• 专利附录
  • 专利说明
  • 权利要求
  • 类似技术
  • 同族专利
  • 引用文献
  • 法律状态
  • 优先权
    • 专利摘要:
    The invention relates to a discontinuous transmission method for base station of a small cell in a heterogeneous network. Depending on the state of filling of the buffer or the lifetime of the data, the base station decides to transmit the data in an elementary frame or on the contrary to put itself in standby during the duration of this frame. In the case where it decides to transmit the data, it makes sure that no base station of a small neighboring cell is transmitting. Otherwise, it goes to sleep for a pseudo-random duration before attempting a new transmission of said data.
    公开号:FR3023438A1
    申请号:FR1456304
    申请日:2014-07-02
    公开日:2016-01-08
    发明作者:Dimitri Ktenas;Domenico Antonio De
    申请人:Commissariat a lEnergie Atomique CEA;Commissariat a lEnergie Atomique et aux Energies Alternatives CEA;
    IPC主号:
    专利说明:

    [0001] TECHNICAL FIELD The present invention relates generally to the field of cellular telecommunications and more particularly to that of heterogeneous networks in which macro-cells and small cells coexist. BACKGROUND OF THE INVENTION (small cells in 3GPP / LTE-Advanced terminology), including pico-cells and femto-cells. STATE OF THE PRIOR ART Conventional second or third generation cellular systems generally call for the deployment of cells of one and the same type. On the other hand, 4th generation cellular systems such as those obeying the "LTE-advanced" standard can use superposed layers of cells of different sizes. Thus, small cells served by base stations of relatively low transmission power (of a few Watts) can coexist with conventional macrocells (a few tens of Watts). In addition, the small cells are characterized by a power consumption of the order of ten Watts while the macro-cells can consume up to 1300 Watts. One of the functions of macro-cells is to provide coverage and management of user mobility, while small cells can be dynamically activated to cope with peak traffic or to cover hot spots. In the following we will call small cells, cells of smaller size than conventional macro-cells and coexisting with them in a heterogeneous network (also called "Het Net"). Thus, the term "small cell" is understood in the following generically and covers in the following both the concepts of femto-cells (femtocells) than micro-cells (microcells) or picocells (picocells) . Small cells use a carrier frequency different from that used by the macro-cell. Thus, there is no interference from the macrocell on small cell users. To fix ideas, small cells have a coverage of ten meters to a hundred meters. They are generally deployed in urban or residential environments and installed in public places of high traffic or high traffic. They can also be used to improve throughput and coverage in businesses or individuals. The density of small cells can reach up to a thousand per macro-cell.
    [0002] This multiplication of small cells leading to a significant consumption of energy in the network, we use a mechanism of intelligent and dynamic activation of these cells to limit the average energy consumption while ensuring the quality of service (QoS) required. One of the activation mechanisms currently envisaged is to switch off (or put to sleep) the base station serving a small cell when it has no data to transmit. More specifically, the base station disables certain components of its RF stage in the absence of data to be transmitted on the downlink. Such a discontinuous transmission mode or DTX (Discontinuous Tansmission) has been described in the article by P. Frenger et al. entitled "Reducing energy consumption in LTE with cell DTX" published in IEEE Proc. of 73rd Vehicular Technology Conference, pp. 1-5, May 15-18, 2011. This mode of discontinuous transmission is however incompatible with the need to transmit certain pilot signals and this, in the absence of any active user in the small cell. Thus, for example, version 10 (release 10) of the 3GPP standard "LTE advanced" provides for transmission in each subframe of a radio frame (an LTE radio frame consists of 10 subframes each having a frame). duration of 1 ms), pilot signals known as specific reference signals or CSRSs (Cell Specific Reference Signals) allowing inter alia the management of the mobility of the users (cell search mechanism), the downlink channel estimation between each antenna of the base station and the user terminal and the evaluation of the quality of the channel on the downlink. Fig. 1 schematically shows a radio frame for the downstream path of an LTE network.
