KR20150095596A - Computing system with joint-transmission mechanism and method of operation thereof - Google Patents

Abstract

The present invention relates to a computing system with a joint-transmission mechanism. The computing system of the present invention comprises a communication unit which identifies total communication contents and some of the total communication contents for blind-join transmission with a second device for use of the second device and a third device for transmitting the total communication contents to a first device, generates a first encoding group upon the total communication contents or some of the total communication contents for communicating to the total communication contents upon a second encoding group for the third device, and determining a first procoding mechanism relating to the first encoding group for communicating with the total communication contents having overload transmission mode including a second precoding mechanism for the third device; and an interface between devices connected to the communication unit, and communicating a first transmitter signal based on the first precoding mechanism and the first encoding group for communicating with a second transmitter signal and the first transmitter signal at the same time from the third device.

Description

[0001] COMPUTING SYSTEM WITH JOINT-TRANSMISSION MECHANISM AND METHOD OF OPERATION THEREOF [0002]

The present invention relates to a computing system, and more particularly, to a system having a joint transmission mechanism.

Modern consumer and industrial devices, particularly devices such as cellular phones, navigation systems, portable digital assistants (PDAs), and combination devices, increase the levels of functionality to support modern life, including mobile communications ≪ / RTI > Research and development within existing technologies can be performed in a myriad of different directions.

Increasing demands for information in modern living require users to access information at an arbitrary time, increasing data rates. However, the communication signals used for mobile communications are efficiently experienced by the various types of interferences from a large number of sources, and the complexity of the computer from a plurality of possible formats for information conveyed due to the amount and speed of the accessible data Rise.

Thus, there is still a need for a computing system with a co-transfer mechanism.

A solution to these issues is desirable from the standpoint of ever-increasing commercial competitive pressures, coupled with increased consumer expectations and reduced opportunities for symbolic product differentiation in the marketplace. In addition, the demand for cost reduction, improved efficiency and performance, and the conflicting pressures are becoming more urgent to find solutions to these problems.

The solutions to these problems have long been sought, but the developments did not teach or suggest any solutions previously, and therefore these problems could not be achieved for a long time in the art.

It is an object of the present invention to provide a computing system having a co-transfer mechanism and a method of operation thereof.

It is another object of the present invention to provide a computing system having a cooperative transmission mechanism for transmitting the entire communication content using multiple transmission devices and an operation method thereof.

For the use of the second device and the third device to transmit the entire communication content to the first device according to the present invention, the entire communication content or part of the entire communication content for the blind- And generates a first encoding set according to a portion of the entire communication content or the entire communication content for communicating with the entire communication content along a second encoding set for the third device, A communication unit for determining a first procoding mechanism associated with the first set of encodings for communicating the entire communication content with an overloaded transmission mode comprising a second precoding mechanism and a communication unit coupled to the communication unit, The first encoding set for communicating a second transmitter signal with a first transmitter signal from the device, And an inter-device interface for communicating the first transmitter signal based on the first precoding mechanism.

In this embodiment, the communication unit determines the first precoding mechanism without using the transmitter channel information.

In this embodiment, the communication unit determines the first precoding mechanism according to a portion of the total communication content.

In this embodiment, the communication unit determines the first precoding mechanism based on a total precoding mechanism according to all of the total communication content.

In this embodiment, the communication unit is configured to communicate with the second device based on adjustment via the node link to adjust the second precoding mechanism with the second precoding mechanism intersecting the second device and the third device, 1 precoding mechanism.

In this embodiment, the communication unit determines the blind-joint transmission for communicating the entire communication content to the first device, including the advanced receiver, and the blind- Generates the first encoding set based on a part of the entire communication content according to the second device for communicating with the first encoding set based on the second encoding set, and transmits the first encoding set to the second device The first precoding mechanism for adjusting the first precoding mechanism with the second precoding mechanism for the entire rank transmission mode to be used, the inter-device interface comprising: Based on the first transmitter signal and the second transmitter signal, The first transmitter transmits the signal for communicating with the entire communication with content.

In this embodiment, the communication unit is configured to transmit the first precoding mechanism without using the transmitter channel information based on the rotation pattern of the entire precoding mechanism to represent the first precoding mechanism and the second precoding mechanism .

In this embodiment, the communication unit determines the all-rank transmission mode for the blind-joint transmission for communication of the entire communication content based on the advanced receiver without regard to the receiver capacity of the first device.

In this embodiment, the inter-device interface identifies the entire communication content in all over the node link, and the communication unit is configured to transmit the first set of ciphers from the entire communication content for a transmission slot in accordance with a full precoding mechanism .

In this embodiment, the inter-device interface receives only a portion of the total communication content via a node link, and the communication unit is adapted to perform the entire communication < RTI ID = 0.0 > Generates the first set of encodings based on a portion of the total communication content according to the first precoding mechanism in accordance with a portion of the entire precoding mechanism for communicating the content.

A method of operation of a computing system in accordance with the present invention, the method comprising the steps of: sending the entire communication content for blind-joint transmission with a second device for transmission of the entire communication content to the first device and the second device for use of the third device Generating a first set of encoding based on the entire communication content and a portion of the total communication content to communicate with the entire communication content according to a second set of encoding for the third device; Determining a communication unit of a first precoding mechanism associated with the first set of encoded bits to communicate with the entire communication content having an overloaded transmission mode comprising a second precoding mechanism for the third device, For communicating with the first transmitter signal that is associated with a second transmitter signal from the third device And communicating the first transmitter signal based on the first encoding set and the first precoding mechanism.

In this embodiment, determining the first precoding mechanism comprises determining the first precoding mechanism without using transmitter channel information.

In this embodiment, determining the first precoding mechanism comprises determining the first precoding mechanism according to the portion in the overall communication content.

In this embodiment, determining the first precoding mechanism comprises determining the first precoding mechanism based on a total precoding mechanism along with all of the overall communication content.

In this embodiment, the step of determining the first precoding mechanism may comprise determining a node link for coordinating the first precoding mechanism with the second precoding mechanism across the second device and the third device, Lt; RTI ID = 0.0 > precoding < / RTI >

A non-transitory computer readable medium in accordance with the present invention includes an entire communication content for a blind-cavity having the second device for transmitting the entire communication content to a first device and the second device for using the third device Or a portion of the total communication content and generates a first encoding set according to a portion of the entire communication content or the entire communication content for communicating with the entire communication content according to a second encoding set for the third device Determining a first precoding mechanism associated with the first set of encodings for communicating the entire communication content with an overload transmission mode comprising a second precoding mechanism for the third device, For transmitting the first transmitter signal with a second transmitter signal Based on the bit of the first pre-encoding mechanism comprises instructions for the computing system to communicate with the first transmitter signal.

In this embodiment, determining the first precoding mechanism comprises determining the first precoding mechanism without using transmitter channel information.

In this embodiment, the determination of the first precoding mechanism comprises determining the first precoding mechanism according to the portion in the overall communication content.

In this embodiment, the determination of the first precoding mechanism determines the first precoding mechanism based on a total precoding mechanism along with all of the overall communication content.

In this embodiment, the determination of the first precoding mechanism may be performed by adjusting the second precoding mechanism across the second device and the third device, along with the node link to adjust the first precoding mechanism Lt; RTI ID = 0.0 > precoding < / RTI >

The present invention proposes a computing system having a cooperative transmission mechanism for transmitting all communication content using multiple transmission devices, thereby increasing the amount and speed of data transmitted at the same time, thereby providing increased efficiency and resource management .

BRIEF DESCRIPTION OF THE DRAWINGS Figure 1 is a diagram of a computing system with a co-transport mechanism in accordance with an embodiment of the present invention;
2 is an exemplary illustration of a configuration of a computing system,
3 is an exemplary illustration of a precoding procedure,
4 is an exemplary illustration of a block diagram of a computing system,
5 is an exemplary illustration of another block diagram of a computing system,
Figure 6 shows a control flow of a computing system; and
7 is a flow chart of a method of operating a computing system in another embodiment of the present invention.

The following embodiments may be used in the implementation of blind common transmission for use of multiple transmitters for transmission to a receiving device. The blind joint transmission may be implemented using a first precoding mechanism and a second precoding mechanism that include full precoding or its unique and non-overlapping portions based on the rotation pattern without transmitter channel information. The blind joint transmission may further utilize an advanced receiver at the receiving device.

The blind joint transmission can transmit the entire communication content using multiple transmission devices without considering the receiver capacity. The blind joint transmission can communicate using the overload transmission mode and includes the full rank transmission mode.

The following embodiments are described in sufficient detail to enable those skilled in the art to make and use the described embodiments. It is to be understood that other embodiments may be apparent on the basis of the presently disclosed embodiments, and that systems, processes, or mechanical changes may be made without departing from the scope of the embodiments.

In the following detailed description, numerous specific details are given by way of illustration and are provided by way of illustration of the invention. However, it will be understood that the invention can be practiced without these specific details. In order to avoid ambiguities in embodiments of the present invention, some well known circuits, system configurations, and process steps are not described in detail.

It is to be understood that the system embodiments shown in the drawings are illustrated in a limited manner and are not limited in scale, and some of the dimensions may be exaggerated within the figures to particularly clarify the invention. Similarly, although the views in the drawings generally show similar directions for convenience of description, the description in this drawing is arbitrarily set in most parts. In general, the present invention can operate in any direction. The embodiments of the present invention are given in the same order as the first embodiment and the second embodiment in a manner of convenience of explanation, and these embodiments are not regarded as providing any limitation or practice of the invention.

The term "module" may include software, hardware, or a combination thereof in an embodiment of the invention in which the context is used. For example, the software may include machine code, firmware, embedded code, and application software. Also, for example, the hardware may include circuitry, processors, computers, integrated circuits, integrated circuit cores, pressure sensors, inertial sensors, microelectromechanical systems (MEMS), passive devices, .

As used herein, the term "processing ", as used herein, refers to data such as signal conditioning, filtering, detection, decoding, assembly of data structures, transmission of data structures, adjustment of data structures, Lt; / RTI > The data structures may be defined as information defined by symbols, packets, blocks, files, input data, system generated data, computed or generated data, and program data.

1 is a diagram of a computing system with a co-transport mechanism in accordance with an embodiment of the present invention.

Referring to FIG. 1, a computing system 100 includes a first device 102, such as a cellular phone, or a mobile device, including a notebook computer, connected to a network 104. The first device 102 may further include a wired device such as a modem or a router. The first device 102 may further include an integrated in-circuit circuit or device as a part or circuit that professionally handles the storage device or information in the system. The first device 102 may include a user equipment (UE).

The network 104 is a system of wired or wireless communication devices or means that are connected to one another to perform communications between the devices. For example, the network 104 may comprise a combination of wires, transmitters, receivers, antennas, towers, stations, repeaters, telephone networks, servers, or client devices for a wireless cellular network . The network 104 may include routers, cables, computers, servers, and client devices for various sized area networks. Also, for example, the network 104 may include a communication bus, a wired line, a cable, a wireless connection, or a combination thereof, between units within the equipment.

The computing system 100 may include a second device 106, a third device 108, or a combination thereof, for direct and / or indirect linking and communication with the first device 102. The network 104 may include or couple the second device 106, the third device 108, or a combination thereof. The second device 106, the third device 108, or a combination thereof may receive radio signals from the first device 102, transmit signals to the first device 102, process the signals, or combinations thereof can do. The second device 106, the third device 108, or a combination thereof can relay (or relay) signals between other base stations, components within the network 104, or combinations thereof have.

The first device 102 may be connected to the network 104 via a second device 106, a third device 108, or a combination thereof. For example, the second device 106, the third device 108, or a combination thereof may be a computing system 100, a base station, an envolved Node B (eNodeB), a server, a router, , Or a combination or combination thereof. For example, the second device 106, the third device 108, or a combination thereof may be controlled, managed, or otherwise configured for various devices within the computing system 100, actions, tasks, or a combination thereof, for scheduling the scheduling of tasks.

Also, for example, the second device 106, the third device 108, or a combination thereof may transmit signals to or receive signals from the first device 102, including a mobile computing device, A cellular tower, a wireless router, an antenna, or a combination or combination thereof that can be used for communication by means of reception of signals. Also for example, the second device 106, the third device 108, and combinations thereof may include a portion or circuitry that professionally handles information stored in the storage device or system.

The first device 102 may communicate and be connected to other devices, such as other mobile devices, servers, computers, phones, or a combination thereof. For example, the first device 102 may display the content of signals, such as transmitting signals, receiving signals, processing signals, or a combination thereof, storing applications or operating systems, And can communicate with other devices by reproducing them, processing them according to their content, or a combination thereof, so that they can hear sounds.

The second device 106 can be used to wirelessly exchange signals for communication and includes voice or web pages of the phone call and data indicative of interaction therewith. The second device 106 may transmit reference signals, training signals, error detection signals, error correction signals, header information, transmission format, protocol information, or a combination thereof.

