Patent Description:
Multi-carrier modulation (MCM) is used in many communication systems due to its advantages regarding flexibility, multi-user support and link adaptation.

Typical multi-carrier modulation schemes include orthogonal frequency division multiplexing (OFDM) modulation and filter-bank multi-carrier (FBMC) modulation. Filter-bank multi-carrier modulation is a promising candidate for next generation mobile communication networks since, in comparison with other multi-carrier modulation schemes, it has advantages such as low out-of-band radiation, and no need for a cyclic prefix (CP).

One of the major challenges for multi-carrier transmission is the energy consumption of communication devices, which affects the battery life time of the communication devices.

Among a number of factors, the peak-to-average power ratio (PAPR) of the multi-carrier communication signals has a major impact on the energy consumption, since it is directly related to the power efficiency of power amplifiers (PA) within the communication devices.

In <NPL>, an iterative clipping base approach is described to reduce the peak-to-average power ratio of filter-bank multi-carrier communication signals. However, the iterative clipping based approach causes high processing complexity and processing delay and/or strong nonlinear distortions and spectrum regrowth, i.e. an increased out-of-band emission, of the multi-carrier communication signals.

In <NPL>, filter-bank spread and discrete Fourier transform (DFT) spread based approaches are described to reduce the peak-to-average power ratio of filter-bank multi-carrier communication signals. Besides having a high processing complexity, these approaches achieve a minor reduction of the peak-to-average power ratio. Moreover, the approaches result in an increased processing delay and longer tails of the multi-carrier communication signals.

In <NPL>), a single-carrier filter-bank multi-carrier (SC-FBMC) modulation is described. In this approach, the overall communication signal can be formed by a pure single carrier communication signal having a reduced peak-to-average power ratio using one filter for the entire transmission bandwidth. However, this causes a reduced flexibility of communications within communication networks.

In <CIT>, a flexible employment of frame configuration in light of the Doppler frequency change is proposed. According to said document, frame configuration for a predetermined frequency band may be changed. Changing a frame configuration may include changing subcarrier spacing. Furthermore, in said document, an efficiency in terms of energy is given as the formula: <NUM>/(<NUM>+ Δf * TCP), wherein Δf is the subcarrier spacing and TCP is the Guard Interval/Cyclic Prefix.

<CIT> discloses a base station, comprising: a transceiver for multi-carrier radio transmission within a radio frequency band, the transceiver being adapted to receive service quality requests of a plurality of users requesting service from the base station; and a radio resource controller being adapted to allocate subcarriers of the multi-carrier radio transmission to the users and to configure the subcarriers in the radio frequency band according to the service quality requests of the users.

When managing communications of a plurality of communication devices within a communication network, it is desirable to consider the energy efficiency for the plurality of communication devices during communications over the communication network.

It is an object of the invention to provide an efficient concept for managing communications of a plurality of communication devices within a communication network.

This object is achieved by the features of the independent claims.

The invention is based on the finding that a sub-carrier frequency spacing of a multi-carrier communication signal transmitted by a communication device is adjusted upon the basis of an energy efficiency indicator provided by the communication device. The number of sub-carriers for a given transmission bandwidth and subsequently the sub-carrier frequency spacing, has a direct impact on the peak-to-average power ratio of the multi-carrier communication signal, which on its part directly relates to the energy efficiency of an amplifier, e.g. a power amplifier, of the communication device.

The adjustment can be performed for a plurality of communication devices based on a frame structure for communications within the communication network. The frame structure can be adapted, thereby exploiting the flexibility of multi-carrier modulation schemes. Consequently, an efficient concept for managing communications within the communication network is provided, which allows for an increased energy efficiency of the plurality of communication devices within the communication network. Energy efficiency specifications of the plurality of communication devices are met by this kind of radio resource management and adaptive transmission over the communication network.

According to a first aspect, the invention relates to a network entity according to independent claim <NUM>. Therewith, an efficient concept for managing communications of the plurality of communication devices within the communication network is realized. The concept being energy efficient.

The network entity can be a base station or a relay station of the communication network or an autonomous transmission terminal. The network entity can be configured to adapt a frame structure for communications of the plurality of communication devices within the communication network, wherein the frame structure can comprise a plurality of resource blocks.

The multi-carrier communication signal can be a filter-bank multi-carrier (FBMC) communication signal. The energy efficiency indicator can be an Energy Efficiency Requirement Indicator (EERI). The resource block indicator indicates the sub-carrier frequency spacing in units of Hz or its temporal counterpart, a symbol duration, in units of seconds.

In a first implementation form of the network entity according to the first aspect as such, the processor is further configured to determine a number of sub-carriers of the multi-carrier communication signal upon the basis of the energy efficiency indicator, wherein the resource block indicator further indicates the number of sub-carriers of the multi-carrier communication signal. In this way, the peak-to-average power ratio of the multi-carrier communication signal can further be adjusted.

The number of sub-carriers times the sub-carrier frequency spacing equals the bandwidth of the multi-carrier communication signal transmitted by a communication device. The number of sub-carriers can further be determined upon the basis of a receiving power indicator, a data rate indicator, and/or a number of communication devices. The multi-carrier communication signal is transmitted by the communication device.

In a typical uplink communication, the number of frequency sub-carriers of each communication device, e.g. user equipment (UE), can be determined. Each communication device transmits a multi-carrier communication signal. The multi-carrier communication signals of all communication devices can aggregate to an overall multi-carrier communication signal which is received by the network entity, e.g. a base station. In this context, an individual multi-carrier communication signal of an individual communication device is considered.