    [0003] It will be recalled that, in an LTE system, downlink transmission is performed by Orthogonal Frequency Division Multiple Access (OFDMA). The CSRS signals are in fact OFDM pilot symbols repeating each subframe T as shown in the figure. Due to the structure of the LTE frame, it is understood that the transmission interruption can occur only between the transmission times of the pilot symbols CSRS, that is to say for a maximum duration 9 between these instants. This particular mode of interruption of transmission between pilot symbols is known in the literature under the name of micro-DTX (micro-discontinuous transmission). In particular, a description of the micro-DTX transmission mode can be found in the article by P. Frenger mentioned above. However, the energy gains of a micro-discontinuous transmission are relatively limited because it can be shown that the RF stage of the base station can be deactivated at most 53% of the time in the absence of data to be transmitted. .
    [0004] Greater energy savings can be achieved by adopting a new LTE frame structure, called NCT (New Carrier Type), to adapt the signaling to the load of the cell. This new frame is characterized in that the pilot signals are transmitted in a sub-frame only to the extent that data are to be transmitted. The adoption of this new frame structure makes it possible to interrupt transmission up to 4 consecutive sub-frames, since synchronization signals must be transmitted every 5 subframes in order to synchronize the different users. Another solution is to deport most of the control signals to the macro-cell. It is then responsible for managing mobility and connection establishment functionalities while small cells are primarily responsible for routing data. The offset of the control signals makes it possible to sleep more easily the small cells and thus to further reduce the energy consumption. This strategy is known in the state of the art under the name of macro-assistance. A description of this strategy is given in the Ericsson white paper entitled "LTE release 12", January 2013. However, this assumes dual connectivity, in the sense that the user's terminal must be able to establish a connection to both with the base station of the macro-cell and with the base station of the small cell on which it depends.
    [0005] Whatever the discontinuous transmission solution adopted, with or without macro-assistance, the small cells activate and go out disordered in a heterogeneous cellular network. This disordered activation impairs the reliability of the estimation of the channel, this estimate can only be realized when the small cell on which the user depends is active. In addition, when several neighboring cells are activated at the same time, the users of these cells can perceive interference peaks which increase the packet error rate and thus substantially reduce the transmission performance.
    [0006] The object of the present invention is therefore to propose a discontinuous mode of transmission for base station of a small cell in a heterogeneous network, which does not have the drawbacks of the state of the art, in other words, which makes it possible to achieve a significant reduction in network energy consumption without significantly reducing transmission performance.
    [0007] DISCLOSURE OF THE INVENTION The present invention is defined by a discontinuous transmission method for a base station of a small cell in a heterogeneous network, said base station being adapted to transmit data on the downlink using elementary frames. , said method comprising the following steps: the base station determines from the state of its transmission buffer if data are to be transmitted and, if not, the base station deactivates all or part of its stage RF for the duration of the elementary frame; - If yes, the base station determines if a base station of a small neighboring cell is transmitting, and - if it is not, transmits the data in the basic frame; if so, wait for a pseudo-random duration before attempting a new transmission of said data. Advantageously, the base station determines whether data is to be transmitted by comparing the amount of data stored in the buffer with a minimum amount of data.
    [0008] The minimum amount of data can be obtained depending on the capacity of the downlink channel and the duration of the basic frame. According to one variant, the base station determines whether data are to be transmitted by comparing the remaining lifetime of the data stored in the buffer with a predetermined threshold value.
    [0009] In a first variant, the base station determines whether a base station of a small neighboring cell is transmitting by listening to pilot signals thereof. According to a second variant, the base station determines whether a base station of a small neighboring cell is transmitting from the signal-to-noise ratio plus interference of its uplink. According to a third variant, the base station determines whether a base station of a small neighboring cell is transmitting from transmission statistics of the latter.
    [0010] According to a fourth variant, the base station determines whether a base station of a small neighboring cell is transmitting from information transmitted by the latter, via a wired transmission channel or a radio transmission channel. Whatever the variant, when the base station determines that no neighboring cell base station is transmitting, it can transmit pilot symbols in addition to all or part of the data stored in the buffer. Further, when the base station determines that a base station of a small neighboring cell is transmitting, the pseudo-random duration for the new transmission can be obtained as the product of a base duration with a pseudo-random number taking its values in a given interval.