(CDMA), Orthogonal Frequency Division Multiple Access (OFDMA), Third Generation Partnership Project (3GPP), Long Term Evolution (LTE) ), And fourth generation (4G) standards, the signals may include a reference portion, a header portion, a format portion, an error correction or detection portion, or a combination thereof embedded in the information to be communicated . The reference portion, the header portion, the format portion, the error correction or detection portion, or a combination thereof may comprise predetermined bits, pulses, waveforms, symbols or a combination thereof.

For purposes of illustration, the computing system 100 will be described as a communication system having a first device 102 as a user device, such as a mobile device, and a second device 106 as a base station or coordinating device. However, it is contemplated that the communication system 100 may include a first device for processing a portion of a disk drive or device that focuses on processing within the memory system, and a second device for processing a portion of a disk drive or device that focuses on storage within the memory system But may be different from a memory system having a second device.

The computing system 100 may further include a node link 112. Node link 112 may comprise a method, process, or mechanism for information communicating directly between node devices or access points.

For example, the node link 112 may comprise a coordinating device for managing the second device 106, the third device 108, or a combination thereof. For example, the node link 112 may be a wired or wireless communication channel or connection between the second device 106 and the third device 108, a method for further processing the exchanged information, the communication protocol, Or a process, or a combination thereof. In more detail, the node link 112 may include a back-haul channel for communication between base stations.

The computing system 100 may utilize the blind joint transmission 110 to communicate information between the devices. The blind common transmission 110 is a mode or format for communication using multiple sources for transmitting information to a single receiving device without the use of global information considered between channels. The computing system 100 may use the node link 112 to adjust or control the blind cavity transmission 110 with multiple transmission devices such as the second device 106 and the third device 107. [

For example, the computing system 100 may communicate with the second device 106, the third device 108, the base station 108, and the base station 110 to transmit the entire communication content 114 to the first device 102 for the blind shared transmission 110. [ Or a further example of a regulating device, or a combination thereof. The entire communication content 114 may include information made for communication to a receiving device so that it can be reproduced and executed at the receiving device.

Continuing, for example, the computing system 100 may be configured to communicate with multiple devices (such as a second device 106, a third device 108, another example of a user equipment (UE), or a combination thereof) 106, or a third device 108, to distribute the entire communication content 114. As a more detailed example, the computing system 100 may determine applicable transmitters according to the first device 102 and may distribute the entire communication content 114 to each example of applicable transmitters.

As a further example, the computing system 100 may distribute unique or non-overlapping portions of the entire communication content 114 with each example of applicable transmitters according to the first device 102. As a more detailed example, the computing system 100 may distribute a first transmission content 116, which may include all or a portion of the entire communication content 114, to a second device 106, ) To the third device 108, or a combination thereof, to the third device 108. The third device 108 may be a wireless device. The first transmission content 116 and the second transmission content 118 may not overlap or only partially comprise the entire communication content 114, respectively.

Continuing, for example, the computing system 100 may use multiple examples of transmitting devices to communicate with the entire communication content 114 to the first device 102 for blind common transmission 110. As a more detailed example, the computing system 100 may use the second device 106 and the third device 108 to simultaneously transmit the only portions of the entire communication content 114 to the first device 102 .

The computing system 100 may encode the content to transmit the content. The computing system 100 may encode the content by encoding the entire communication content 114. The computing system 100 may encode the entire communication content 114 to execute an error correction process, an error detection process, or a combination thereof to communicate information between the devices.

The computing system 100 may generate the entire encoded message 120 by encoding the entire communication content 114. [ The entire encoding message 120 may include the entire communication content 114 encoded according to a coding mechanism such as a polar coding scheme or a turbo coding scheme.

The computing system 100 may generate the entire encoded message 120 in various manners. For example, the computing system 100 may use one or more transmission devices to generate the entire encoded message 120, respectively. Also, for example, the computing system 100 may generate a full encoded message 120 that crosses multiple devices.

As a more specific example, the first device 102, the second device 106, and the third device 108, or a combination thereof, that transmit the entire encoded message 120, or a portion thereof, The first transmission content 116 and the second transmission content 118 may be respectively generated by the first transmission content 116 and the second transmission content 118, respectively. As a more specific example, the second device 106, the third device 108, or a combination thereof may include a first transmission content 116, each containing only non-overlapping portions of the entire communication content 114, 2 transported content 118, respectively.

The second device 106, the third device 108, or a combination thereof may be implemented by a first encoding set 122 by encoding the first transport content 116, a second encoding content 122 by encoding the second transport content 118, 2 encoding set 124, or a combination thereof. The first encoding set 122 and the second encoding set 124 may include information for transmission using multiple devices, multiple antennas, or a combination thereof.

The first transmission content 116, the second transmission content 118, or a combination thereof may follow the entire encoding message 120. [ The entire encoded message 120 may include a first transmitted content 116, a second transmitted content 118, or a combination thereof.

The entire code message 120 includes a first code word 126, a second code word 128, a third code word 130, and a fourth code word 132, . ≪ / RTI > The first codeword 126, the second codeword 128, the third codeword 130 and the fourth codeword 132 may each comprise an element or unit of a standardized code or protocol.

Subsequently, for example, the first codeword 126, the second codeword 128, the third codeword 130, and the fourth codeword 132 may be included in the entire encoded message 120 Element or a unique instance of a unit. The first and second sets of codewords 122 and 124 may include a first codeword 126, a second codeword 128, a third codeword 130, a fourth codeword 132, As shown in FIG.

As a more detailed example, the second device 106 may include a first code word 126 in accordance with the encoding of the entire communication content 114, or the first transmission content 116 thereof or the second transmission content 118, 2 code word 128, a third code word 130, a fourth code word 132, or a combination thereof. Also as a further specific example, the third device 108 may include a first codeword 126 in accordance with the encoding of the entire communication content 114, or the first transmission content 116 thereof or the second transmission content 118, A second code word 128, a third code word 130, a fourth code word 132, or a combination thereof.

For specific purposes, the computing system 100 may be configured to describe a second device 106 and a third device 108 that respectively generate an entire encoded message 120, or a first codeword 120 according to a first set of codewords 122, A third device 108 for generating a third codeword 130 and a fourth codeword 132 according to a second encoding set 124 and a second device for generating a second codeword 128 and a second codeword 128, ). However, it can be understood that the encoding of the content is distributed across the devices in a variety of ways.

For example, the second device 106 may generate the second encoding set 124, and the third device 108 may generate the first encoding set 122. Also, for example, the second device 106 and the third device 108 may communicate with the first codeword 126, the second codeword 128, the third codeword 130, or the fourth codeword 132 ). ≪ / RTI >

The computing system 100 may further process the encoding results for processing. For example, the computing system 100 may generate symbols according to the entire communication content 114 or portions thereof. The computing system 100 may generate symbols according to a constellation, a modulation scheme, such as Quadrature Amplitude Modulation (QAM), Phase Shift Keying (PSK) Can be generated.

Also, for example, the computing system 100 may utilize a precoding process in the transmission of content. The computing system 100 may utilize a precoding process to utilize the transmit diversity of multiple sources, antennas, or a combination thereof for transmission to the intended receiver.

The computing system 100 may utilize a precoding process associated with (or following) a source, an antenna, transmitted data, channel information, or a combination thereof. The entire precoding mechanism 134 may include factors, control parameters, processes, or methods, assignments, sequences, or combinations thereof associated with them to utilize transmit diversity to communicate the entire communications content 114 .

For example, the entire precoding mechanism 134 may include a precoding matrix. The entire precoding mechanism 134 may include batches, timings, sequences, or a combination thereof for specific examples of units or portions within the overall communication content 114. [ For a more detailed example, the entire precoding mechanism 134 may be transmitted from a second device 106, a third device 108, or a particular antenna thereof, for a particular transmission slot or opportunity, a sequence thereof, A first codeword 126, a second codeword 128, a third codeword 130, or a fourth codeword 132 for transmission, or a combination thereof.

The computing system 100 may further utilize the first precoding mechanism 136 and the second precoding mechanism 138 in the precoding process. The first precoding mechanism 136 and the second precoding mechanism 138 may each include an entire precoding mechanism 134, unique non-overlapping portions thereof, or a combination thereof. The first precoding mechanism 136 and the second precoding mechanism 138 may comprise a factor, a control parameter, a process, or a related method, arrangement, sequence or combination thereof associated with a transmitter, . ≪ / RTI >

For example, the first precoding mechanism 136, the second precoding mechanism 138, or a combination thereof may follow the second device 106, the third device 108, or a combination thereof. As a more detailed example, the first precoding mechanism 136 may follow the second device 106 and the second precoding mechanism 138 may follow the third device 108.

Also, for example, the first precoding mechanism 136, the second precoding mechanism 138, or a combination thereof may be implemented as a first transmission content 116, a second transmission content 118, The entire communication content 114, or a portion thereof. As a more detailed example, the first precoding mechanism 136 may follow the first transmitted content 116 and the second precoding mechanism 138 may follow the second transmitted content 118.

The computing system 100 may send the entire encoded message 120 to the intended device. Computing system 100 may utilize multi-demultiplexed devices for transmission to full encoding message 120 to utilize a co-transmission comprising blind common transmission 110. For example, the computing system 100 may include a second device 106, a third device 108, or a combination thereof for transmission of a first transmitter signal 140, a second transmitter signal 142, Can be used.

The first transmitter signal 140 may comprise actual signals or information transmitted in one example of a transmitting device for co-transmission of content. The second transmitter signal 142 may comprise actual signals or information transmitted in another example of a transmitting device for co-transmission of content. The first transmitter signal 140 is transmitted continuously and is transmitted simultaneously with the second transmitter signal 142.

For example, the first transmitter signal 140 may include the actual signal or information transmitted by the second device 106, and the second transmitter signal 142 may include the first transmitter signal 140, 3 device 106. In one embodiment, Also for example, the first transmitter signal 140 may follow a first encoding set 124, and the second transmitter signal 142 may follow a second encoding set 124. The first transmitter signal 140, the second transmitter signal 142, or a combination thereof may comprise further processed information from an encoded output such as based on a modulation scheme, a precoding scheme, or a combination thereof.

The transmitted signals may traverse communication channels between devices such as a transmitting device and a receiving device. The communication channel may include a direct link between the first device 102 and the second device 106, or depending on devices such as between the first device 102 and the third device 108. The communication channel may comprise repeaters, amplifiers, or a combination thereof, between them for an indirect link.

The communication channel may include specific examples or values of communication details such as frequency, time slot, packet designation, transmission rate, channel code, or a combination thereof used for transmission signals between intended devices. The communication channel further includes structures or influences such as fading characteristics of the signals, the cause of the unique delay or reflection of the signals. The communication channels may be distorted and altered by signals traversing them.

The communication channel may include a first transmission channel 144 and a second transmission channel 146. The first communication channel 144 may include a communication channel between the first device 102 and the second device 106. The second communication channel 146 may include a communication channel between the first device 102 and the third device 108.

For example, the first communication channel 144 may include a first communication channel 116, a first coding set 122, a first precoding mechanism 136, a first transmitter signal 140, . For example, the second transmission channel 146 may include a second communication content 118, a second encoding set 124, a second precoding mechanism 138, a second transmitter signal 142, and combinations thereof. You can follow. For example, the first transmission channel 144 and the second transmission channel 146 may follow the entire communication content 114, the entire encoding message 120, the entire precoding mechanism 134, and combinations thereof .

The computing system 100 may communicate with the entire communication content 114 using the full rank transmission mode 148. [ The full rank transmission mode 148 is a configuration or set of methods, methods, or processes, or a combination thereof, that utilizes available or applicable resources in the signals to be transmitted to the device.

For example, the all-rank transmission mode 148 may be enabled by a second device 108, a third device 108, any additional applicable user equipment (UE), or a base station to transmit a signal to an intended receiver And may include the use of all such applicable transmitting devices. Also, for example, the full rank transmission mode 148 may include any of the second device 106, the third device 108, any additional applicable user equipment or base station for communicating the entire communication content 114, ≪ RTI ID = 0.0 > and / or < / RTI >

The computing system 100 may use an advanced receiver 150 for communicating information. The advanced receiver 150 is a device that includes a capacity for processing information that exceeds the physical receiving configuration of the device.

The advanced receiver 150 may include a device or portion thereof that is capable of processing the received signal 152 in accordance with information exceeding the receiver capacity 154. For example, the advanced receiver 152 may receive, detect, decode, or decode the received signal 152 for a receiver signal 152 in accordance with transmission signals associated with a transmission capacity 156 equal to or exceeding the receiver capacity 154. For example, Combination can be done. Also, for example, the advanced receiver 150 may include an interference-aware receiver.