In a second implementation form of the network entity according to the first aspect as such or any preceding implementation form of the first aspect, the processor is further configured to determine a lower transmission frequency of the multi-carrier communication signal, an upper transmission frequency of the multi-carrier communication signal, and/or a transmission time slot of the multi-carrier communication signal, wherein the resource block indicator further indicates the lower transmission frequency, the upper transmission frequency, and/or the transmission time slot of the multi-carrier communication signal. Thus, radio resources for communications within the communication network can be allocated.

The transmission bandwidth of the multi-carrier communication signal can be indicated by a difference between the upper transmission frequency and the lower transmission frequency. The upper transmission frequency and the lower transmission frequency can define a transmission bandwidth of a transmitted multi-carrier communication signal of a communication device.

In a third implementation form of the network entity according to the first aspect as such or any preceding implementation form of the first aspect, the sub-carrier frequency spacing of the plurality of sub-carriers is an integer multiple of a predetermined sub-carrier frequency spacing associated with the communication network. Thus, the sub-carrier frequency spacing can be determined efficiently.

The predetermined sub-carrier frequency spacing can be a minimum sub-carrier frequency spacing derived from a predetermined sub-carrier frequency grid associated with a frame structure of the communication network.

In a fourth implementation form of the network entity according to the first aspect as such or any preceding implementation form of the first aspect, the communication interface is further configured to transmit a reference signal over the communication network to the communication device, and to receive a receiving power indicator over the communication network from the communication device, wherein the receiving power indicator indicates a path loss of the reference signal, and wherein the processor is further configured to determine the sub-carrier frequency spacing upon the basis of the receiving power indicator. Thus, propagation characteristics of the reference signal can be considered for managing communications within the communication network.

The processor can further be configured to determine the number of sub-carriers of the multi-carrier communication signal upon the basis of the receiving power indicator. The receiving power indicator can be a Reference Signal Receiving Power (RSRP) indicator. The reference signal can be a pilot signal. The path loss can be a propagation path loss.

In a fifth implementation form of the network entity according to the first aspect as such or any preceding implementation form of the first aspect, the communication interface is further configured to receive a data rate indicator over the communication network from the communication device, wherein the data rate indicator indicates a data rate specification of the communication device, and wherein the processor is further configured to determine the sub-carrier frequency spacing upon the basis of the data rate indicator. Thus, desired data rates can be considered for managing communications within the communication network.

The processor can further be configured to determine the number of sub-carriers of the multi-carrier communication signal upon the basis of the data rate indicator.

In a sixth implementation form of the network entity according to the first aspect as such or any preceding implementation form of the first aspect, the processor is configured to determine the sub-carrier frequency spacing of the plurality of sub-carriers upon the basis of a number of communication devices within the plurality of communication devices. Thus, the sub-carrier frequency spacing can be determined efficiently. The network entity can adapt the frame structure according to the number of communication devices.

The processor can further be configured to determine the number of sub-carriers of the multi-carrier communication signal upon the basis of the number of communication devices. The processor can be configured to determine the number of communication devices within the plurality of communication devices. The number of communication devices can serve as an input parameter based on which the frame structure and/or the frequency sub-bands having different sub-carrier frequency spacings can be adjusted. The number of communication devices can e.g. be <NUM>, <NUM>, <NUM>, <NUM>, <NUM>, <NUM> or <NUM>.

According to a second aspect, the invention relates to a communication device according to independent claim <NUM>. Thus, an efficient concept for managing communications of the plurality of communication devices within the communication network is realized.

The communication device can be a user equipment (UE). The energy efficiency specification is derived upon the basis of a battery status of the communication device or the energy efficiency specification of the communication device is predetermined, e.g. by an energy efficiency category of the communication device.

In a first implementation form of the communication device according to the second aspect as such, the resource block indicator further indicates a number of sub-carriers of the multi-carrier communication signal, a lower transmission frequency of the multi-carrier communication signal, an upper transmission frequency of the multi-carrier communication signal, and/or a transmission time slot of the multi-carrier communication signal, wherein the processor is further configured to generate the multi-carrier communication signal upon the basis of the number of sub-carriers, the lower transmission frequency, the upper transmission frequency, and/or the transmission time slot. Thus, the multi-carrier communication signal can be generated efficiently.

In a second implementation form of the communication device according to the second aspect as such or any preceding implementation form of the second aspect, the communication interface is further configured to receive a reference signal over the communication network, wherein the processor is further configured to generate a receiving power indicator upon the basis of the reference signal, wherein the receiving power indicator indicates a path loss of the reference signal, and wherein the communication interface is further configured to transmit the receiving power indicator over the communication network. Thus, propagation characteristics of the reference signal can be considered for managing communications within the communication network.

In a third implementation form of the communication device according to the second aspect as such or any preceding implementation form of the second aspect, the processor is further configured to generate a data rate indicator indicating a data rate specification of the communication device, wherein the communication interface is further configured to transmit the data rate indicator over the communication network. Thus, desired data rates can be considered for managing communications within the communication network.

In an example form of the communication device according to the second aspect as such or any preceding implementation form of the second aspect, the communication interface comprises an amplifier being configured to amplify the multi-carrier communication signal, wherein the amplifier has an adjustable amplifying back-off, wherein the processor is further configured to determine a peak-to-average power ratio of the multi-carrier communication signal, and to adjust the amplifying back-off of the amplifier upon the basis of the determined peak-to-average power ratio. Thus, the energy efficiency of the communication device can be adjusted efficiently.