    [0011] This basic duration can be obtained from a filling state of the buffer and / or the remaining life of the data stored therein. In addition, when the base station determines that data is to be transmitted, it advantageously calculates a cost function dependent on the average energy consumption of the base station and a quality of service indicator, said cost function being an increasing function of the average energy consumption and the quality of service indicator, and if the value of the cost function is greater than a predetermined maximum value, the base station deactivates all or part of its RF stage for the duration of the elementary field. The cost function is for example a linear combination of the energy consumption of the base station and a quality of service indicator. In a typical embodiment, the heterogeneous network is an advanced LTE network. BRIEF DESCRIPTION OF THE DRAWINGS Other features and advantages of the invention will appear on reading a preferred embodiment of the invention with reference to the appended figures in which: FIG. 1 schematically shows the structure of an LTE radio frame on the downlink; Fig. 2 schematically represents a discontinuous transmission method for a base station of a small cell in a heterogeneous network, according to a first embodiment of the invention; Fig. 3 schematically represents a discontinuous transmission method for a base station of a small cell in a heterogeneous network, according to a second embodiment of the invention. DETAILED DESCRIPTION OF PARTICULAR EMBODIMENTS A heterogeneous cellular telecommunication network will be considered in the following, composed of a first layer of macro-cells and a second layer of small cells in the sense defined above, for example a type network. LTE advanced. Those skilled in the art will understand that other types of heterogeneous networks may also be envisaged, combining different access networks, without departing from the scope of the present invention. For example, the invention will be applicable to a multi-RAT (RAT: Radio Access Technology) network for accessing GSM / UMTS / LTE and WiFi networks. A description of a multi-RAT network can be found in the article by P. Xing et al., Entitled "Multi-RAT network architecture", Wireless World Research Forum, version 2.0, November 2013. Regardless of the heterogeneous network envisaged, it will be assumed that each small cell in the network is served by a base station that can be dynamically activated or dormant. Activation / sleep of a base station means activation / dormant of all or part of the RF stage of its transmitter, in particular the power amplifiers that it comprises. In addition to the RF stage (or only part of it), some circuits of the modulation stage (OFDM modulation stage in the case of an LTE advanced network) can also be activated / implemented. sleep. It will further be assumed that the data is transmitted in the form of elementary frames (for example, sub-frames in an LTE system). The principle of the invention is not to activate the base station when it has no data to transmit on the downlink and, conversely, to verify that the base stations of the small neighboring cells are not transmitting, before transmitting the data, and if necessary pilot symbols, in an elementary frame.
    [0012] More specifically, FIG. 2 represents a discontinuous transmission method for a base station of a small cell, according to a first embodiment of the invention.
    [0013] In step 210, the base station acquires the state of its transmit buffer. In step 220, the base station checks the status of this buffer. The checking of the state of the buffer can consist simply in checking the presence of a minimal amount of data to be transmitted. When the amount of data is sufficient, the base station proceeds to step 250. The quantity is deemed sufficient if it exceeds a minimum amount of data, which is a function of the downlink capacity and the duration of the basic frame. . If the amount of data is insufficient, the base station goes into sleep at 225 until the beginning of the next elementary frame, by deactivating all or part of its RF stage. However, even if the amount of data is insufficient but the remaining life of some data in the buffer is below a predetermined threshold (latency constraint for real-time data, for example), the base station still needs to be updated. Step 250. According to an alternative embodiment, it can be provided that the buffer is split into two parts, a first part containing the data subject to a latency constraint (for example real time flow) and a second part containing the other data. When the remaining lifetime of the data in the first part of the buffer is less than said threshold but the quantity of these data is less than the minimum quantity mentioned above, they are supplemented by data stored in the second part, up to the amount of said quantity. minimum, before proceeding to step 250.30 In step 250, the base station determines whether a base station of a small neighboring cell is transmitting. According to a first variant, the base station can listen to pilot signals transmitted by the neighboring base stations. If it detects the presence of such pilot signals, it deduces that at least one base station of a neighboring cell is being transmitted. In a second variant, it measures the signal-to-noise plus interference ratio (SINR) on the uplink. If this ratio is greater than a predetermined level, it concludes that a broadcast is in progress in a small neighboring