The receiver signal 152 may comprise actual information available at the receiving device. For example, the receiver signal 152 may include an energy level accessed by the first device 102. [ For example, the receiver signal 152 may include a first transmitter signal 140, a second transmitter signal 142, or a combination thereof from a second device 106, a third device 108, And < RTI ID = 0.0 > a < / RTI > Also, for example, the receiver signal 152 may include in-signal distortions and degradation from a communication channel, noise, or error components, or a combination thereof.

The receiver capacity 154 may comprise a number of sources or portions within a receiver device that are available for receiving communication information. For example, the receiver capacity 154 may comprise the number of antennas, ports, or combinations thereof in the first device 102. [ Transmission capacity 156 may comprise a number of sources or portions within a transmission device available for transmitting communication information. For example, the transmission capacity 156 may include the number of antennas, ports, or combinations thereof in the second device 106, the third device 108, or a combination thereof.

The receiving device may process the receiver signal 152 for channel estimation 158 calculations. The channel estimate 158 may be a description or characteristic of an environment or connection between the devices exchanging information. The channel estimate 158 may include characteristics of a communication channel.

The channel estimate 158 may be represented or characterized as fading, distortions, or attenuations from delayed signals or echoes, or combinations thereof, for a communication channel. The channel estimate 158 may further quantize or quantify attenuation, loss, variation, distortion, variation, or a combination thereof within the signal caused by the intersection of the communication channels.

For example, the channel estimate 158 may describe or estimate changes in the first transmitter signal 140, the second transmitter signal 142, or a combination thereof. Also for example, the channel estimate 158 may be described or characterized by a first transmission channel 144, a second transmission channel 146, or a combination thereof.

More specifically, the channel estimate 158 may include a matrix that sets a value that indicates a change in the original transmitted signal observed at the receiving device since crossing the provided channel. As a more detailed example, the channel estimate 158 may include a channel quality indicator (CQI), a channel state information (CSI), a precoding matrix index (PMI) Combinations thereof.

The computing system 100 may operate with or without transmitter channel information 160 from a receiving device. The transmitter channel information 160 may be information or knowledge of the communication channel for the transmitting device.

For example, the transmitter channel information 160 may include predictions about communication channels that are calculated by the second device 106, the third device 108, or a combination thereof. For example, the transmitter channel information 160 may include feedback information from a receiving device, such as a channel estimate 158, based on or in combination with CQI, CSI, PMI, or a combination thereof.

As a more detailed example, the transmitter channel information 160 may include a channel estimate 158, channel state information at the transmitter (CSIT), global channel information, or a combination thereof. Also, as a more detailed example, the computing system 100 may communicate with the entire communication content 114 without the use of transmitter channel information 160 for open loop communication. Here, the receiving apparatus does not provide feedback information including information on the communication channel for returning to the transmitting apparatus.

The computing system 100 may communicate the entire communication content 114 using blind common transmission 110. The computing system 100 may communicate the entire communication content 114 without the use of channel estimation 158, transmitter channel information 160, such as the entire precoding mechanism 134 that may be generated without the use of CQI, CSI, or PMI. Communication can be performed. The computing system 100 may further communicate with the overload transmission mode 162 to the full rank transmission mode 148 using the advanced receiver 150. [

Overloaded transmission mode 162 may comprise a configuration or a method, method or process that uses transmission resources that exceed received resources, or a combination thereof. The overload transmission mode 162 may include the use of a transmission capacity 156 that is greater than or equal to the reception capacity. For example, the overload transmission mode 162 may include the use of multiple transmitters, multiple transmit antennas, or a combination thereof over multiple receive antennas.

As a more detailed example, the computing system 100 may be used for transmission from multiple antennas for a receiver including one receive antenna, as is typically intended for a single input single output (SISO) can do. As a more detailed example, the computing system 100 is for a Multiple Input Multiple Output (MIMO) communication format and may additionally utilize four examples of transmission sources for a receiver including two receive antennas simultaneously.

The overload transmission mode 162 may be limited to the full rank transmission mode 148. [ The computing system 100 may utilize an overloaded transmission mode 162 or a full rank communication mode 148 that does not consider the receiver capacity 154 for the advanced receiver 150. [ A detailed description of the communication of the entire encoded message 120 for the blind common transmission 110 will be described in detail below.

For purposes of illustration, the computing system 100 describes a second device 106 and a third device 108 that transmit information to the first device 102. However, it is understood as information that can be transmitted from any device in the computing system 100 or to any device. For example, the first device 102, the second device 106, the third device 108, or a combination thereof may be configured to transmit the entire communication content 114, receive the entire communication content 114, . ≪ / RTI >

Also for purposes of illustration, the computing system 100 describes the use of wireless communication. However, it is understood that the processors described herein may be used for wired communications.

Also for purposes of illustration, the computing system 100 describes two base stations for transmitting information. It is understood, however, that the computing system 100 may use the user equipment to transfer information to other user equipment. It is to be appreciated that the computing system 100 may utilize three or more sources to transmit information.

Also for purposes of illustration, the computing system 100 describes an open loop system in which there is no feedback information for a communication channel. It is understood, however, that the computing system 100 may include a closed loop system, channel feedback information communicated between devices, or a combination thereof.

2 is a diagram illustrating an exemplary configuration of a computing system.

Referring to FIG. 2, computing system 100 may include an antenna 202. The antenna 202 may comprise instruments or structures for radiated or received radio waves. The antenna 202 may be a specialized metal or conductive device for responding to electromagnetic energy or changes therein. The first device 102, the second device 106, the third device 108, or a combination thereof may include an antenna 202.

For example, the first device 102 may comprise a collection of antennas 202 according to the receiver capacity 154 of FIG. For example, the second device 106 and the third device 108 may each include a set of antennas 202 according to the transmission capacity 156 of FIG. 1, respectively. As a more specific example, the first device 102, the second device 106, and the third device 108 may each include two instances of the antenna 202.

The computing system 100 may communicate using the settings of the data layers 204. Each of the data layers 204 may represent a stream of unique communications. The data layers 204 may represent a set of information, either singly or in combination. Each of the data layers 204 may be subject to a unique combination or pairing between the transmit and receive antennas.

The computing system 100 may include a layer count 206 that indicates the amount of data layers 204. Layer count 206 may be based on transmission capacity 156 without regard to receiver capacity 154 for computing system 100 using blind common transmission 110 to communicate with advanced receiver 150 of FIG. have.

For example, the layer count 206 may be greater than the receiver capacity 154 for the overloaded transmission mode 162 of FIG. For example, the layer count 206 may be the same as the transmission capacity 156 for the entire rank transmission mode 148 of FIG. 1 without regard to the receiver capacity 154.

3 is a diagram illustrating an example of a precoding procedure.

Referring to FIG. 3, the computing system 100 of FIG. 1 may utilize a precoding process to transfer the content. The computing system 100 includes a precoding mechanism 134, a first precoding mechanism 136, a second precoding mechanism 138, and a second precoding mechanism 136 for allocation of specific data transmitted from a particular device, a specific antenna, Or a combination thereof.

For example, the computing system 100 may utilize a full precoding mechanism 134 that includes a first transmission portion 302 and a second transmission portion 304. The first transmission portion 302 and the second transmission portion 304 may comprise unique and non-overlapping portions of each full precoding mechanism 134 according to the unique transmission equipment.

As a more detailed example, the first transmission portion 302 includes a first transmission content 116 of FIG. 1, which includes or represents the first transmitter signal 140 of FIG. 1, the entire communication content 114 of FIG. 1, Or a combination thereof. 1, which includes or represents the entirety of the third device 108 of FIG. 1, the second transmitter signal 142 of FIG. 1, and the entire communication content 114, as a more detailed example, The second transmitted content 118, or a combination thereof.

The precoding process, including the first transmission portion 302 and the second transmission portion 304, may correspond to a first direction sequence 306, a second direction sequence 308, or a combination thereof. The first direction sequence 306 and the second direction sequence 308 may each include factors, control parameters, processes or methods associated therewith, their alignment or certain associations, unique and orthogonal directions or dimensions Or an arrangement of combinations or combinations thereof.

For example, the first direction sequence 306 may represent a sequence of codewords scheduled to be transmitted from a particular instance of the antenna 202 of FIG. 2 in the computing system 100. The first direction sequence 306 exemplifies a column in FIG.

For example, the second direction sequence 308 may comprise a set of codewords scheduled to be transmitted simultaneously in time or slots across all instances of the antenna 202 within the computing system 110 for communication to a particular receiver . The second direction sequence 308 may represent a set of codewords scheduled to be transmitted for the second device 106, the third device 108, or a combination thereof. The second direction sequence 308 is illustrated as a row in FIG.

As a more specific example, the entire precoding mechanism 134 may be implemented as each instance of a first direction sequence 306 according to a unique instance of antenna 202, including a first antenna slot 310, a second antenna slot 312, A third antenna slot 314, and a fourth antenna slot 316. The first antenna slot 310 and the second antenna slot 312 may correspond to instances of the antenna 202 on the second device 106. The first antenna slot 310 and the second antenna slot 312 may further correspond to the first transmission portion 302.

Subsequently, for example, the third antenna slot 314 and the fourth antenna slot 316 may correspond to instances of the antenna 202 on the third device 108. The third antenna slot 314 and the fourth antenna slot 316 may further correspond to the second transmission portion 304.

Continuing, for example, the entire precoding mechanism 134 may transmit the first transmission slot 318, the second transmission slot 320, and the second transmission slot 318 to each instance of the second direction sequence 308 according to a particular transmission time or opportunity in the schedule, A third transmission slot 322, and a fourth transmission slot 324. The first transmission slot 318, the second transmission slot 320, the third transmission slot 322, and the fourth transmission slot 324 may be all or part of a whole, such as a codeword scheduled to be transmitted from each of the antennas in time or instance. Respectively, as part of the precoding mechanism 134.

Continuing, for example, the computing system 100 determines the first precoding mechanism 136 as the first transmission portion 302 and determines the second precoding mechanism 138 as the second transmission portion 304 . The computing system 100 may communicate with the entire communication content 114 from each of its antennas designated for communicating with the first device 102 or each of the second device 106 and third device 108, A first precoding mechanism 136 and a second precoding mechanism 138 may be used to transmit the entire frame.

Continuing, for example, the computing system 100 may distribute or communicate all of the entire communication content 114 to each transmission device. As a more detailed example, the computing system 100 may distribute or communicate the entire communication content 114 to each of the transmission devices, such as the second device 106 and the third device 108. Each of the transmission devices includes a first codeword 12, a second codeword 128, a third codeword 128 (FIG. 1) for the first encoding set 122 and the second encoding set 124 of FIG. 1, 130), and a fourth code word (132).

Further, as a more specific example, the communication system 100 may determine the first precoding mechanism 138 and the second precoding mechanism 138, respectively, as the entire communication content 114 or portions of the encoded information accordingly. The first precoding mechanism 136 is illustrated in FIG. 3 to include a first antenna slot 310 and a second antenna slot 312. The second precoding mechanism 138 is illustrated in FIG. 3 to include a third antenna slot 314 and a fourth antenna slot 316.

Subsequently, for example, the first precoding mechanism 136 may schedule the first codeword 126 and the second codeword 128 without the third codeword 130 and the fourth codeword 132 have. The second precoding mechanism 138 may schedule the third codeword 130 and the fourth codeword 132 without the first codeword 126 and the second codeword 128. [

Continuing, for example, the computing system 100 may receive a portion of the entire communication content 114 from each of the second device 106 and the third device 108, a portion thereof designated to communicate with the first device 102, A first precoding mechanism 136 and a second precoding mechanism 138 may be used to transmit each of the antennas, or a combination thereof.

Continuing, for example, the computing system 100 may distribute and communicate only portions of the entire communication content 114 with each of the transmission devices, such as the second device 106 and the third device 108. [ As a more specific example, the computing system 100 may distribute and communicate a single portion of the entire communication content 114 to each of the transmitting devices, such as the second device 106 and the third device 108. [ The second device 106 generates a first codeword 126 and a second codeword 128 without a third codeword 130 and a fourth codeword 132 for the first set of codewords 122 . The third device 108 generates a third codeword 130 and a fourth codeword 132 without a first codeword 126 and a second codeword 128 for the second encoding set 124 .

The computing system 100 may utilize a rotation pattern 326, a parallel orthogonal pattern 328, or a combination thereof for the precoding process. The rotation pattern 326 is a design or arrangement that includes repetitive combinations for crossing multiple transmission points. The rotation pattern 326 is generated by the second device 106 and the third device 108 which cross the multiple antennas corresponding to the second device 106, the third device 108, To distribute the transmission of the entire communication content 114 evenly across multiple devices.

3, for a first transmit slot 318 of the entire precoding mechanism 134, a first code word 126 may be scheduled for a first antenna slot 310, The word 128 may be scheduled for the second antenna slot 312 and the third codeword 130 may be scheduled for the third antenna slot 314 and the fourth codeword 132 may be scheduled for the second antenna slot 312, 4 < / RTI > antennas slot 316. FIG. The rotation pattern 326 may increase antenna assignments with wrap-around or circular buffers to schedule codewords for each of the following transmission slots.