The number of sub-carriers and consequently the sub-carrier frequency spacing directly relates to the peak-to-average power ratio. The peak-to-average power ratio directly relates to the energy efficiency of the amplifier and/or of the communication device. The amplifier can be a power amplifier (PA).

A communication system not covered by the claims comprises a network entity for managing communications of a plurality of communication devices within a communication network, and a communication device for transmitting a multi-carrier communication signal over the communication network. Thus, an efficient concept for managing communications of the plurality of communication devices within the communication network is realized.

The communication system can be a centralized cellular communication system or a device-to-device (D2D) communication system that may either operate stand-alone or under assistance of a cellular infrastructure. The network entity and the communication device can communicate with each other over the communication network.

According to a third aspect, the invention relates to a frame structure according to independent claim <NUM>. Thus, an efficient concept for managing communications of the plurality of communication devices within the communication network is realized.

The network entity can be configured to adapt the frame structure. The communication device can be configured to transmit the multi-carrier communication signal according to the frame structure.

The first resource block can be arranged within a first lower transmission frequency and a first upper transmission frequency. The second resource block can be arranged within a second lower transmission frequency and a second upper transmission frequency. The first sub-carrier frequency spacing and the second sub-carrier frequency spacing can be different.

In an example form of the frame structure according to the fourth aspect as such, the first resource block of the plurality of resource blocks comprises a first plurality of transmission time slots, and the second resource block of the plurality of resource blocks comprises a second plurality of transmission time slots. Thus, a transmission time slot can be allocated to a communication device.

The plurality of resource blocks is a plurality of time-frequency resource blocks. The plurality of resource blocks can have different sub-carrier frequency spacings and time durations. Each resource block of the plurality of resource blocks can accommodate multi-carrier communication signals of multiple communication devices for simultaneous transmission, e.g. using different sub-carrier sets.

According to a fourth aspect, the invention relates to a method for managing communications of a plurality of communication devices according to independent claim <NUM>. Thus, an efficient concept for managing communications of the plurality of communication devices within the communication network is realized.

The method can be performed by the network entity. Further features of the method directly result from the functionality of the network entity.

According to a fifth aspect, the invention relates to a method for transmitting a multi-carrier communication signal over a communication network according to independent claim <NUM>. Thus, an efficient concept for managing communications of the plurality of communication devices within the communication network is realized.

The method can be performed by the communication device. Further features of the method directly result from the functionality of the communication device.

According to a sixth aspect, the invention relates to a computer program according to independent claim <NUM>. Thus, the methods can be performed in an automatic and repeatable manner. The network entity and/or the communication device can be programmably arranged to perform the computer program.

The invention can be implemented in hardware and/or software.

Embodiments of the invention will be described with respect to the following figures, in which:.

<FIG> shows a diagram of a network entity <NUM> for managing communications of a plurality of communication devices within a communication network according to an embodiment.

A communication device of the plurality of communication devices is configured to transmit a multi-carrier communication signal comprising a plurality of sub-carriers, and to transmit an energy efficiency indicator indicating an energy efficiency specification of the communication device.

The network entity <NUM> comprises a communication interface <NUM> being configured to receive the energy efficiency indicator over the communication network, and a processor <NUM> being configured to determine a sub-carrier frequency spacing of the plurality of sub-carriers upon the basis of the energy efficiency indicator, and to generate a resource block indicator associated with the communication device, wherein the resource block indicator indicates the sub-carrier frequency spacing, wherein the communication interface <NUM> is further configured to transmit the resource block indicator over the communication network to the communication device.

<FIG> shows a diagram of a communication device <NUM> for transmitting a multi-carrier communication signal over a communication network according to an embodiment. The multi-carrier communication signal comprises a plurality of sub-carriers.

The communication device <NUM> comprises a communication interface <NUM> being configured to transmit an energy efficiency indicator over the communication network, the energy efficiency indicator indicating an energy efficiency specification of the communication device <NUM>, and to receive a resource block indicator over the communication network, the resource block indicator indicating a sub-carrier frequency spacing of the plurality of sub-carriers, and a processor <NUM> being configured to generate the multi-carrier communication signal upon the basis of the sub-carrier frequency spacing, wherein the communication interface <NUM> is further configured to transmit the multi-carrier communication signal over the communication network.

<FIG> shows a diagram of a communication system <NUM> comprising a network entity <NUM> and a communication device <NUM> according to an embodiment. The network entity <NUM> and the communication device <NUM> communicate with each other over a communication network <NUM>.

The network entity <NUM> is configured to manage communications of a plurality of communication devices within the communication network <NUM>. The communication device <NUM> is configured to transmit a multi-carrier communication signal comprising a plurality of sub-carriers over the communication network <NUM>, and to transmit an energy efficiency indicator indicating an energy efficiency specification of the communication device <NUM> over the communication network <NUM>.

The network entity <NUM> comprises a communication interface <NUM> being configured to receive the energy efficiency indicator over the communication network <NUM>, and a processor <NUM> being configured to determine a sub-carrier frequency spacing of the plurality of sub-carriers upon the basis of the energy efficiency indicator, and to generate a resource block indicator associated with the communication device <NUM>, wherein the resource block indicator indicates the sub-carrier frequency spacing. The communication interface <NUM> is further configured to transmit the resource block indicator over the communication network <NUM> to the communication device <NUM>.

