an entire packet of the size used to send data on the high speed data path, some packet space is empty and wasted . The need for this special circuitry to put the management and control data in the high speed data path makes the disk arrays more expensive and complex and placing management and control data in the high speed data packets wastes network throughput.
Some disk arrays store the management and control data on a separate disk drive which can be polled. However, this approach does not solve the problem of the need for special circuitry to get the management and control data into packets in the high speed data path and the resulting extra complexity and wasted throughput. It only allows time shifting thereby enabling transmission of the management and control data when network traffic volume is low and the throughput loss is not as significant. This time shifting is implemented by providing more storage capacity for the management and control data than is provided in the registers of the other prior art type disk arrays described above.
In some networks, management traffic is transmitted in-band by placing the management and control packets inside empty data packets and shipping these partially filled packets over the existing network connections between the server, hub and disk drives. This causes loss in throughput since the data packets are large and the management data does rot fill the data packets entirely. This leads to wasted bandwidth. Further, arbitration by the management process to have one or more packets awarded to it for management traffic and to have access to the network so that transmissions to all servers and disk drive arrays of management messages consumes processing resources and network throughput unnecessarily.
One proposal has been made in the prior art to interleave special management and control packets in with the packet stream on the high speed data path to alleviate the above mentioned problem. However, this makes the design of the integrated circuits that implement the processing on the various network protocol layers more complex and difficult. So far this approach has been a commercial failure.
Another approach that has been tried in the prior art for transmission of management and control packets is to provide an entirely separate network for the management and control data such that each server and disk array is connected to the out of band management and control process running on a separate diagnostic processor by its own network segment. This substantially increases the wiring and connection cost of the system, especially in distributed systems, as every server and disk array must have an additional network segment connected thereto. In addition, each server and disk array uses a card slot for the management and control network card which adds to the expense, complexity and failure point count of each of these units.
A multiplexing approach that has been used in the prior art to send multiple television signals over the same media is represented by U.S. Pat. No. 3,623,105. This patent teaches receiving multiple video signals and translating each one to a different channel or subband and adding all the subband signals together to form a composite signal. The composite signal is then applied to the frequency control input of a VCO having a nominal frequency of 750 mHz. The output of the VCO is applied to one input of a pulse width modulator the other input of which receives an 18 gHz carrier. The pulse width modulator serves to key the 18 gHz carrier in accordance with the period of the signal from the VCO so that what is transmitted is a train of 18 gHz waves the width of each wave or “pulse” being set by the instantaneous period of the signal output from the VCO.
Another approach to implement a subchannel or auxiliary channel over a digital communication system is represented by U.S. Pat. No. 4,079,203 to Dragoo. This patent teaches an auxiliary channel implemented on a time division multiplexed carrier system by modulating the pulse repetition rate of the digital bitstream on the transmit side of the transaction. Each transceiver transmit section includes a FIFO shift register acting as a buffer. Modulation of the auxiliary channel data is carried out by varying the rate at which the digital information of the main channel is clocked out of the FIFO shift register at the transmitting end. The modulating signal varies the pulse repetition rate of a voltage controlled multivibrator which has its output coupled to the clock out input of the FIFO shift register and to a phase comparator of a phase lock loop. Data is clocked in using a clock signal derived from the incoming serial data stream. One drawback of this system is that the capacity of the FIFO can be exceeded if the clock out rate falls substantially behind the clock in rate because of the nature of the modulating signal during certain intervals.
Another approach which has been tried in the prior art is represented by U.S. Pat. No. 4,425,642 to Moses et al. This patent teaches sending digital data simultaneously with analog signals over the same media
Black Alistair
Feldman Richard
Falk & Fish
Fish Ronald C.
Gadzoox Networks, Inc.
Pizarro Ricardo N.
Ton Dang
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