Subsequently, for example, a second transmission slot 320, a third code word 132 may be scheduled for slot 310, for a first antenna, and a first code word 126 may be scheduled for slot 310, The second codeword 128 may be scheduled for the third antenna slot 314 and the third codeword 130 may be scheduled for the fourth antenna slot 316, . The codewords may similarly increase in the horizontal direction for the third transmission slot 322 and the fourth transmission slot 324, as an example of FIG. 3 for the rotation pattern 326. [

Continuing, for example, the rotation pattern 326 may include a parallel orthogonal pattern 328 for each instance of the codeword. The parallel orthogonal patterns 328 may represent horizontal movement or traversal within an assigned antenna crossing the available antennas on multiple transmission slots. The parallel orthogonal pattern 328 is designed to have the same horizontal motion or traversal in the same increment and same direction for all portions of the entire encoding message 120 of FIG. 1, such as for all codewords in the entire encoding message 120 More.

The rotation pattern 326 may further include an alternating orthogonal pattern 330. The cross orthogonal pattern 330 may represent a crossing pattern of horizontal movements or movements in the antenna arrangement across repeating available antennas on multiple transmission slots. The cross orthogonal pattern 330 may indicate horizontal movement or movement within the antenna assignment, such as repeating directions or increments after a predetermined number of transmission slots, and intra-horizontal shifts. The cross orthogonal pattern 330 shown in the second precoding mechanism 138 for FIGURE 3 is a cross orthogonal pattern for other portions of the overall encoded message 120 such as for all codewords in the overall encoded message 120. [ And may provide intersecting diagonal movement patterns.

For illustrative purposes, the rotation pattern 326 may be described as orthogonal patterns that intersect the antenna placement on the transmission slots. However, the rotation pattern 326 may be any regular pattern for evenly distributing transmission of each of a portion of the total communication content 114 crossing all available transmission points, such as its instruments or antennas .

As a more detailed example, the rotation pattern 326 may include a full precoding mechanism 134, a first precoding mechanism 136, and a second precoding mechanism 132 to transmit a unique instance of a codeword from each of the available antennas, A second precoding mechanism 138, or a combination thereof. As a more detailed example, the rotation pattern 326 includes a full precoding mechanism 134, a first precoding mechanism 136, and a second precoding mechanism 136 for transmission of all codewords from each of the available antennas using unique factors for each codeword, , The second precoding mechanism 138, or a combination thereof.

The first antenna slot 310, the second antenna slot 312, the third antenna slot 314, the fourth antenna slot 316, or a combination thereof may be a first codeword 126, a second codeword 128, a third code word 130, a fourth code word 132, or a combination thereof. Each of the codewords may be combined into a unique factor described by a full precoding mechanism 134, a first precoding mechanism 136, a second precoding mechanism 138, or a combination thereof.

Subsequently, a set of unique factors described by, for example, a total precoding mechanism 134 for each of the codewords, a first precoding mechanism 136, a second precoding mechanism 138, or a combination thereof Or the sequence may vary across the transmission slots according to the rotation pattern 326. [ The only factors described by the full precoding mechanism 134, the first precoding mechanism 136, the second precoding mechanism 138, or a combination thereof are the values for the same instance of codewords crossing multiple antennas Lt; RTI ID = 0.0 > a < / RTI > The rotation pattern 326 may comprise an offset according to each of the antennas.

The rotation pattern 326 may be based on the size or amount of the entire communication content 114, the first transmission content 116, the second transmission content 118, or a combination thereof. The rotation pattern 326 may be based on the transmission capacity 156. A detailed description considering the precoding process will be described below.

4 is an exemplary illustration of a block diagram of a computing system.

4, the computing system 100 may include a first device 102, a network 104, and a second device 106. In one embodiment, The first device 102 transmits information in the first device transmission 408 on the network 104 to the second device 106. The second device 106 transmits information in the second device transmission 410 on the network 104 to the first device 102.

It is to be understood that for purposes of illustration, the computing system 100 depicts the first device 102 as a client device, but the computing system 100 may have a first device 102 as another type of device . For example, the first device 102 may be a server having a display interface.

It will also be appreciated that for purposes of illustration, the computing system 100 depicts the second device 106 as a server, but the computing system 100 may have a second device 106 as another type of device have. For example, the second device 106 may be a client device.

Briefly stated, the first device 102 may be described as a client device, and the second device 106 as a server device. The embodiments are not limited to this selection for the types of devices. The selection is an example according to the embodiment.

The first device 102 may include a first control unit 412, a first storage unit 414, a first communication unit 416, and a first user interface 418. The first control unit 412 may include a first control interface 422. The first control unit 412 may execute the first software 426 to provide intelligence of the computing system 100.

The first control unit 412 may be implemented in a plurality of different ways. For example, the first control unit 412 may be a processor, a processor, an application specific integrated circuit (ASIC) embedded in a processor, a microprocessor, hardware control logic, a hardware finite state machine (FSM) A digital signal processor (DSP), or a combination thereof. The first control interface 422 can be used for communication between the first control unit 412 and other functional units in the first device 102. [ The first control interface 422 may be used for communication with the outside of the first device 102.

The first control interface 422 may receive information from other functional units or external sources, or may transmit information to other functional units or external destinations. The external sources and the external destinations represent the sources and destinations outside the first device 102.

The first control interface 422 may be implemented in other ways and may include functional units that are interfaced with the first control interface 422 or other implementations that rely on external units. For example, the first control interface 422 may be a pressure sensor, an inertial sensor, a microelectromechanical system (MEMS), a light guide, waveguides, a wireless circuit, a wireline circuitry, Or a combination thereof.

The first storage unit 414 stores the first software 426. The first storage unit 414 may store appropriate information, such as data representing incoming images, data representing previously existing images, sound files, or a combination thereof.

The first storage unit 414 may be a volatile memory, a non-volatile memory, an internal memory, an external memory, or a combination thereof. For example, the first storage unit 414 may be a non-volatile random access memory (NVRAM), a non-volatile storage such as a flash memory, disk storage, or a static random access memory (SRAM) ). ≪ / RTI >

The first storage unit 414 may include a first storage interface 424. The first storage interface 424 may be used for communication between the first storage unit 414 and other functional units in the first device 102. The first storage interface 424 may be used for communication with the outside of the first device 102.

The first storage interface 424 may receive information from other functional units or external sources and may transmit information to other functional units or external destinations. External sources and external destinations may represent sources and destinations outside the first device 102.

The first storage interface 424 may include functional units that interface with the first storage unit 414 or other implementations according to external units. The first storage interface 424 may be implemented with techniques and techniques similar to those of the first control interface 422.

The first communication unit 416 may perform external communication from the first device 102 or to the first device 102. [ For example, the first communication unit 416 may be coupled to a first device (e.g., a second device) for communication with a second device 106, access to other devices, peripherals or a desktop computer, network 104, 102).

The first communication unit 416 may function as a communication hub that allows the first device 102 to function as part of the network 104 and is not limited to an endpoint or terminal unit to the network. The first communication unit 416 may include active and passive components such as microelectronics or antennas for interacting with the network 104.

The first communication unit 416 may include a baseband device or component for transmitting, formatting, receiving, detecting, decoding, further processing, or a combination thereof communication signals, a modem, a digital signal processor, have. The first communication unit 416 may be configured to process voltages, currents, digital information, or a combination thereof, such as an analog to digital converter, a digital to analog converter, a filter, an amplifier, a processor type circuit, ≪ / RTI > The first communication unit 416 may further include one or more portions for storing information such as cache or RAM memory, registers, or combinations thereof.

The first communication unit 416 may be connected to the first inter-device interface 417. The first device-to-device interface 417 may be part of or a device for physically communicating signals of the individual devices. The first inter-device interface 417 can communicate signals from other devices by receiving signals or transferring signals to other devices. The first inter-device interface 417 may include one or more instances of the antenna 202 of FIG. 2 for wireless signals, a physical connection for wired signals and a transmitter receiver, or a combination thereof. The first inter-device interface 417 may include an omnidirectional antenna, a wire, an antenna chip, a ceramic antenna, or a combination thereof. The first inter-device interface 417 may further include a port, a wire repeater, a connector, a filter, a sensor, or a combination thereof.

The first inter-device interface 417 may detect or respond to the power of the electromagnetic wave and may provide detection results to the first communication unit 416 for reception of the signal including the second device transmission 410. The first inter-device interface 417 may provide a response or path of the currents or voltages provided by the first communication unit 416 for transmission of the signal including the first device transmission 408.

The first communication unit 416 may include a first communication interface 428. The first communication interface 428 may be used for communication between the first communication unit 416 and other functional units of the first device 102. The first communication interface 428 may receive information from other functional units and may transmit information to other functional units.

The first communication interface 428 may include other implementations depending on the functional units that are interfaced with the first communication unit 416. The first communication interface 428 may be implemented with techniques and techniques similar to those of the first control interface 422.

The first user interface 418 allows a user (not shown) to interface and interact with the first device 102. The first user interface 418 may include an input device and an output device. Examples of input devices of the first user interface 418 include a keypad for providing data and communication inputs, a touch pad, soft keys, a keyboard, a microphone, an infrared sensor for receiving remote signals, or any combination thereof can do.

The first user interface 418 may include a first display interface 430. The first display interface 430 may include an output device. The first display interface 430 may include a display, a projector, a video screen, a speaker, or any combination thereof.

The first control unit 412 may operate a first user interface 418 for display information generated by the computing system 100. The first control unit 412 may execute the first software 426 for other functions of the computing system 100. The first control unit 412 may further execute the first software 426 for interaction with the network 104 via the first communication unit 416. [

The second device 106 may be optimized to be implemented with embodiments within the multiple device embodiments of the first device 102. [ The second device 106 may provide additional and higher power processing performance as compared to the first device 102. The second device 106 may include a second control unit 434, a second communication unit 436, a second user interface 438, and a second storage unit 446.

The second user interface 438 allows a user (not shown) to interface and interact with the second device 106. The second user interface 438 may include an input device and an output device. Examples of input devices of the second user interface 438 may include a keypad, touchpad, soft keys, keyboard, microphone, or any combination thereof for providing data and communication inputs. An example of an output device of the second user interface 438 may include a second display interface 440. The second display interface 440 may include a display, a projector, a video screen, a speaker, or a combination thereof.

The second control unit 434 may execute the second software 442 to provide intelligence of the second device 106 of the computing system 100. The second software 442 may operate in conjunction with the first software 426. The second control unit 434 may provide additional performance as compared to the first control unit 412. [

The second control unit 434 may operate the second user interface 438 for display of information. The second control unit 434 is coupled to the second software 442 for other functions of the computing system 100 including the operation of the second communication unit 436 for communicating with the first device 102 on the network 104. [ ).

The second control unit 434 may be implemented in a number of different ways. For example, the second control unit 434 may be a processor, an embedded processor, a microprocessor, hardware control logic, a hardware finite state machine (FSM), a digital signal processor (DSP), or a combination thereof.

The second control unit 434 may include a second control interface 444. [ The second control interface 444 may be used for communication between the second control unit 434 and other functional units of the second device 106. [ The second control interface 444 may be used for communication with the outside of the second device 106.

The second controller interface 444 may receive information from other functional units or external sources or may transmit information to other functional units or external destinations. The external sources and the external destinations represent the sources and destinations outside the second device 106.

The second controller interface 444 may be implemented in other ways and may include functional units that are interfaced with the second controller interface 444 or other implementations according to external units. For example, the second controller interface 444 may be implemented with a pressure sensor, an inertial sensor, a microelectromechanical system (MEMS), an optical circuit, waveguides, a wireless circuit, a wireline circuit, or a combination thereof.

The second storage unit 446 may store the second software 442. The second storage unit 446 may store appropriate information such as data representing incoming images, data representing a previously existing image, sound files, or a combination thereof. The second storage unit 446 may be of a size to provide additional storage capacity to assist the first storage unit 414.

It should be appreciated that for purposes of illustration, the second storage unit 446 is shown as a single element, but the second storage unit 446 can be distributed as storage elements. Also for purposes of illustration, the computing system 100 has shown a second storage unit 446 as a single hierarchical storage system, but the computing system 100 has a second storage unit 446 of another configuration And the like. For example, the second storage unit 446 may be formed of caching, main memory, rotating media, or other storage techniques forming a memory hierachy system that includes different levels of off-line storage.

The second storage unit 446 may be a volatile memory, a non-volatile memory, an internal memory, an external memory, or a combination thereof. For example, the second storage unit 446 may be nonvolatile random access memory (NVRAM), flash memory, nonvolatile storage such as disk storage, or volatile storage such as static random access memory (SRAM).

The second storage unit 446 may include a second storage interface 448. The second storage interface 448 may be used for communication between the second storage unit 446 and other functional units in the second device 106. The second storage interface 448 may be used for communication with the outside of the second device 106.