The communication device <NUM> comprises a communication interface <NUM> being configured to transmit the energy efficiency indicator over the communication network <NUM>, and to receive the resource block indicator over the communication network <NUM>, and a processor <NUM> being configured to generate the multi-carrier communication signal upon the basis of the sub-carrier frequency spacing. The communication interface <NUM> is further configured to transmit the multi-carrier communication signal over the communication network <NUM>.

<FIG> shows a diagram of a frame structure <NUM> for communications of a plurality of communication devices within a communication network according to an embodiment.

A first communication device of the plurality of communication devices is configured to transmit a first multi-carrier communication signal comprising a first plurality of sub-carriers. A second communication device of the plurality of communication devices is configured to transmit a second multi-carrier communication signal comprising a second plurality of sub-carriers.

The frame structure <NUM> comprises a plurality of resource blocks <NUM>, <NUM>, wherein a first resource block <NUM> of the plurality of resource blocks <NUM>, <NUM> comprises the first plurality of sub-carriers having a first sub-carrier frequency spacing, and wherein a second resource block <NUM> of the plurality of resource blocks <NUM>, <NUM> comprises the second plurality of sub-carriers having a second sub-carrier frequency spacing.

The first resource block <NUM> can be arranged within a first lower transmission frequency and a first upper transmission frequency. The second resource block <NUM> can be arranged within a second lower transmission frequency and a second upper transmission frequency. The first sub-carrier frequency spacing and the second sub-carrier frequency spacing can be different.

The first resource block <NUM> of the plurality of resource blocks <NUM>, <NUM> can comprise a first plurality of transmission time slots, and the second resource block <NUM> of the plurality of resource blocks <NUM>, <NUM> can comprise a second plurality of transmission time slots.

<FIG> shows a diagram of a method <NUM> for managing communications of a plurality of communication devices within a communication network according to an embodiment.

The method <NUM> comprises receiving <NUM> the energy efficiency indicator over the communication network, determining <NUM> a sub-carrier frequency spacing of the plurality of sub-carriers upon the basis of the energy efficiency indicator, generating <NUM> a resource block indicator associated with the communication device, wherein the resource block indicator indicates the sub-carrier frequency spacing, and transmitting <NUM> the resource block indicator over the communication network to the communication device.

<FIG> shows a diagram of a method <NUM> for transmitting a multi-carrier communication signal over a communication network according to an embodiment. The multi-carrier communication signal comprises a plurality of sub-carriers.

The method <NUM> comprises transmitting <NUM> an energy efficiency indicator over the communication network, the energy efficiency indicator indicating an energy efficiency specification of the communication device, receiving <NUM> a resource block indicator over the communication network, the resource block indicator indicating a sub-carrier frequency spacing of the plurality of sub-carriers, generating <NUM> the multi-carrier communication signal upon the basis of the sub-carrier frequency spacing, and transmitting <NUM> the multi-carrier communication signal over the communication network.

In the following, further implementation forms and embodiments of the network entity <NUM>, the communication device <NUM>, the communication system <NUM>, the frame structure <NUM>, the method <NUM>, and the method <NUM> are described.

The approach allows for an energy efficiency adapted transmission in communication networks, e.g. wireless communication networks, using multi-carrier communication signals, e.g. filter-bank multi-carrier communication signals.

Multi-carrier modulation is used in many communication networks due to its advantages regarding flexibility, multi-user support and link adaptation. Among different multi-carrier modulation schemes, filter-bank multi-carrier is a promising candidate for next generation mobile communications, e.g. fifth generation (<NUM>) mobile communications, since, in comparison with conventional multi-carrier modulation schemes, it has many advantages such as low out-of-band radiation, no need for cyclic prefix (CP). Moreover, it can allow for a flexible adaption of a frame structure for communications within the communication network.

<FIG> shows a diagram of a communication system <NUM> comprising a network entity <NUM> and a communication device <NUM> according to an embodiment. The network entity <NUM> can be a base station (BS) of the communication network. The communication device <NUM> can be a user equipment (UE). The communication device <NUM> can be a high end / cell center communication device <NUM>, a low end communication device <NUM>, or a cell edge communication device <NUM>. The diagram illustrates uplink transmission of different types of communication devices <NUM> having different energy efficiency specifications.

In a first exemplary application, it is considered that multi-carrier modulation schemes, such as filter-bank multi-carrier modulation, are used for uplink transmission. One of the major challenges for uplink transmission can be the energy consumption of the communication devices, which can affect the battery life of the communication devices. Therefore, energy efficiency is taken into account in the design of schemes for uplink transmission.

Among a number of factors, the peak-to-average power ratio (PAPR) of the transmit multi-carrier communication signals can have a major impact on the energy efficiency, since it can directly be related to the power efficiency of amplifiers, e.g. power amplifiers (PA), within the communication devices <NUM>, which can consume a large percentage of the total power. Generally, the lower the peak-to-average power ratio is, the higher the energy and/or power efficiency may be. In other words, the higher the peak-to-average power ratio, the lower the energy and/or power efficiency may be. Low energy efficiency can be crucial for communication devices <NUM>, in particular cell edge user equipments or low end user equipments, e.g. machine type user equipments. Therefore, sophisticated approaches are desired for an adjustment of the peak-to-average power ratio.

Embodiments of the invention exploit the flexibility of multi-carrier modulation schemes, in particular of filter-bank multi-carrier modulation, with respect to the frame structure. Thus, a flexible adjustment of the peak-to-average power ratio according to the specifications and actual transmission needs of the communication devices <NUM> is enabled.

