DE69837471T2 - Method and device for improving the capacity in a radio communication system - Google Patents

Description

Territory of invention

The The present invention relates to radio communication systems, in particular to systems using an FDD scheme (FDD = frequency divided duplex) for frequency allocation, for example a global system for mobile Communication (GSM) or a universal mobile telecommunication system (UMTS).

background the invention

In A FDD scheme uses a first frequency band for uplink communications and a second frequency band for Downlink communications, for example between a mobile terminal and a fixed terminal, such as a base station assigned.

One CDMA system operating in the FDD scheme, such as wideband CDMA, as for UMTS has a limited capacity. The capacity is limited by disturbances. Therefore, the noise level increases to the system if the system load (the number of subscribers, which use the system) increases, reducing the capacity of the system is limited.

It is therefore desirable the capacity of one Telecommunications system, such as a broadband CDMA system, the working under the FDD scheme, increasing to an increase in demand to accommodate a load on the telecommunications system.

Of the Conference article by J.W. Liang and A.J. Paulraj entitled "Forward link antenna diversity using feedback for indoor communication systems "describes a procedure for duplex communications over one wireless connection between terminals with a fixed feedback low rate for a forward link antenna diversity.

The Patent Cooperation Treaty Patent Application WO 95/075878 a system that determines the transmission data rate in a multi-user communication system. The data rate will be according to a comparison between a measured resource usage and a threshold modified.

Summary the invention

According to one The first aspect of the present invention is a method for Improvement of capacity provided in a duplexing scheme according to claim 1.

According to one second aspect of the present invention is a device for one Duplex communication via a wireless connection according to claim 12 available posed.

Further Preferred features and advantages will become apparent in the accompanying description and the accompanying dependent claims and become clear from them.

By Use one of the frequencies available on the uplink band Reserve capacity around feedback data transferred to, Is it possible, Downlink communications to optimize for interference on the downlink band of frequencies decrease, causing the Downlink capacity elevated becomes.

A such technique is particularly in situations of, for example asymmetrical system load useful, where the load on the downlink is greater than on the uplink. Such a burden can occur in locations where it is There are slowly moving participants, such as microcells and in picocells.

Now At least one example of the present invention will be exemplified with reference to the accompanying drawings.

Short description the drawings

1 is a schematic representation of a communication system;

2 Fig. 12 is a schematic diagram of a base station constituting an embodiment of the invention;

3 Fig. 12 is a schematic diagram of a terminal constituting an embodiment of the invention;

4 FIG. 10 is a flowchart illustrating an operation of the device of FIG 2 represents;

5 is a flowchart illustrating an interaction of the terminal with the device of 2 represents;

6 Fig. 10 is a flowchart illustrating an operation of the base station which is another embodiment of the invention;

7 is a flowchart of a functional block of 6 ; and

8th is a flow chart of another functional block of 6 ,

Description of a preferred embodiment

A broadband CDMA system 100 ( 1 ) comprises a base station 102 and a plurality of other base stations 104 that have a supply area 106 provide. The base station 102 can via a radio frequency interface 110 with a mobile device 108 communicate. In the supply area 106 can more mobile devices 112 to be available.

The base station 102 ( 2 ) comprises a transmission diversity processor 206 and an antenna weighting and selection unit 208 , The functionality of the transmission diversity processor 206 and an antenna weighting and selection unit 208 both are in a microprocessor (not shown) of the base station 102 contain.

The transmission diversity processor 206 has a first entrance 210 to receive a signal indicating the quality of signals received at the base station 200 be received, a second input 212 to receive an acknowledgment of an optimization scheme to be used (described in more detail below) and a third input 214 to receive feedback data. The transmission diversity processor 206 also has a first output 216 for transmitting weighting and delay data (w, d) to the antenna weighting and selection unit 208 and a second exit 218 for transmitting downlink control channel information to the mobile terminal 108 and the other mobile devices 112 ,

The transmission diversity processor 206 includes one at the first entrance 210 coupled uplink quality unit 220 and a scheme selection unit 222 , wherein the scheme selection unit 222 to the second entrance 212 and the second exit 218 is coupled. The scheme selection unit 222 is to a derivative unit 224 coupled. The derivation unit 224 is at the third entrance 214 and the first exit 216 coupled. The derivation unit 224 directs the weights and delays (w, d) from those at the third input 214 received feedback data.

The feedback data includes data relating to the functions of the signals transmitted on the downlink in particular and / or data that the mobile terminal 108 used to the base station 102 in terms of weights and delays in the antenna weighting and selection unit 208 are to be applied.

The antenna weighting and selection unit 208 has a fourth entrance 226 to a first spreading and modulation unit 232 coupled, wherein the first spreading and modulation unit 232 is able to spread and modulate data to be transmitted to a first user. The antenna weighting and selection unit 208 has a fifth entrance 228 and an Nth input 230 , both to a second and N-th spreading and modulation unit 234 . 236 are coupled. Likewise, the second and third spreading and modulating units spread and modulate 234 . 236 Data from a second user or an Nth user.

The antenna weighting and selection unit 208 also has a third output 238 , a fourth exit 240 and a fifth exit 242 , The third exit 238 , fourth exit 240 and fifth exit 242 are each to a first RF unit 244 (RF = radio frequency); a second RF unit 246 , or a third RF unit 248 coupled. The first, second and third RF units 244 . 246 . 248 convert input signals into radio frequency signals according to any method known to those skilled in the art. The first, second and third RF units 244 . 246 . 248 are each to a first antenna 250 , a second antenna 252 , or a third antenna 254 coupled. The first, second and third antenna 250 . 252 . 254 form an antenna group.