The second storage interface 448 may receive information from other functional units or external sources and may transmit information to other functional units or external destinations. External sources and external destinations may represent sources and destinations outside the second device 106.

The second storage interface 448 may include functional units that interface with the second storage unit 446 or other implementations according to external units. The second storage interface 448 may be implemented with techniques and techniques similar to those of the second controller interface 444.

The second communication unit 436 may perform external communication from the second device 106 or to the second device 106. [ For example, the second communication unit 436 may allow the second device 106 to communicate with the first device 102 on the network 104.

The second communication unit 436 may function as a communication hub that allows the second device 106 for functionality as part of the network 104 and is not limited to endpoints or terminal units to the network 104. [ The second communication unit 436 may include active and passive components such as microelectronics or antennas for interacting with the network 104.

The second communication unit 436 may comprise a baseband device or component for transmitting, formatting, receiving, detecting, decoding, further processing, or a combination thereof communication signals, a modem, a digital signal processor, have. The second communication unit 436 may be implemented as one or more components for processing voltages, currents, digital information, or a combination thereof, such as analog to digital converters, digital to analog converters, filters, amplifiers, processor type circuits, ≪ / RTI > The second communication unit 436 may further include one or more portions for storage of information, such as a cache or RAM (RAM) memory, registers, or a combination thereof.

The second communication unit 436 may be coupled to the second device-to-device interface 437. The second device-to-device interface 437 may be a part or device of the device for physically communicating the signals of the individual devices. The second device-to-device interface 437 can communicate signals by receiving signals from other devices or by transmitting signals to other devices. The second inter-device interface 437 may include one or more instances of the antenna 202 for wireless signals, a physical connection for wired signals and a transmitter receiver, or a combination thereof. The second device-to-device interface 437 may include an omni-directional antenna, a wire, an antenna chip, a ceramic antenna, or a combination thereof. The second device-to-device interface 437 may further include a port, a wire repeater, a connector, a filter, a sensor, or a combination thereof.

The second device-to-device interface 437 may detect or respond to the power of the electromagnetic wave and may provide detection results to the second communication unit 436 for reception of the signal including the first device transmission 408. The second inter-device interface 437 may provide a response or path of the currents or voltages provided by the second communication unit 436 for transmission of the signal including the second device transmission 410.

The second communication unit 436 may include a second communication interface 450. The second communication interface 450 may be used for communication between the second communication unit 436 and other functional units of the second device 106. [ The second communication interface 450 may receive information from other functional units and may transmit information to other functional units.

The second communication interface 450 may include other implementations depending on the functional units that are interfaced with the second communication unit 436. The second communication interface 450 may be implemented with techniques and techniques similar to the implementation of the second controller interface 444. [

The first communication unit 416 may be coupled to the network 104 for transmitting information to the second device 106 within the first device transmission 408. [ The second device 106 may receive information in the second communication unit 436 from the first device transmission 408 of the network 104.

The second communication unit 436 may be coupled to the network 104 for transmitting information to the first device 102 in the second device transmission 410. [ The first device 102 may receive information in the first communication unit 416 from the second device transmission 410 of the network 104. [ For purposes of illustration, the second device 106 is shown as a partition having a second user interface 438, a second storage unit 446, a second control unit 434, a second communication unit 436, , But it will be appreciated that the second device 106 may have different partitions. For example, the second software 442 may be differently divided into all or part of the functions that may be the second control unit 434 and the second communication unit 436. Also, the second device 106, which may include other functional units, is not shown for clarity in FIG.

The functional units of the first device 102 may operate as separate and independent functional units. The first device 102 may operate separately and independently from the second device 106 and the network 104. [

The functional units of the second device 106 may operate as separate and independent functional units. The second device 106 may operate separately and independently from the first device 102 and the network 104.

The functional units described above may be implemented in hardware. For example, one or more of the functional units may comprise a gate, a circuit, a processor, a computer, integrated circuit cores, a pressure sensor, an inertial sensor, a microelectronic device, or other device having instructions for performing a software function, Mechanical systems (MEMS), passive devices, and physical non-volatile memory media.

For purposes of illustration, the computing system 100 has been described by the operation of the first device 102 and the second device 106. It is understood that the first device 102 and the second device 106 may operate with any of the modules and functions of the computing system 100.

5 is an exemplary diagram illustrating another block diagram of a computing system.

Referring to FIG. 5, the first device 102 may transmit information in the first device transmission 408 on the network 104 to the third device 108. The third device 108 may transmit information in the third device transmission 510 on the network 104 to the first device 102.

For purposes of illustration, the computing system 100 depicts a third device 108 as a server, but the computing system 100 may have a third device 108 operating as another type of device. For example, the third device 108 may be a client device.

Briefly describing this embodiment, the third device 108 may be described as a client device. The embodiment does not limit this choice for other types of devices. The selection is an example according to the embodiment.

The third device 108 may provide additional and higher power processing performance as compared to the first device 102. The third device 108 may include a third control unit 534, a third communication unit 536, and a third user interface 538.

The third user interface 538 allows a user (not shown) to interface and interact with the third device 108. The third user interface 538 may include an input device and an output device. Examples of input devices of the third user interface 538 may include a keypad, a touchpad, soft keys, a keyboard, a microphone, or any combination thereof for providing data and communication inputs. An example of an output device of the third user interface 538 may include a third display interface 540. The third display interface 540 may include a display, a projector, a video screen, a speaker, or a combination thereof.

The third control unit 534 may execute the third software 542 for providing intelligence of the third device 108 of the computing system 100. [ The third software 542 may operate in conjunction with the first software 426 and the second software 442 of FIG. The third control unit 534 may provide additional performance as compared to the first control unit 412. [

The third control unit 534 may operate the third user interface 538 for display of information. The third control unit 534 may control the operation of the third communication unit 536 for communicating with the first device 102, the group-accommodation device 106, or a combination thereof on the network 104 And may execute third software 542 for other functions of computing system 100, including.

The third control unit 534 may be implemented in a number of different ways. For example, the third control unit 534 may be a processor, an embedded processor, a microprocessor, hardware control logic, a hardware finite state machine (FSM), a digital signal processor (DSP), or a combination thereof.

The third control unit 534 may include a third controller interface 544. The third controller interface 544 may be used for communication between the third control unit 534 and other functional units of the third device 108. [ The third controller interface 544 may be used for communication with the outside of the third device 108.

The third controller interface 544 may receive information from other functional units or external sources or may transmit information to other functional units or external destinations. The external sources and the external destinations represent the sources and destinations outside the third device 108.

The third controller interface 544 may be implemented in other ways and may include functional units that are interfaced with the third controller interface 544 or other implementations depending on the external units. For example, the third controller interface 544 may be implemented with a pressure sensor, an inertial sensor, a microelectromechanical system (MEMS), an optical circuit, waveguides, a wireless circuit, a wireline circuit, or a combination thereof.

The third storage unit 546 may store the third software 542. The third storage unit 546 may store appropriate information such as data representing incoming images, data representing previously existing images, sound files, or a combination thereof. The third storage unit 546 may be of a size to provide additional storage capacity to assist the first storage unit 414.

It is understood that for purposes of illustration, the third storage unit 546 is shown as a single element, but the third storage unit 546 can be distributed as storage elements. Also for purposes of illustration, the computing system 100 has shown a third storage unit 546 as a single hierarchical storage system, but the computing system 100 has a third storage unit 546 of another configuration And the like. For example, the third storage unit 546 may be formed of caching, main memory, rotating media, or other storage techniques forming a memory hierachy system that includes different levels of off-line storage.

The third storage unit 546 may be a volatile memory, a non-volatile memory, an internal memory, an external memory, or a combination thereof. For example, the third storage unit 546 may be non-volatile storage such as non-volatile random access memory (NVRAM), flash memory, disk storage, or volatile storage such as static random access memory (SRAM).

The third storage unit 546 may include a third storage interface 548. [ The third storage interface 548 may be used for communication between the third storage unit 546 and other functional units in the third device 108. The third storage interface 548 may be used for communication with the outside of the third device 108.

The third storage interface 548 may receive information from other functional units or external sources and may transmit information to other functional units or external destinations. External sources and external destinations may represent sources and destinations outside the third device 108.

The third storage interface 548 may include functional units interfaced with the third storage unit 546 or other implementations according to external units. The third storage interface 548 may be implemented with techniques and techniques similar to those of the third controller interface 544.

The third communication unit 536 can perform external communication from the third device 108 or to the third device 108. [ The third communication unit 536 allows the third device 108 to communicate with the first device 102, the second device 106, or a combination thereof of Figure 4 on the network 104 can do.

The third communication unit 536 may function as a communication hub that allows the third device 108 for functionality as part of the network 104 and is not limited to endpoints or terminal units to the network 104. [ The third communication unit 536 may include active and passive components such as microelectronics or antennas for interacting with the network 104.

The third communication unit 536 may comprise a baseband device or component for transmitting, formatting, receiving, detecting, decoding, further processing, or a combination thereof communication signals, a modem, a digital signal processor, have. The third communication unit 536 may be configured to receive voltages, currents, digital information, or a combination thereof, such as an analog to digital converter, a digital to analog converter, a filter, an amplifier, a processor type circuit, ≪ / RTI > The third communication unit 536 may further include one or more portions for storing information such as cache or RAM memory, registers, or combinations thereof.

The third communication unit 536 may be connected to the third device-to-device interface 537. The third inter-device interface 537 may be a part or device of the device for physically communicating the signals of the individual devices. The third device-to-device interface 537 can communicate signals by receiving signals from other devices or by transmitting signals to other devices. The third device-to-device interface 537 may include one or more instances of the antenna 202 of FIG. 2 for wireless signals, a physical connection for wired signals and a transmitter receiver, or a combination thereof. The third inter-device interface 537 may include an omnidirectional antenna, a wire, an antenna chip, a ceramic antenna, or a combination thereof. The third inter-device interface 537 may further include a port, a wire repeater, a connector, a filter, a sensor, or a combination thereof.

The third inter-device interface 537 may detect or respond to the power of the electromagnetic wave and may provide detection results to the third communication unit 536 for reception of signals including the third device transmission 508. The third inter-device interface 537 may provide a response or path of the currents or voltages provided by the third communication unit 536 for transmission of the signal including the third device transmission 510.

The third communication unit 536 may include a third communication interface 550. The third communication interface 550 may be used for communication between the third communication unit 536 and other functional units of the third device 108. [ The third communication interface 550 may receive information from other functional units and may transmit information to other functional units.

The third communication interface 550 may include other implementations according to the functional units that are interfaced with the third communication unit 536. The third communication interface 550 may be implemented with techniques and techniques similar to those of the third controller interface 544.

The first communication unit 416 may be coupled to the network 104 for transmitting information to the third device 108 within the first device transmission 408. [ The third device 108 may receive information in the third communication unit 536 from the first device transmission 408 of the network 104.

The third communication unit 536 may be coupled to the network 104 for transmitting information to the first device 102 in the third device transmission 510. [ The first device 102 may receive information in the first communication unit 416 from the third device transmission 510 of the network 104. [ The computing system 100 may be executed by a first control unit 412, a third control unit 534, or a combination thereof. The group facility device 106 may communicate and interact similarly to the third device 108 used in accordance with its units or functions.

The third device 108 is shown as a partition with a third user interface 538, a third storage unit 546, a third control unit 534, a third communication unit 536, It will be appreciated, however, that the third device 108 may have other partitions. For example, the third software 542 may be differently divided into all or part of the functions that may be the third control unit 534 and the third communication unit 336. [ Also, the third device 108, which may include other functional units, is not shown for clarity in FIG.

The functional units of the third device 108 may operate as separate and independent functional units. The third device 108 may operate independently and independently from the first device 102, the group facility device 106, the host device 110, and the network 104.

For purposes of illustration, the computing system 100 has been described by the operation of the first device 102 and the third device 108. It is understood that the first device 102, the group equipment 106, the host device 110, and the third device 108 may operate with any of the modules and functions of the computing system 100.

6 is a diagram showing a control flow of the computing system.

6, the computing system 100 includes a content management module 602, an encoding module 604, a precoding module 606, a transmission module 608, a receiver module 610, can do.

The content management module 602 may be coupled to an encoding module 604 that may be further coupled to a precoding module 606. The precoding module 606 may be further coupled to a transmission module 608, which may be coupled to the receiver module 610.

The modules may be interconnected in various ways. For example, the modules may be connected by the use of wired or wireless connections in the network 104 of FIG. 1, by having inputs of one module connected to the other output in steps, process sequences, or combinations thereof . It may also be indirectly connected with other modules or devices, for example, with connection means between directly connected modules and connecting means between directly connected or indirectly connected modules without any other intermediate structure.