Embodiments of the invention are analogously applied to downlink transmission or to direct device-to-device (D2D) transmission. These applications may e.g. be envisaged if energy efficiency is of importance in such kinds of transmissions.

For communication devices <NUM> located at a cell edge or low-end communication devices <NUM>, the peak-to-average power ratio can be an important parameter and its reduction can have a high priority. Therefore, it can be desirable to provide a dedicated transmission scheme for such kinds of communication devices <NUM> in order to reduce the peak-to-average power ratio.

However, reducing the peak-to-average power ratio may result in a reduction of spectral efficiency and may increase the complexity of transceivers within the communication devices <NUM>. For communication devices <NUM> located in a cell center or high-end communication devices <NUM> or communication devices <NUM> with plugged in electricity, the priority of energy efficiency can be lower compared to cell edge communication devices <NUM> or low-end communication devices <NUM>. Thus, such communication devices <NUM> can afford a higher peak-to-average power ratio and can put a higher priority on other aspects like spectral efficiency and complexity. Therefore, an uplink transmission scheme capable to dynamically adjust the peak-to-average power ratio according to the actual transmission specifications is desirable so as to optimize the trade-off between energy efficiency, spectral efficiency and complexity. For example, for communication devices <NUM> located at the cell edge and with a limited power budget, the peak-to-average power ratio can be adjusted to a low level so that the effective transmit power can be increased or that the consumed power can be reduced.

Similar challenges can occur in downlink or direct device-to-device (D2D) transmissions. One example for downlink transmission is that communication signals having a low peak-to-average power ratio, if synthesized and amplified in a dedicated manner e.g. using a separate high power amplifier (HPA), can greatly improve the transmitter power efficiency and meanwhile, help the cell edge communication devices <NUM> or low-end communication devices <NUM> to have a higher effective received communication signal power, since the dynamic range of radio frequency (RF) receivers, in particular of low noise amplifiers (LNAs) and analog-to-digital-converters (ADCs), can be exploited more efficiently.

Another example refers to the case where a low-cost relay station or a small base station shares spectrum with a macro base station. The relay station or small base station may transmit only in a frequency sub-band of the entire shared spectrum and may adjust the peak-to-average power ratio in this frequency sub-band according to the linearity of its radio frequency transmitter. Similarly, in the direct device-to-device (D2D) case, the transmitter may transmit a multi-carrier communication signal only in a frequency sub-band of the entire downlink and/or uplink spectrum. It may be able to adjust the peak-to-average power ratio of its multi-carrier communication signal in this frequency sub-band according to its energy efficiency specification.

<FIG> shows a diagram of a frame structure <NUM> for communications of a plurality of communication devices within a communication network according to an embodiment. The frame structure <NUM> is illustrated in terms of time versus frequency. The frame structure <NUM> comprises a first resource block <NUM> having a small sub-carrier frequency spacing, and a second resource block <NUM> having a large sub-carrier frequency spacing. A resource block is allocated to each communication device according to specifications on energy efficiency and data rate. The diagram illustrates the principle of an uplink frame structure allowing for different sub-carrier frequency spacings in different resource blocks.

Embodiments of the invention apply a transmission scheme based on filter-bank multi-carrier modulation, and exploit the flexibility of multi-carrier modulation, in particular of filter-bank multi-carrier modulation, with respect to the frame structure <NUM>. Since the frame structure <NUM> allows for adjusting the sub-carrier frequency spacing in different resource blocks, the peak-to-average power ratio of the multi-carrier communication signals in each resource block is adjusted flexibly. Thus, an adjustment of the energy efficiency of communication devices <NUM> is performed according to actual specifications for transmission.

For a given transmission bandwidth, e.g. of a user equipment, a base station or a relay station, the larger the sub-carrier frequency spacing, the smaller the number of sub-carriers may be in a transmitted multi-carrier communication signal. Here, a localized allocation of sub-carriers can be assumed, i.e. only contiguous sub-carriers may be allocated. A smaller number of sub-carriers can lead to a reduced peak-to-average power ratio. Based on the above observations, it is possible to achieve an adjustment of the relevant peak-to-average power ratio by adjusting the sub-carrier frequency spacing of each communication device <NUM>. This can be an effective and flexible way to adjust the peak-to-average power ratio, which can allow for a low implementation complexity.

The adjustment of the sub-carrier frequency spacing and thus the adjustment of the relevant peak-to-average power ratio can be realized by the following approaches.

Firstly, a definition of a flexible uplink and/or downlink frame structure <NUM> can be provided which comprises uplink (UL) and/or downlink (DL) resource blocks and/or transmission time slots with different bandwidths and sub-carrier frequency spacings for communication devices <NUM> having different energy efficiency specifications. The numbers of resource blocks with different sub-carrier frequency spacing can be adapted according to numbers of communication devices <NUM> having different energy efficiency specifications. As an option, resource blocks with the same sub-carrier frequency spacing can be arranged such that they are neighboring each other.

Secondly, a configuration of the uplink and/or downlink transmission scheme to dedicated users, i.e., communication devices <NUM>, can be performed. The transmission scheme can be defined to be compatible to the above-defined frame structure <NUM>. According to the transmission scheme, each communication device <NUM> can be allocated to a certain resource block and/or transmission time slot. This can be performed based on a power control mechanism, e.g. an open-loop power control mechanism, it is adopting, e.g. for communications between a base station and a user equipment, its device category regarding typical energy consumption, and its data rate specifications. The power control mechanism and the device category regarding typical energy consumption can determine the specification on energy efficiency.