cell. According to a third variant, the base station uses the transmission statistics of the base stations of the small neighboring cells to predict whether or not an emission will take place in one of them during the elementary frame. These statistics may have been established using prior measurement campaigns or may result from learning as successive transmission attempts are made. Finally, according to a fourth variant, if an exchange of information between base stations of small neighboring cells is possible, whether by wire or by a dedicated radio channel, each base station can be directly informed that a station of neighboring base is transmitting. This information exchange can be done from base station to base station or coordinated locally by a control station in charge of a set (cluster) of small neighboring cells. The control station may be only a particular base station. It should be noted that, in this case, other information can be exchanged between neighboring base cells, in particular the states of their respective buffers or the latency constraints of their respective data. Thus, thanks to this information, when several neighboring base stations are preparing to transmit simultaneously, an arbitration can be performed, either distributed or centrally, to determine the one that will emit priority. Whatever the variant envisaged, if the base station determines that a base station of a small neighboring cell is being transmitted, it goes into sleep for a pseudo-random duration at 255. This pseudo-random duration random can be proportional to a base duration which is a function of latency constraints of the data stored in the buffer (or in its first part, in the variant mentioned above) and / or the filling state of the buffer. Thus, this base time will be shorter as the remaining life of the data will be low and / or the buffer will be filled. The pseudo-random duration can be calculated as the product of the basic duration by a pseudo-random number obtained by drawing within a given interval. At the end of this pseudo-random duration, the base station returns to step 250 for a new transmission attempt. On the other hand, if in step 250 the base station determines that no neighboring small cell base station transmits data, it proceeds to transmission step 260.
    [0014] In step 260, the base station transmits during the current elementary frame, the data stored in its buffer, on the downstream channel. It can also transmit during the same elementary frame pilot symbols allowing users of the small cell to perform a channel estimation. This channel estimate can then be sent to the base station as a Channel State Indicator or CSI (Channel State Indicator). The base station may choose to transmit pilot symbols or not with the data depending on whether or not it needs to update its knowledge of the state of the channel. This choice may in particular depend on the quality of service (QoS) required, the buffer state as defined above, and the quality of the radio channel (attenuation, presence or absence of interfering). It will be understood that if the quality of service is high and / or if the data to be transmitted belong to real-time traffic, pilot symbols must be transmitted with the data in the elementary frame. At the end of the transmission of the elementary field, we return to step 210 for a new acquisition of the state of the buffer.
    [0015] Fig. 3 represents a discontinuous transmission method for a base station of a small cell, according to a second embodiment of the invention. The steps 310 to 360 are identical to the steps 210 to 260 and their description will therefore be omitted here.
    [0016] The second embodiment differs from the first embodiment in that the data transmission on the downstream channel is subject to the realization of an additional condition in step 330. Indeed, at this stage, a function of cost depending on the average energy consumption of the base station and a quality of service indicator (QoS). Depending on the case, this quality of service indicator can be defined as the inverse of the average latency of packets transmitted on the downstream channel or the packet error rate, or as the average bit rate. In general, the cost function is an increasing function of the average base station energy consumption and the quality of service indicator observed on the downstream path.
    [0017] For example, the cost function can be expressed in the form of a linear combination: F (E, D) = yE + (1 - y) D where É is the average energy consumed by the base station, D is the aforementioned quality of service indicator and is a parameter between 0 and 1 weighting the relative importance respectively given to energy consumption and quality of service. Other expressions of the cost function can be envisaged by those skilled in the art without departing from the scope of the present invention, for example a multiplicative combination of the type: F (E, D) = EYD1-Y The cost function can not be fully recalculated at each elementary field but simply be updated by means of a recursive low-pass filter with forgetting factor. Alternatively, the cost function can be calculated beforehand and its values stored in a look-up table indexed by the average energy and the service indicator.
    [0018] In step 340, it is checked whether the cost is lower than a predetermined maximum cost. If this is the case, we go to step 350 for a transmission attempt. Otherwise, the base station is muted at 355 until the beginning of the next elementary frame.