As a more detailed example, one or more inputs or outputs of the content management module 602 may be connected to one or more inputs of the encoding module 604 using conductors or transport channels that do not come between the modules or devices thereof have. For example, transmission module 608 may also be coupled to a communication channel such as network 104, first transmission channel 144, second transmission channel 146, or node link 112 of FIG. 1, or a combination thereof Lt; RTI ID = 0.0 > 610 < / RTI > The content management module 602, the encoding module 604, the precoding module 606, the transmission module 608, the receiver module 610, or a combination thereof may be directly or indirectly connected in a manner similar to the above- .

The computing system 100 may use the device or communicate with the device by displaying an image, regenerating sounds, exchanging process steps or instructions. The computing system 100 may communicate information between devices. The receiving device may further communicate with the user by playing images, reproducing sounds, exchanging process steps or instructions, or combinations thereof depending on the information in communication with the device.

Content management module 602 is configured to coordinate communication of the entire communication content 114 of FIG. The content management module 602 may identify the entire communication content 114 or a portion thereof for specific transmission devices. Content management module 602 may coordinate communications for use of overloaded transmission mode 162 of FIG. 1, including the full rank communication mode 1498 of FIG. The content management module 602 may coordinate communication to further use the advanced receiver 150 of FIG.

1 for the transfer of the entire content 114 to the first device 102 of FIG. 1 that includes the advanced receiver 150. The content management module 602 may include a third device 106, The content data can be managed and identified to use the device 108. The content management module 602 can identify and communicate the entire communication content 114 or only a portion thereof for each of the second device 106 and the third device 108 and can enable communication through the antennas, Activation of transmission module 162, activation of blind cavity transmission 110, or a combination thereof.

The content management module 602 may determine the capacity or capability of the first device 102. The content management module 602 may be configured to determine the content of the first device 102 based on information that considers the first device 102 predetermined by the computing system, the device identification or device description from the first device 102, Such as the presence or effectiveness of the advanced receiver 150 or the receiver capacity 154 of the receiver.

The content management module 602 may include a blind common transmission 110 for communicating the entire communication content 114 to the first device 102 based on the first device 102, an overloaded transmission mode 162, The combination can be determined. For example, the content management module 602 may include a blind shared transmission 110, an overloaded transmission mode 162, an all-rank transmission mode 148, and a full-rank transmission mode 160 when the first device 102 includes the advanced receiver 150. [ Or a combination thereof. The content management module 162 does not consider the capacity 154 of the receiver of the first device 102 but does not consider the capacity 154 of the receiver of the first device 102, 110, an overload transmission mode 162, an all-rank transmission mode 148, or a combination thereof.

Content management module 602 may determine blind joint transmission 110, overload transmission mode 162, full rank transmission mode 148, or a combination thereof, in various ways. For example, the content management module 602 may include a blind joint based on the setting or communication of values indicating blind common transmission 110, overload transmission mode 162, full rank transmission mode 148, Transmission 110, overload transmission mode 162, full rank transmission mode 148, or a combination thereof.

For example, the content management module 602 may include a blind shared transport 110, an overloaded transport mode 118, a second transported content 118, or a combination thereof, based on the determination of the first transported content 116, the second transported content 118, A full rank transmission mode 148, or a combination thereof. The content management module 602 may determine the first transmission content 116 for transmission from the second device 106. [ The content management module 602 may determine the second transmission content 118 for transmission from the third device 108. [

Continuing, for example, the content management module 602 may include a first transmission content 116, a second transmission content 118, or a combination thereof as the entire communication content 114, a unique portion thereof, Can be determined. The content management module 602 may include a second device 106, a third device 108, a combination of their antennas, or a combination thereof, depending on the blind common transmission 110, the overloaded transmission mode 162, The first transmission content 116 and the second transmission content 118 according to the transmission can be determined from the combination.

As a more detailed example, the content management module 602 may determine the first transmission content 116 and the second transmission content 118 to include the entire communication content 114, respectively. As a more detailed example, the content management module 602 may include the entire communication content 114 according to the transmission capacity 156 of FIG. 1 according to the applicable transmission equipment, such as the second device 106 or the third device 108, Can be distributed. The content management module 602 may include a first transmission content 116 as a unique instance or a collection of distributed portions of the transmission capacity 156 according to an associated transmission device according to a plurality of available antennas or ports on each transmission device, And the second transmitted content 118 may be determined.

The content management module 602 may be configured to communicate with the entire communication content 114 for all or specific portions of the entire communication content 114 for determining the first transmission content 116, the second transmission content 118, ) Can be identified. The content management module 602 may identify the entire communication content 114 based on communication of the entire communication content 114 for all or specific portions of the entire communication content 114 among the devices.

Content management module 602 may communicate all or a portion of the entire communication content 114 between transmitting devices, coordinating devices, or a combination thereof. As a more specific example, the content management module 602 may communicate between the second device 106, the third device 108, the coordinating device, or a combination thereof.

The content management module 602 can identify and communicate the entire communication content 114 to all or specific portions of the entire communication content 114 based on reception, transmission, coordination, or a combination thereof for the data . For example, the content management module 602

Receiving, transmitting, or receiving a first transmission content 116, a second transmission content 118, or a combination thereof between the first device 106, the second device 106, the third device 108, the adjustment device, The entire communication content 114 may be identified and communicated to all or specific portions of the entire communication content 114 based on a variety of communication content,

As a more detailed example, the content management module 602 may include a coordinating device for determining the first transmission content 116 and the second transmission content 118, as in the example described above. The content management module 602 may further include a coordinating device for communicating the first transmission content 116 to the second device 106 and communicating the second transmission content 118 to the third device 108 .

As a further example, the content management module 602 may include a second device 106 for determining the first transmission content 116 and the second transmission content 118, as in the example described above. The content management module 602 may further include a second device 106 for communicating the second transport content 118 to a third device 108.

The content management module 602 includes a first device interface 417, a second device interface 437, a first communication unit 416, a second communication unit 436, The third device interface 537 of FIG. 5, the third communication unit 536, or a combination thereof. The content management module 602 may include an identification, decision, distribution, grouping or grouping thereof for the entire communication content 114, a portion thereof, a first transmission content 116, a second transmission content 118, 5, the first communication unit 416, the second communication unit 436, the third communication unit 536, the first control unit 412, the second control unit 434, 3 control unit 534, or a combination thereof.

The content management module 602 includes a first communication unit 416, a second communication unit 436, a third communication unit 536, a first storage unit 414 of FIG. 4, a second storage unit 414 of FIG. The first transmission content 116, the second transmission content 118, or a combination thereof, within the first storage unit 546, the third storage unit 546 of FIG. 5, or a combination thereof. Lt; / RTI >

After adjusting the communication of the entire communication content 114, the control flow proceeds to the encoding module 604. [ The control flow may proceed through various methods. For example, the control flow may include an entire communication content 114, a portion thereof, a first transmission content 116, a second transmission content 118, or a combination thereof, from the content management module 602 to the encoding module 604. [ The processing result of one module proceeding to the other module by movement of the combination results in the entire communication content 114, a portion thereof, the first transmission content 116, the second communication content 114 in the encoding module 604, By the use of a combination of storage, flag, interrupt, status signal, or encoding module 604 of processing results in another location module accessible with a known location, such as by storage of transport content 118 or a combination thereof, Identification of other modules, or a combination of such processes.

The encoding module 604 is configured to process and prepare the content for communication between the devices. The encoding module 604 can process and prepare the encoded content data. The encoding module 604 may encode the entire communication content 114, a portion thereof, the first transmission content 116, the second transmission content 118, or a combination thereof. The encoding module 604 may encode the content data for the generation of the first encoding set 122, the second encoding set 124, or a combination thereof of FIG.

For example, the encoding module 604 may generate a first encoding set 122 according to the entire communication content 114 and portions thereof for the first transmission content 116. For example, The first encoding module 604 may further generate the first encoding set 122 at the second device 106 or using the second device 106. [

For example, the encoding module 604 may generate a second encoding set 124 according to the entire communication content 114 or portions thereof for the second transmission content 118. [ The encoding module 604 may generate a second encoding set 124 for the third device 108. The encoding module 604 may further generate the second encoding set 124 at the third device 108 or using the third device 108. [

The encoding module 604 may be configured to communicate with the second encoding set 124 to communicate with the first encoding set 122 coordinated with the second encoding set 124 based on the different portion of the total communication content 114 according to the third device 108. [ The first encoded set 122 may be generated based on a portion of the total communication content 114 in accordance with the first communication set 106. [ Encoding module 604 may generate a second set of encodings 124 based on different portions of the entire communications content 114 for coordinated communications.

As a more detailed example, the encoding module 604 may generate the entire encoding message 120 of FIG. 1 in accordance with the overall communication content 114. As illustrated in Figures 1 and 3, the encoding module 604 includes a first codeword 126, a second codeword 128, a third codeword 130, and a fourth codeword 132, The entire encoded message 120 may be generated.

Continuing, for example, the encoding module 604 may generate a first encoding set 122 and a second encoding set 124, respectively, including the entire encoding message 120. The encoding module 604 may encode the first transmission content 116 or the second transmission content 118 that includes only portions of each or all of the communication content 114 that contain non-overlapping portions of the entire encoding message 120 The first encoding set 122 and the second encoding set 124 may be generated. As illustrated in Figures 1 and 3, the encoding module 604 may generate a first encoding set 122 to include a first codeword 126 and a second codeword 128, To generate a second set of codes 124 for including the word 130 and the fourth codeword 132. [

Encoding module 604 may generate a first set of encodings 122 and a second set of encodings 124 to coincide or accompany the transmission. For example, the encoding module 604 may generate a first encoding set 122 for transmission from the second device 106 concurrently with or accompanied by transmission of the second encoding set 124 from the third device 108 can do. The encoding module 604 may generate the second encoding set 124 for transmission from the third device 108 either concurrently with or accompanied by the transmission of the first encoding set 122 from the second device 106 .

The encoding module 604 may be encoded based on a predetermined method or process by a computing system, a communications standard, or a combination thereof. For example, the encoding module 604 may encode based on a turbo-coding scheme or a polar-coding scheme. As a more specific example, the encoding module 604 may be configured to add information, remove information, format the content data, rearrange the content data, or update the content data for an error correction process, an error detection process, a communication protocol, Combination can be done.

The encoding module 604 includes a first communication unit 416, a second communication unit 436, a third communication unit 536, a first control unit 412, a second control unit 434 ), A third control unit 534, or a combination thereof, and can generate the encoded result. The encoding module 604 includes a first communication unit 416, a second communication unit 436, a third communication unit 536, a first storage unit 414, a second storage unit 446, (546), or a combination thereof.

After encoding the content data and generating the encoded result, the control flow may proceed from the encoding module 604 to the precoding module 606. The control flow may proceed in a similar manner as described above between the content management module 602 and the encoding module 604, but may be performed in the entire encoding message 120, the first encoding set 122, the second encoding set 124, The processing result of the encoding module 604 such as a combination thereof can be used.

The precoding module 606 may be configured for further processing and provisioning of content data for communication between the devices. The precoding module 606 may implement a precoding process for the encoding results. For example, the precoding module 606 may generate a pre-coding matrix based on the first coding set 122, the second coding set 124, or a combination thereof, including the entire coding message 120 or a portion thereof, The entire precoding mechanism 134, the first precoding mechanism 136, the second precoding mechanism 138, or a combination thereof.

The precoding module 606 may determine a first precoding mechanism 136 associated with the first set of encodings 122. The precoding module 606 may determine a second precoding mechanism 138 associated with the second set of encodings.

Precoding module 606 may be used to simultaneously or cooperate with multiple instruments, multiple antennas thereof, or a combination thereof to provide a full precoding mechanism 134, a first precoding mechanism 136, a second precoding mechanism < RTI ID = 0.0 > (138), or a combination thereof. The first precoding module 606 may use the entire pre-coding for communicating with the entire communication content 114 using the overload transmission mode 162, the full rank transmission mode 148, the blind joint transmission 110, The coding mechanism 134, the first precoding mechanism 136, the second precoding mechanism 138, or a combination thereof.

The precoding module 606 may determine a first precoding mechanism 136 according to the first set of encodings 122, a second precoding mechanism 138 according to the second set of encodings 124, have. For example, the precoding module 606 may be directly associated with the entirety of the entire communication content 114 such that the first set of encodings 122 and the second set of encodings 124 are included in the entire coded message 120 The first precoding mechanism 136 and the second precoding mechanism 138 may be determined as the entire precoding mechanism 134 or a part thereof.

For example, the precoding module 606 may determine the first precoding mechanism 136 and the second precoding mechanism 138 to include unique and non-overlapping portions of the entire precoding mechanism 134. The precoding module 606 together with the entire precoding mechanism 134 together with the first precoding mechanism 136 and the entire precoding mechanism 134 as the first transmission portion 302 of FIG. The second precoding mechanism 138 as the transmit portion 304, or a combination thereof.