Embodiments of the invention allow the uplink and/or downlink transmissions to be adapted according to energy efficiency specifications of each individual communication device <NUM> and thus allow an extension of battery life time of the communication devices <NUM>.

<FIG> shows a diagram of a predetermined sub-carrier frequency grid associated with a frame structure <NUM> according to an embodiment. The diagram illustrates different sub-carrier frequency spacings of different communication devices <NUM>, e.g. low battery communication devices <NUM>, medium battery communication devices <NUM>, low power and low data rate communication devices <NUM>, and communication devices <NUM> having plugged in electricity. The diagram can relate to a predetermined sub-carrier frequency grid for an uplink frame structure <NUM> having different sub-carrier frequency spacings in different resource blocks.

Embodiments of the invention utilize an adaptable frame structure <NUM> and an adaptive scheduling scheme to realize a flexible and dynamic adjustment of the transmission bandwidth and the sub-carrier frequency spacing and thus of the peak-to-average power ratio of transmitted multi-carrier communication signals.

The frame structure <NUM> can be realized as follows. Firstly, a sub-carrier frequency grid for uplink and/or downlink transmission is predefined. This sub-carrier frequency grid can determine a minimum sub-carrier frequency spacing allowed in the uplink and/or downlink transmission. This predetermined sub-carrier frequency grid is illustrated in <FIG>.

Based on the sub-carrier frequency grid, the uplink and/or downlink resource can be divided into a number of resource blocks, which can use different sub-carrier frequency spacings. The sub-carrier frequency spacing within each resource block can be an integer multiple of the minimum sub-carrier frequency spacing determined by the sub-carrier frequency grid.

The number of resource blocks with the same sub-carrier frequency spacing can be adapted according to the numbers of communication devices <NUM> having different energy efficiency specifications, e.g. related to downlink and/or uplink power control, device category regarding energy consumption, or a channel quality indicator (CQI), and their data rate specifications.

<FIG> shows a diagram of a frame structure <NUM> for communications of a plurality of communication devices within a communication network according to an embodiment. The frame structure <NUM> is illustrated in terms of time versus frequency. The frame structure <NUM> comprises a plurality of resource blocks (RBs). The plurality of resource blocks can have different sub-carrier frequency spacings, e.g. sub-carrier frequency spacing #<NUM>, sub-carrier frequency spacing #<NUM>, and sub-carrier frequency spacing #<NUM>. The diagram illustrates a time and frequency resource map in two dimensions (2D) for uplink and/or downlink transmissions.

A resource block (RB) is defined as time-frequency resource that is allocated to a communication device. A resource block can indicate a number of minimum sub-carrier frequency spacings in frequency domain, e.g. being determined by a predetermined sub-carrier frequency grid, and duration in time. Actual transmitted multi-carrier communication signals within resource blocks can have different sub-carrier frequency spacings that can be integer multiples of the minimum sub-carrier frequency spacing.

Different definitions for a resource block may exist. A resource block may e.g. be regarded as a time-frequency unit, wherein the term unit may indicate that its size remains the same everywhere within the frame structure. In this context, a resource block refers to a time-frequency resource that is allocated to a communication device. The resource of an entire frame structure can be allocated based on a certain granularity, e.g. a smallest unit that comprises a certain number of minimum sub-carrier frequency spacings and certain duration in time.

If the resource blocks or the sub-frames are self-explanatory, e.g. if reference signals are inserted, a communication device <NUM> can detect the signal, even if it is not synchronized. This can enable an asynchronous transmission within a communication system <NUM>.

Furthermore, one modulated communication symbol, e.g. a BPSK symbol, a QPSK symbol, or a <NUM>-QAM symbol, can occupy one resource element having a unit sub-carrier frequency spacing and symbol duration.

In a filter-bank multi-carrier (FBMC) communication system, which can be critically sampled, the symbol sampling rate can equal the sub-carrier frequency spacing. This means that the larger the sub-carrier frequency spacing is chosen, the smaller the symbol duration is. Thus, the number of transmitted communication symbols within each resource block can actually be the same, independently of the sub-carrier frequency spacing. A particular case is that the sub-carrier frequency spacing equals the allocated transmission bandwidth, which can convert to a single carrier transmission for this resource block.

<FIG> shows a diagram of a frame structure <NUM> for communications of a plurality of communication devices within a communication network according to an embodiment. The frame structure <NUM> comprises a plurality of resource blocks, e.g. resource block #<NUM>, and resource block #<NUM>. A plurality of pilot symbols is arranged within the frame structure <NUM>. The diagram illustrates uplink pilot patterns for different resource blocks having different sub-carrier frequency spacings.

In order to achieve equal qualities of channel estimation, and/or phase tracing in different resource blocks, a pilot symbol overhead of different resource blocks may be proportional to the transmission bandwidth. This can be achieved by adapting the pilot symbol, e.g. reference symbol, allocation to keep the pilot symbol overhead constant for each resource block, independently of the sub-carrier frequency spacing. As described, the number of transmitted communication symbols within each resource block can actually be the same, independently of the sub-carrier frequency spacing. Therefore, for a constant pilot symbol overhead, the number of pilot symbols within each resource block may also be the same. Within each resource block, the pilot symbols can be distributed evenly in frequency and/or time, as illustrated in the diagram.