    权利要求:
    Claims (14)
    [0001]
    REVENDICATIONS1. A discontinuous transmission method for a base station of a small cell in a heterogeneous network, said base station being adapted to transmit data on the downlink using elementary frames, characterized in that: - the base station determines (220, 320) from the state of its transmission buffer if data are to be transmitted and, if not, the base station deactivates (225, 325) all or part of its RF stage for the duration the elementary field; - if so, the base station determines (250, 350) whether a base station of a small neighboring cell is transmitting, and - if it is not, transmits (260, 360 ) the data in the elementary field; if so, wait for a pseudo-random duration (255, 355) before attempting a new transmission of said data.
    [0002]
    A discontinuous transmission method according to claim 1, characterized in that the base station determines whether data is to be transmitted by comparing the amount of data stored in the buffer with a minimum amount of data.
    [0003]
    A discontinuous transmission method according to claim 2, characterized in that the minimum amount of data is obtained depending on the capacity of the downlink channel and the duration of the elementary field.
    [0004]
    A discontinuous transmission method according to claim 1, characterized in that the base station determines whether data is to be transmitted by comparing the remaining lifetime of the data stored in the buffer with a predetermined threshold value.
    [0005]
    5. Discontinuous transmission method according to one of the preceding claims, characterized in that the base station determines whether a base station of a small neighboring cell is transmitting by listening to pilot signals thereof.
    [0006]
    The discontinuous transmission method according to one of claims 1 to 4, characterized in that the base station determines whether a base station of a neighboring small cell is transmitting from the signal-to-noise ratio plus interference from its rising path.
    [0007]
    Batch transmission method according to one of claims 1 to 4, characterized in that the base station determines whether a base station of a neighboring small cell is transmitting from transmission statistics of the latter.
    [0008]
    A discontinuous transmission method according to one of claims 1 to 4, characterized in that the base station determines whether a base station of a neighboring small cell is transmitting from information transmitted by that base station. last, via a wired transmission channel or a radio transmission channel.
    [0009]
    9. discontinuous transmission method according to one of the preceding claims, characterized in that when the base station determines that no neighboring cell base station is transmitting, transmits pilot symbols in addition to any or part of the data stored in the buffer.
    [0010]
    10. discontinuous transmission method according to one of the preceding claims, characterized in that when the base station determines that a base station of a small neighboring cell is transmitting, the pseudo-random duration for the new transmission is obtained as the product of a base duration with a pseudo-random number taking its values in a given interval.
    [0011]
    11. Discontinuous transmission method according to claim 10, characterized in that the base duration is obtained from a filling state of the buffer and / or the remaining life of the data stored therein.
    [0012]
    Discontinuous transmission method according to one of the preceding claims, characterized in that, when the base station determines that data are to be transmitted, the latter calculates (330) a cost function depending on the average energy consumption of the the base station and a quality of service indicator, said cost function being an increasing function of the average energy consumption and the quality of service indicator, and if the value of the cost function is greater than a predetermined maximum value (340), the base station deactivates (345) all or part of its RF stage for the duration of the elementary field.
    [0013]
    Discontinuous transmission method according to one of the preceding claims, characterized in that the cost function is a linear combination of the energy consumption of the base station and a quality of service indicator.
    [0014]
    14. Discontinuous transmission method according to one of the preceding claims, characterized in that the heterogeneous network is an advanced LTE network.
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    法律状态:
    2015-07-31| PLFP| Fee payment|Year of fee payment: 2 |
    2016-01-08| PLSC| Search report ready|Effective date: 20160108 |
    2016-07-29| PLFP| Fee payment|Year of fee payment: 3 |
    2018-04-27| ST| Notification of lapse|Effective date: 20180330 |
    优先权:
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    FR1456304A|FR3023438B1|2014-07-02|2014-07-02|DISCONTINUOUS TRANSMISSION METHOD FOR BASE STATION OF A SMALL CELL IN A HETEROGENEOUS NETWORK|FR1456304A| FR3023438B1|2014-07-02|2014-07-02|DISCONTINUOUS TRANSMISSION METHOD FOR BASE STATION OF A SMALL CELL IN A HETEROGENEOUS NETWORK|
    US14/789,007| US20160007280A1|2014-07-02|2015-07-01|Discontinuous transmission method for base station of a small cell in a heterogeneous network|
    EP15174782.1A| EP2963991A1|2014-07-02|2015-07-01|Discontinuous transmission method for a base station of a small cell in a heterogeneous network|
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