For example, the precoding module 606 may determine the first precoding mechanism 136 either directly from the first set of encodings 122 or using only the first set of encodings 122, The second precoding mechanism 138 can be determined either directly from the first set 124 or only using the second set of encodings 124. [ The first precoding module 606 is configured to generate a first portion of the entire encoded message 114 in which the first set of encodings 122 and the second set of encodings 124 are each directly associated with unique portions within the entire communication content 114, The first precoding mechanism 136 and the second precoding mechanism 138 may be determined based on unique portions of the content or directly associated with the only portion of the content.

The precoding module 606 may determine the first precoding mechanism 136 and the second precoding mechanism 138 based on the rotation pattern 326 of FIG. The precoding module 606 may determine the first precoding mechanism 136 and the second precoding mechanism 138 without using the channel information 160 of FIG. The computing system 100 may receive the first device 102 from multiple transmission devices, such as the second device 106 and the third device 108, without using the channel estimate 158 or the transmitter channel information 106 of FIG. Lt; / RTI > may utilize blind common transmission based on coordinated transmissions to a receiver such as < RTI ID = 0.0 >

The precoding module 606 may determine the length or size of the first transmission content 116 or the second transmission content 118 for each transmission device, The precoding mechanism 136 and the second precoding mechanism 138 may be determined. For example, the precoding module 606 may transmit (or transmit) information to the second device 106 or the third device 108, an instance of the antenna 202 of FIG. 2, in cross or transmission slots, The entire precoding mechanism 134 may be determined based on the rotated portion of the entire encoded message 120 according to the rotation pattern 326 intersecting the devices.

As a more detailed example, the precoding module 606 may include a first antenna slot 310 of FIG. 3, a second antenna slot 312 of FIG. 3, a second antenna slot 312 of FIG. 3 for the first transmission slot 318 of FIG. 3, 3 antenna slot 314 and the fourth antenna slot 316 of Figure 3 each include a first codeword 126, a second codeword 128, a third codeword 130, and a fourth codeword 140 The entire precoding mechanism 134 can be determined. The precoding module 606 may include the second transmission slot 320 of Figure 3 according to the rotation pattern 326 such as the parallel orthogonal pattern 328 of Figure 3 or the cross orthogonal pattern 330 of Figure 3, 3 transmission slot 322, and another instance of the antenna slot for the fourth transmission slot 324 of FIG. 3, by allocating each codeword.

Continuing, for example, the precoding module 606 may determine the entire precoding mechanism 134 by assigning portions of the entire precoding mechanism 134 based on the repetition of the rotation pattern 326. The precoding module 606 may determine the first precoding mechanism 136 with the entire precoding mechanism 134 in its entirety or its first transmission portion 302, as in the example above. The precoding module 134 may determine the second precoding mechanism 138 with the entire precoding mechanism 134 in its entirety or its second transmission portion 304, as in the example above.

For example, precoding module 606 may include a first transmission portion 302, a second transmission portion 302, and a second transmission portion 302 for each of the instances of antenna 202 for each of the transmission devices, the intersection transmission slots, The first precoding mechanism 136 and the second precoding mechanism 138 may be determined based on the rotated portions of the portion 304, or a combination thereof. The precoding module 606 includes a first precoding mechanism 136 and a second precoding module 142 according to a first set of encodings 122 and a second set of encodings 124 associated with non-overlapping and unique portions of the entire communication content 114, 2 < / RTI > precoding mechanism 138 may be determined. The precoding module 606 may be configured to perform the precoding based on the size, length, amount, or availability of the first encoding set 122, the second encoding set 124, the transmission capacity 156 associated with each of the transmitting devices, 1 precoding mechanism 136 and the second precoding mechanism 138 may be determined.

As a more detailed example, the first encoding set 122 may include a first codeword 126 and a second codeword 128 for the second device 106, and the second encoding set 124 may include And a third codeword 130 and a fourth codeword 132 for the third device 108. [ The precoding module 606 includes a first code word 126 that crosses transmission slots and antenna assignments based on a rotation pattern 326 such as a parallel orthogonal pattern 328 or a cross orthogonal pattern 330, The first precoding mechanism 136 may be determined based on the assignment of the codeword 128.

Continuing, for example, the precoding module 606 may generate a second code word 130 and a fourth code word 132 based on the rotation pattern 326, based on the third codeword 130 and the fourth codeword 132 intersecting the transmission slots and antenna assignments, The precoding mechanism 138 may be determined. The starting point or adjustment for the rotation pattern 326 of the second precoding mechanism 138 may be offset or complementary to the first precoding mechanism 136.

The rotation pattern 326 may be based on a rotation given as a set of data or code words for a particular transmission device that crosses the available antennas of each instance of the transmission device. The precoding module 606 includes a first encoding set 120 according to the portion of the overall encoding message 120 for instances of the second device 106 and its antenna 202 to determine a first precoding mechanism 136, The rotation pattern 326 may be used together with the rotation pattern 122. The precoding module 606 may determine the second precoding mechanism 138 based on the second part of the overall encoding message 120 for the instance of the third device 108 and its antenna 202 to determine the second precoding mechanism 138. [ The rotation pattern 326 may be further used together with the set 124.

The precoding module 606 includes all instances of transmitting devices, such as instances of the second device 106, the third device 108, and their antennas 202 for determining the entire precoding mechanism 134 The rotation pattern 326 may be used together with the first coding set 122 and the second coding set 124 according to all of the hash total coding messages 120. [ The rotation pattern 326 may be based on rotation of the entire set of data or code words crossing all available instances of the antenna 202 crossing all available transmission devices. The precoding module 606 may determine the first precoding mechanism 136 and the second precoding mechanism 138, respectively, as unique and non-overlapping portions of the overall precoding mechanism 134.

The precoding module 606 may determine the first precoding mechanism 136, the second precoding mechanism 138, or a combination thereof without the use of the transmitter channel information 160. The precoding module 606 may determine the first precoding mechanism 136, the second precoding mechanism 138, or a combination thereof based on the rotation pattern 326 instead of the transmitter channel information 160 .

It is found that the first precoding mechanism 136 and the second precoding mechanism 138 based on the rotation pattern 326 instead of the transmitter channel information 160 can provide increased efficiency and resource management. The first precoding mechanism 136 and the second precoding mechanism 138 using a rotation pattern may use available antennas that cross multiple transmitters without being limited by the receiver capacity 154. [ Blind co-transmission 110 may utilize all available resources considering receiver capacity 154 without being limited to a single transmitter.

The precoding module 606 includes a first precoding mechanism 136 based on adjustment via a node link to adjust the first precoding mechanism 136 with a second precoding mechanism 138 crossing the transmission devices, The second precoding mechanism 138, or a combination thereof. Precoding module 606 may communicate with the determination of blind common transmission 110, as described above. The precoding module 606 may further communicate a starting point, offset value, format or initialization, antenna allocation or identification, or a combination thereof for each of the transmission devices.

For example, the precoding module 606 may select a transmitting device, its antenna, or a combination thereof for allocation of a particular instance of an antenna slot for the entire precoding mechanism 134. [ The precoding module 606 may be configured to assign a first antenna slot 310 and a second antenna slot 312 of the entire precoding mechanism 134 in accordance with an instance of the antenna 202 on the second device 106. [ 2 device 106 in order to be able to communicate. The precoding module 606 may be similarly assigned to the third antenna slot 314 and the fourth antenna slot 316 as an instance of the antenna 202 of the third device 108. [

For example, the precoding module 606 may communicate predetermined settings, configurations, offset values, starting points, or a combination thereof, by the computing system 100 for each of the transmission devices. The communication settings, configurations, offset values, starting points, or a combination thereof may depend on the relationship or correspondence between the particular antenna of the transmitting device and the instance of the antenna slot of the entire precoding mechanism 134.

The precoding module 606 may utilize all available instances of the antenna 202 that cross the transmitting devices within the transmission range for the first device 102 for the full rank communication mode 148. [ The precoding module 606 may adjust the instances of the antennas 202 or the combined amount thereof to less than all available instances for the overloaded transmission mode 162 that do not reach the full rank transmission mode 148 .

Precoding module 606 may adjust antenna positions according to a transmission mode similar to that described above. The precoding module 606 includes a first precoding mechanism 138 for the entire rank transmission mode 148 using the second device 106 and the third device 108 as described above, To determine the first precoding mechanism 136, the second precoding mechanism 138, or a combination thereof, to adjust the mechanism 136.

As a general example, the second device 106 may identify or receive portions of the entire communication content 114 with the first transmission content 116 along with the content management module 602. The second device 106 may be configured to transmit a first precoding mechanism 136 based on the portion of the overall communication content 114 for the first precoding mechanism 136 in accordance with a portion within the entire precoding mechanism 134 determined by the precoding module 606. [ An encoding module 604 may be used to generate the encoding set 122.

Subsequently, for example, the third device 108 may identify or receive the other portion of the entire communication content 114 as the second transferred content 118 with the content management module 602. The third device 108 may be located in another part of the overall communication content 114 for the second precoding mechanism 138 in accordance with another part within the entire precoding mechanism 134, as determined by the precoding module 606 The encoding module 604 may be used to generate the second set of encoded data 124 based on the second set of encoded data.

Subsequently, for example, the second device 106 and the third device 108 can encode and determine each other without any mutual adjustment based on the receipt of the only portions of the entire communication content 114. The computing system 100 includes a first precoding mechanism 136 for communicating the entire communication content 114 with blind common transmission 110 that simultaneously uses transmissions from multiple devices without the use of global channel information at transmitters. And a second encoding set 124 having a second precoding mechanism 138 may be used.

또는

로 나타낼 수 있다. 제 1 프리코딩 매커니즘(136)은 전체 프리코딩 매커니즘(134)의 첫 번째 두 컬럼(column)들 또는 로우(row)들을 포함할 수 있다. 제 2 프리코딩 매커니즘(138)은 전부 내의 전체 프리코딩 매커니즘(134)을 더 포함할 수 있다. 제 2 프리코딩 매커니즘(138)은 첫 번째 두 로우들 또는 컬럼들이 될 수 있도록 재정렬된 마지막 두 로우들과 컬럼들을 갖는 전체 프리코딩 매커니즘(134)을 더 포함할 수 있다.Continuing, for example, the entire precoding mechanism 134 may be based on the rotation pattern 326

or

. The first precoding mechanism 136 may include the first two columns or rows of the entire precoding mechanism 134. The second precoding mechanism 138 may further include an entire precoding mechanism 134 within the entire system. The second precoding mechanism 138 may further include a full precoding mechanism 134 having the last two rows and columns rearranged to be the first two rows or columns.

Continuing, for example, each device may be to transmit unique and non-overlapped portions of the entire communication content 114 over multiple transmission slots. The computing system 100 may include a complete set of communication content 114 or a complete set of communications communicated for each instance of a transmission slot that intersects multiple antennas and multiple antennas.

The second device 106 or the third device 108 or a combination of them may be used together with the content management module 602 to transmit the first transmission content 116, the second transmission content 118, , Or a combination of all of them. The second device 106, the third device 108, or a combination thereof may include a first encoding set 112 that includes the entire encoding message 120 based on the entirety of the entire communication content 114, (S) 124, or a combination thereof.

Subsequently, for example, the second device 106, the third device 108, or a combination thereof may be used for an instance of a transmission slot for the entire precoding mechanism 134 as determined by the precoding module 606 May generate a first encoding set 122, a second encoding set 124, or a combination thereof from the entire communication content 114. [ The second device 106 and the third device 108 can be encoded and determined based on the adjustment between the above-described devices.

Subsequently, for example, the second device 106 and the third device 108 may determine according to a precoding mechanism for transmitting the entire inner communication content 114 from each device on the multiplex transmission slots. The second device 106 and the third device 108 may be configured to transmit the entire communication content 114 to the blind common transmission 110 that simultaneously uses transmissions from multiple devices without the use of global channel information at the transmitters. It can be decided according to the coding mechanism.

또는

으로 각각 나타낼 수 있다. 컴퓨팅 시스템(100)은 다중 기기들과 다중 안테나들을 가로지르는 전송 슬롯의 각 인스턴스를 위해 전체 통신 컨텐트(114)와 그것의 완전 집합을 포함할 수 있다.Subsequently, for example, the first precoding mechanism 136, the second precoding mechanism 138, or a combination thereof may be based on the rotation pattern 326

or

Respectively. The computing system 100 may include an entire communication content 114 and a complete set thereof for each instance of a transmission slot across multiple devices and multiple antennas.

The entire precoding mechanism 134 based on the rotation pattern 326 may find to provide increased low burstness and communication rate. The entire precoding mechanism 134 based on the rotation pattern 326 may eliminate the need for transmitter channel information 160 during a precoding procedure to activate co-transmission for an open loop communication scheme. The joint communication can increase the amount of data transmitted at the same time and increase the transmission speed.

Blind co-transfer 110 may find to provide increased efficiency and resource management. The blind cavity transmission 110 may utilize available antennas that cross multiple transmitters without being limited by the receiver capacity 154. Blind co-transmission 110 may utilize the available resources without being limited to one receiver without regard to receiver capacity.