In the case of uplink transmission, the frame structure <NUM> having different resource blocks can be indicated via specific signaling in the downlink. Such signaling can indicate a start and an ending of each resource block, e.g. both in time and frequency, wherein the transmission bandwidth of each resource block can implicitly be indicated by the start and ending in frequency, and the corresponding sub-carrier frequency spacing. In an embodiment, the start of the resource block in frequency relates to the lower transmission frequency, and the ending of the resource block in frequency relates to the upper transmission frequency.

In the following, a scheme for allocation of resource blocks to communication devices <NUM> is described.

An adaptation scheme is used for the allocation of a resource block to each communication device <NUM>, so that the used sub-carrier frequency spacing and thus the peak-to-average power ratio matches the energy efficiency specification of a communication device <NUM>. This adaptation is based on a specific signaling using an energy efficiency indicator, e.g. an Energy Efficiency Requirement Indicator (EERI), or can be deduced from a category of the communication device <NUM> e.g. by the network entity <NUM> or the communication device <NUM>.

For energy efficiency based adaptation, a user-specific signaling field for the adaptation of energy efficiency can be defined as Energy Efficiency Requirement Indicator (EERI). This signaling field can be used to indicate the desired energy efficiency for each communication device <NUM>. As an example, incrementing an energy efficiency indicator value can mean reducing a demand for energy efficiency. The following table provides two examples of values and meanings of an energy efficiency indicator.

For some communication devices <NUM>, e.g. sensors, the energy efficiency indicator is fixed and predefined and can therefore be known by the network entity <NUM>, e.g. base station. For some other communication devices <NUM>, the energy efficiency indicator varies depending on different factors, according to the claimed invention varies depending on a battery status.

As will be described in the following, the energy efficiency indicator is taken into account in the resource block allocation and/or assignment of the sub-carrier frequency spacing. In addition to the energy efficiency indicator, an open loop power control based on a receiving power indicator, e.g. a reference signal receiving power (RSRP) indicator, can also be taken into account, which can be relevant for a transmission power of a communication device <NUM>.

For example, a bad receiving power indicator can mean that a wireless communication channel between the network entity <NUM>, e.g. a base station or a relay station, and the communication device <NUM>, or between two communication devices <NUM> in direct device-to-device (D2D) communication can have a high path loss and the communication device <NUM> may have to use a high transmission power for the corresponding transmission.

One typical example is that an energy sensitive communication device <NUM>, e.g. indicated by the energy efficiency indicator, with a bad receiving power indicator caused by a high path loss desires a low peak-to-average power ratio in order to enhance an effective transmission power. For such a communication device <NUM>, the network entity <NUM> can allocate the resource block with the largest possible sub-carrier frequency spacing that supports the desired data rate of this communication device <NUM>.

Based on the energy efficiency indicator, e.g. the Energy Efficiency Requirement Indicator (EERI), and the receiving power indicator, e.g. the reference signal receiving power (RSRP) indicator, dynamic schemes can be utilized for the allocation of the resource blocks and/or sub-carrier frequency spacings. The schemes can differ in the cases of cellular uplink/downlink transmission, direct device-to-device (D2D) communications, and transmissions of relay stations in a downlink spectrum.

<FIG> shows a diagram of a communication system <NUM> comprising a network entity <NUM> and a communication device <NUM> according to an embodiment. The diagram illustrates a possible implementation of an open loop power and energy efficiency based control as well as a resource block allocation. The network entity <NUM> can be a base station (BS).

An allocation scheme for cellular uplink and/or downlink communications can be of particular interest. Allocation schemes for direct device-to-device (D2D) communications and transmissions of relay stations in a downlink spectrum are natural extensions. For cellular uplink and/or downlink communications, the following procedure can be used for the adaptation of the peak-to-average power ratio.

In a first step, each communication device <NUM> can estimate a downlink path loss and a receiving power indicator e.g. based on downlink pilot symbols.

In a second step, for uplink communications, each communication device <NUM> sends an energy efficiency indicator, and/or a receiving power indicator back to the network entity <NUM> in an uplink control channel. For downlink communications, only a receiving power indicator may be sent.

In a third step, the network entity <NUM> derives the energy efficiency specification of each communication device <NUM> from the energy efficiency indicator and optionally the receiving power indicator. Based on the specifications of each communication device <NUM> with regard to energy efficiency and data rate, the network entity <NUM> determines a sub-carrier frequency spacing for each communication device <NUM> and optionally a number of sub-carriers.

According to the number of sub-carriers and/or the sub-carrier frequency spacing of all communication devices <NUM>, the network entity <NUM> can adapt a structure of resource blocks of an uplink frame structure for uplink communications. Afterwards, the network entity <NUM> allocates a resource block, thereby determining the sub-carrier frequency spacing, and sub-carriers to each communication device <NUM>.

For downlink communications, the network entity <NUM> can adapt the structure of transmission time slots of a downlink frame structure. Each transmission time slot may comprise only one sub-carrier frequency spacing. Different transmission time slots of different lengths can have different sub-carrier frequency spacings. An example is that for all edge communication devices <NUM> having high energy efficiency specifications, the network entity <NUM> allocates a transmission time slot having a large sub-carrier frequency spacing, i.e. a low number of sub-carriers and thus a low peak-to-average power ratio. Afterwards, the network entity <NUM> can allocate a transmission time slot, thereby e.g. determining the sub-carrier frequency spacing, to each communication device <NUM>.

In a fourth step, the communication device <NUM> can perform an open loop power control based on the allocated resource block and/or sub-carrier frequency spacing by adjusting a back-off of a transmission power for uplink communications, and an automatic gain control based on the allocated transmission time slot and/or sub-carrier frequency spacing by adjusting a reception gain for downlink communications.