Each first precoding mechanism 136 and second precoding mechanism 138 according to the entire encoding message 120 may provide increased processing throughput while providing reduced processing errors. Each first precoding mechanism 136 and second precoding mechanism 138 in accordance with the full encoded message 120 is configured to perform a rotation that intersects all the antennas and all parts of the content to remove undesired effects from the communication channel Pattern 326 may be used.

Each of the first precoding mechanism 136 and the second precoding mechanism 138 according to the other unique portions in the overall coding message 120 provides reduced processing complexity while providing an increased overall throughput. The first precoding mechanism 136 and the second precoding mechanism 138 according to other unique portions may reduce the need for duplication of content in the encodings at each of the transmitters.

The precoding module 606 may be configured to determine a precoding mechanism such as a first precoding mechanism 134, a second precoding mechanism 136, an entire precoding mechanism 134, A second communication unit 436, a third communication unit 536, a first control unit 412, a second control unit 434, a third control unit 534, or a combination thereof. . The precoding module 606 includes a first communication unit 416, a second communication unit 436, a third communication unit 536, a first storage unit 414, a second storage unit 446, (546), or a combination thereof.

After determining the precoding mechanism, the control flow may be passed from the precoding module 606 to the transmission module 608. The control flow uses the processing results of the precoding module 606, such as the first precoding mechanism 136, the second precoding mechanism 138, the entire precoding mechanism 134, or a combination thereof, May be similarly propagated between module 602 and encoding module 604 as described above.

The transmission module 608 and the receiver module 610 are configured to communicate the intended content between the devices. The transmission module 608 may be configured to transmit the entire communication content 114 for the blind common transmission 110. For example, the transmission module 608 may transmit the first transmitter signal 140 of FIG. 1 and the second transmitter signal 140 of FIG. 1 from the second device 106 and the third device 108 to the first device 102 142).

The transmission module 608 may communicate by transmission of the first transmitter signal 140 based on the first encoding set 122 and the first precoding mechanism 136. The transmission module 608 may further communicate the second transmitter signal 142 based on the second encoding set 124 and the second precoding mechanism 138. The transmission module 608 may communicate by transmitting the first transmitter signal 140 and the second transmitter signal 142 concurrently or concurrently from the second device 106 and the third device 108.

The transmission module 608 may transmit the first transmission content 116 and the second transmission content 118 via the first transmitter signal 140 and the second transmitter signal 142. The transmission module 608 may transmit the first transmission content 116 and the second transmission content 118 that contain different or unique data. For example, transmission module 608 may be configured to transmit unique and non-overlapping portions of the entire communication content 114 instead of duplicate or identical information transmitted via first transmitter signal 140 and second transmitter signal 142 1 transmission content 116 and second transmission content 118, respectively.

The transmission module 608 includes a first device interface 417, a second device interface 437, a third device interface 537, a first communication unit 416, a second communication unit 436, (S) 536, or a combination thereof. Transmission module 608 may cross multiple instances of antenna 202 and be transmitted by the generation of electrical signals based on the operating voltage, current, power supply, or a combination thereof.

The receiver module 610 is configured to receive the EKfms receiver signal 152 in the first transmitter signal 140 and the second transmitter signal 142 and recover the entire communication content 114. The receiver module 610 can recover the entire communication content 114 using the advanced receiver 150 at the first device 102. [

The advanced receiver 150 may utilize the amount of layer count 206 in FIG. 2 over the receiver capacity 154 and the processing mechanism configured to process instances of the data layers 204 in FIG. 2. The advanced receiver 150 may utilize a processing mechanism that includes an interference recognition processing mechanism.

For example, the advanced receiver 150 may be implemented with interference detection or interference-aware decoding to recognize information communicated beyond the receiver capacity 154. Advanced receiver 150 may be part of overall communication content 114 and may recognize additional information rather than interfering signals.

7 is a flow chart of a method of operating a computing system in another embodiment of the present invention.

Referring to FIG. 7, at step 702, the method 700 begins at block 702 with a second device for using the second device and a third device to transmit the entire communication content to the first device, At block 704, a first set of encodings according to the entire communication content or a portion thereof for communicating the entire communication content along a second set of encodings for the third device is generated , At block 706, the precoding mechanism associated with the first set of communications for communicating the entire communication content with the overloaded transmission mode comprising a second precoding mechanism for the third device is determined, and at block 708 Communicating a first transmitter signal based on a first encoding set and a first precoding mechanism to communicate a first transmitter signal concurrently with a second transmitter signal from a third device It includes.

The modules described with these applications are the first communication unit 416 of Figure 4, the third communication unit 536 of Figure 5, the second communication unit 436 of Figure 4, the second control unit 438 of Figure 4 ), The third control unit 534 of FIG. 5, or a combination thereof, passive circuitry, active circuitry, or both. The modules include a first communication unit 416, a second communication unit 436, a third communication unit 536, a first control unit 412, a second control unit 434, a third control unit 534, Or any combination thereof, but may be a passive circuit, an active circuit, or both in the first device 102 of FIG. 1, the second device 106 of FIG. 1, the third device 108 of FIG. 1, Or both hardware implementations or hardware accelerators.

The computing system 100 of FIG. 1 is illustratively illustrated with modules or sequences. The computing system 100 may be partitioned in order of other modules or other modules. For example, the encoding module 604 and the precoding module 606 may be combined. Also, for example, the content management module 602 may be implemented as a second device 106, a third device 108, a node link 112 of FIG. 1, a coordinating device, or a combination thereof, A submodule for obtaining information and a submodule for acquisition of a submodule for the designated content determined for transmission in each device.

For the purposes shown, the various modules may be described as being specific for the first device 102, the second device 106, the third device 108, or a combination thereof. However, it can be understood that the modules can be distributed differently. For example, the various modules may be implemented in different devices or the functions of the modules may be distributed across multiple devices. Also, for example, the various modules may be stored in an unregistered memory medium.

As a more specific example, the one or more modules described above may be stored in a non-volatile memory medium for distribution to another system, another device, another user, or a combination thereof for manufacture. As a further example, the modules described above may be implemented and stored using a single hardware unit, such as a chip or a processor, or an intersection of multiple hardware units.

Modules described in these applications may be stored in non-volatile computer storage media. The first communication unit 416, the second communication unit 436, the third communication unit 536, the first storage unit 414 of FIG. 4, the second storage unit 446 of FIG. 4, 3 storage unit 546, or a combination thereof, may replace non-volatile computer storage media. A first communication unit 416, a second communication unit 436, a third communication unit 516, a first storage unit 414, a second storage unit 446, a third storage unit 546, Combinations thereof, or portions thereof, may be removed from the first device 102, the second device 106, the third device 108, or a combination thereof. For example, non-transitory computer readable media can be non-transitory memory cards or sticks, external hard disk drives, tape cassettes, or optical disks.

The physical transformation of the precoding mechanism, such as the entire precoding mechanism 134, the first precoding mechanism 136, the second precoding mechanism 138, or a combination thereof, of FIG. 1 may be performed using precoding mechanisms Such as content that is displayed or regenerated for a user on the first device 102 from processing the entire communication content 114 of FIG.

The content regenerated on the first device 102, such as navigation information or the voice signal of the person making the call, may be influenced by the user's movement, such as the next navigation information or a reply back to the caller. Movements within the physical world can be feedback to the computing system and result in changes in the geographic location of the first device 102 that may be influenced by transmission devices and available resources.

Methods, processes, devices, devices, products, and / or systems are simple, cost effective, complex, versatile, accurate, sensitive, efficient, May be implemented by employing well known components for manufacture, application, and use. Another important aspect of the above-described embodiment of the present invention is that it provides valuable support and service for historical trends of cost reduction, system simplification, and performance enhancement.

As a result of the above-described other valuable aspects of the present invention, at least the state of the art to the next step is improved.

While the embodiments of the invention have been described in conjunction with a specific optimum mode, many alternatives, modifications and variations will be apparent to those skilled in the art in light of the foregoing description. Accordingly, it is to be understood that the invention includes all such alternatives, modifications and variations that fall within the scope of the claims. And all that is to be seen in the accompanying drawings shall be interpreted as being limited to the ones shown.

100: computing system 102: first device
104: network 106: second device
108: Third device 110: Blind joint transmission
112: node link 114: full communication content
116, 118: Transmission contents 120:
122, 124: Encoded sets 126, 128, 130, 132: Codewords
134: full precoding mechanism 136, 138: precoding mechanisms
140, 142: Transmitter signals 144, 146: Transmission channels
148: full rank transmission mode 152: receiver signal
154: Receiver capacity 156: Transmitter capacity
158: channel estimation 160: transmitter (transmission) channel information
162: overload transmission mode 408: first device transmission
410: second device transmission 412: first control unit
414: first storage unit 416: first communication unit
417: first inter-device interface 418: first user interface
422: first controller interface 424: first storage interface
426: first software 428: first communication interface
430: first display interface 434: second control unit
436: second communication unit 437: interface between the second devices
438: second user interface 440: second display interface
442: second software 444: second controller interface
446: Second storage unit 448: Second storage interface
450: second communication interface 510: third device transmission
534: third control unit 536: third communication unit
537: Inter-device interface 538: Third user interface
540: Third Display Interface 542: Third Software
544: Third controller interface 546: Third storage unit
548: Third storage interface 550: Second communication interface
602: Content management module 604: Encoding module
606: precoding module 608: transmission module
610: Receiver module

Claims (10)

Identifying a portion of the entire communication content or the entire communication content for blind-joint transmission with the second device for use of the second device and the third device to transmit the entire communication content to the first device,
Generating a first set of ciphers based on the entire communication content or a portion of the total communication content for communicating with the entire communication content along a second set of ciphering for the third device,
A communication unit for determining a first procoding mechanism associated with the first set of encodings for communicating the entire communication content with an overloaded transmission mode comprising a second precoding mechanism for the third device; And
And a second encoder coupled to the communication unit for transmitting the second transmitter signal from the third device to the first encoder set and for communicating the first transmitter signal based on the first precoding mechanism, A computing system comprising an interface. The method according to claim 1,
Wherein the communication unit determines the first precoding mechanism without the use of transmitter channel information. The method according to claim 1,
Wherein the communication unit determines the first precoding mechanism in accordance with a portion of the total communication content. The method according to claim 1,
Wherein the communication unit determines the first precoding mechanism based on a total precoding mechanism along with all of the total communication content. The method according to claim 1,
The communication unit determines the first precoding mechanism based on the adjustment via the node link to adjust the second precoding mechanism with the second precoding mechanism intersecting the second device and the third device Lt; / RTI > The method according to claim 1,
The communication unit determines the blind-joint transmission for communicating the entire communication content to the first device, including an advanced receiver,
Based on a portion of the total communication content according to the second device for communicating with the first set of coded sets adjusted for the second set of coded sets based on a different portion of the total communication content according to the third device, Lt; / RTI >
Determining the first precoding mechanism for adjusting the first precoding mechanism with the second precoding mechanism for the entire rank transmission mode using the second device and the third device,
The inter-device interface transmits the first transmitter signal for communicating with the entire communication content with the first transmitter signal, which is accompanied by the second transmitter signal, based on the second encoding set and the second precoding mechanism Computing system. The method according to claim 6,
Wherein the communication unit determines the first precoding mechanism without using transmitter channel information based on a rotation pattern of the entire precoding mechanism for indicating the first precoding mechanism and the second precoding mechanism,
The communication unit determines the overall-rank transmission mode for the blind-joint transmission for communication of the entire communication content based on the advanced receiver without regard to the receiver capacity of the first device. The method according to claim 6,
The inter-device interface identifies the entire communication content in all over the node link,
Wherein the communication unit generates the first set of encoded symbols from the total communication content for a transmission slot in accordance with a full precoding mechanism. The method according to claim 6,
The inter-device interface receives only a portion of the total communication content over a node link,
Wherein the communication unit is configured to communicate with the entire communication content according to the first precoding mechanism in accordance with a portion of the entire precoding mechanism for communicating the entire communication content along the second precoding mechanism in accordance with another portion of the entire precoding mechanism To generate the first set of encoded symbols based on a portion of the first set of encoded symbols. A method of operating a computing system,
Identifying a portion of the entire communication content or the entire communication content for blind-joint transmission with a second device for use in a third device and a second device for transmitting the entire communication content to a first device;
Generating a first set of communications according to a portion of the total communication content and the entire communication content to communicate with the entire communication content according to a second set of encoding for the third device;
Determining a communication unit of a first precoding mechanism associated with the first set of encoded bits to communicate with the entire communication content having an overloaded transmission mode comprising a second precoding mechanism for the third device;
And communicating the first transmitter signal based on the first encoding set and the first precoding mechanism for communicating with the first transmitter signal accompanying the second transmitter signal from the third device.

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