In a fifth step, a periodical repetition of the first step to the fourth step can be performed. In the diagram, an exemplary implementation of the described scheme based on open loop power control and energy efficiency indicator based control is illustrated.

<FIG> shows a diagram of a scheduling approach based on an energy efficiency indicator, a receiving power indicator, and a data rate indicator according to an embodiment. The energy efficiency indicator, the receiving power indicator, and the data rate indicator can be relevant factors influencing the scheduling and/or allocation performed by the network entity <NUM> in the third step.

Firstly, the network entity <NUM> can determine the number of sub-carriers according to the receiving power indicator and/or the energy efficiency indicator, which can be an important factor determining the peak-to-average power ratio of the multi-carrier communication signal.

Afterwards, the network entity <NUM> determines the sub-carrier frequency spacing, e.g. the resource block and/or transmission time slot for the communication device <NUM> according to the data rate specification of the concerned communication device <NUM> and/or a targeted signal-to-interference-plus-noise ratio (SINR) of the concerned communication device <NUM>. The reason can be that the sub-carrier frequency spacing multiplied by the number of sub-carriers can equal the transmission bandwidth used by the concerned communication device <NUM>.

Based on the overall number of sub-carriers and/or the sub-carrier frequency spacing of a communication system <NUM>, the network entity <NUM> can adapt the resource block structure of an uplink frame structure, e.g. a number of different resource blocks having different sub-carrier frequency spacings, the values of the sub-carrier frequency spacings, and the transmission bandwidth of each resource block for uplink communications.

Based on the overall number of sub-carriers and/or the sub-carrier frequency spacing of the communication system <NUM>, the network entity <NUM> can adapt the structure of the transmission time slots, e.g. the number of different transmission time slots having different sub-carrier frequency spacings, the values of the sub-carrier frequency spacings, and the duration of each transmission time slot for downlink communications.

The uplink and/or downlink partitioning can be conducted by the network entity <NUM> and can be broadcasted to all connected communication devices <NUM>. Finally, in the third step, the network entity <NUM> can indicate the frequency sub-band and/or transmission time slot allocation and granting via specific signaling. Such signaling may e.g. utilize a sub-band / time slot indicator and/or a sub-carrier frequency spacing indicator in a downlink broadcast / control channel.

For direct device-to-device (D2D) communications, the above scheme can be reused with just the following modification in the first step. In the first step, a communication device participating in the direct device-to-device communications estimates the path loss and the receiving power indicator of the communication link and communicates it to its partnering device-to-device communication device. Such estimation can be performed e.g. based on a transmission of training signals between such communication devices.

For transmissions of a relay station in a downlink spectrum, the above scheme can be simplified as follows in order to adjust the peak-to-average power ratio of the transmitted multi-carrier communication signal of the relay station. In the first step, each communication device <NUM> estimates a downlink path loss and a receiving power indicator based on downlink common reference or pilot signals. In the second step, the energy efficiency indicator of the relay station can be predetermined and/or known by itself. Therefore, based on the path loss to the served communication device and its energy efficiency indicator, it can determine the sub-carrier frequency spacing and the used number of sub-carriers in the frequency resource allocated to it so that the peak-to-average power ratio can match its energy efficiency specification.

The frame structure <NUM>, e.g. for uplink communications, can be standardized including the transmission bandwidths of the resource blocks, the resource map, and the resource blocks having different sub-carrier frequency spacings. Furthermore, the signaling fields for indicating the structure of the resource blocks as well as the resource block allocation and/or granting via a downlink broadcast / control channel can be standardized.

Embodiments of the invention relate to a filter-bank multi-carrier (FBMC) signal transmission frame structure <NUM> based on a common frequency sub-carrier grid and/or a resource block (RB) grid, wherein the transmission resource is divided into variable resource blocks and/or transmission time slots with different sub-carrier frequency spacings, wherein the transmission bandwidth of each resource block and/or a duration of each transmission time slot are adapted according to a numbers of communication devices <NUM> with different energy efficiency specifications and data rate specifications, and/or wherein an equal pilot symbol overhead in each resource block with different sub-carrier frequency spacings is utilized.

Claim 1:
A network entity (<NUM>) for managing communications of a plurality of communication devices over a communication network (<NUM>), the network entity (<NUM>) comprising:
a communication interface (<NUM>) being configured to receive an energy efficiency indicator over the communication network (<NUM>) from a communication device (<NUM>) of the plurality of communication devices, which is configured to transmit a multi-carrier communication signal comprising a plurality of sub-carriers in a resource block allocated to the communication device (<NUM>), wherein the energy efficiency indicator indicates an energy efficiency specification of the communication device (<NUM>), wherein the energy efficiency specification is derived upon the basis of a battery status of the communication device or the energy efficiency specification of the communication device is predetermined; and
a processor (<NUM>) being configured to determine a sub-carrier frequency spacing of the plurality of sub-carriers upon the basis of the energy efficiency indicator, wherein the sub-carrier frequency spacing of the plurality of sub-carriers and thus a peak-to-average power ratio of the corresponding multi-carrier communication signal matches the energy efficiency specification of the communication device (<NUM>) , and to generate a resource block indicator associated with the communication device (<NUM>), wherein the resource block indicator indicates the sub-carrier frequency spacing;
wherein the communication interface (<NUM>) is further configured to transmit the resource block indicator over the communication network (<NUM>) to the communication device (<NUM>).