The antenna weighting and selection unit 208 includes a first weighting and delay network 256 , a second weighting and delay network 258 and a third weighting and delay network 260 ,

The first weighting and delay network 256 comprises a first mixing unit 262 , a second mixing unit 264 and a third mixing unit 266 all at the fourth entrance 226 are coupled. The first, second and third mixing unit 262 . 264 . 266 are each to a first delay unit 268 , a second delay unit 270 , or to a third delay unit 272 coupled. The first, second and third mixing unit 262 . 264 . 266 each have a first weight input w _{1, 1} , a second weight input w _1,2 , and a third weight input w _1,3 for supplying weight data for the first, second and third antenna 250 . 252 . 254 concerning the data of the first user.

The second weighting and delay network 258 comprises a first mixing unit 274 , a second mixing unit 276 and a third mixing unit 278 all at the fifth entrance 228 are coupled. The first, second and third mixing unit 274 . 276 . 278 are ever because of a first delay unit 280 , a second delay unit 282 , or to a third delay unit 284 coupled. The first, second and third mixing unit 274 . 276 . 278 each have a first weight input w _{2, 1} , a second weight input w _2,2 , and a third weight input w _2,3 for supplying weight data for the first, second and third antenna 250 . 252 . 254 concerning the data of the second user.

The third weighting and delay network 260 comprises a first mixing unit 286 , a second mixing unit 288 and a third mixing unit 290 all to the sixth entrance 230 are coupled. The first, second and third mixing unit 286 . 288 . 290 are each to a first delay unit 292 , a second delay unit 294 , or to a third delay unit 296 coupled. The first, second and third mixing unit 286 . 288 . 290 each have a first weight input w _{N, 1} , a second weight input w _{N, 2} , and a third weight input w _{N, 3} for supplying weight data for the first, second and third antenna 250 . 252 . 254 concerning the data of the Nth user.

The first delay units 268 . 280 . 292 are to a first summation unit 297 coupled to sum all the weighted and delayed signals for the first antenna 250 are provided, wherein the first summation unit 297 to the third exit 238 is coupled.

The second delay units 270 . 282 . 294 are to a second summation unit 298 coupled to summate all the weighted and delayed signals for the second antenna 252 are provided, wherein the second summation unit 298 to the fourth exit 240 is coupled.

The third delay units 272 . 284 . 296 are to an Nth summation unit 299 coupled to sum all the weighted and delayed signals for the third antenna 254 are provided, wherein the N-th summation unit 299 to the fifth exit 242 is coupled.

The mobile device 108 ( 3 ) includes one to an RF unit 302 coupled antenna 300 , The RF unit 302 performs all the tasks known to those skilled in the art, for example, modulation and frequency conversion. The RF unit 302 is to a microprocessor 304 coupled, the microprocessor 304 to a memory 306 is gekop pelt. The functionality of the invention may be in the microprocessor 304 be embedded.

Of the Operation of the above apparatus will now be described.

The base station 102 communicates with the mobile device 108 over a frequency range. The frequency range is divided into a first band (uplink) of frequencies f _UL and a second band (downlink) of frequencies f _DL , according to an FDD scheme known to those skilled in the art. Thus, the uplink band of frequencies f _UL for uplink transmissions from the mobile terminal 108 to the base station 102 used while the downlink band of frequencies f _DL for downlink transmissions from the base station 102 to the mobile device 108 is used.

A first, second, third, fourth and fifth optimization scheme S ₁ , S ₂ , S ₃ , S ₄ , S ₅ are stored in a memory (not shown) in the base station 100 saved. The first, second, third, fourth and fifth optimization schemes S ₁ , S ₂ , S ₃ , S ₄ , S ₅ each have a first, second, third, fourth, and fifth linked capacitance value. The first, second, third, fourth and fifth capacitance values relate to the amount of capacitance claimed by the first, second, third, fourth and fifth optimization schemes S ₁ , S ₂ , S ₃ , S ₄ , S ₅ Feedback data to the base station 102 to transmit on the uplink band of frequencies f _UL . The amount of capacitance claimed by each of the first, second, third, fourth, and fifth optimization schemes S ₁ , S ₂ , S ₃ , S ₄ , S ₅ varies on an incremental basis, with the first optimization scheme S _{1 being} the lowest Capacity is claimed while the fifth optimization scheme S ₅ occupies most of the capacity on the uplink band of frequencies, that is, capacity (S ₁ ) <capacity (S ₂ ) <. , , <Capacity (S ₅ ). This is not an essential requirement.

Examples of the optimization scheme are the following:

The first optimization scheme, S ₁ , may be delay based. In such an optimization scheme, the first, second and third antennas transmit 250 . 252 . 254 all at the same power. However, the CDMA code is provided with a time offset.

In the second optimization scheme, S ₂ , becomes the first, second and third antenna 250 . 252 . 254 selected a single antenna that corresponds to the best overall performance in the mobile terminal 108 Will be received.

In the third optimization scheme, S ₃ , two of the best functioning antennas of the first, second and third antennas 250 . 252 . 254 selected, that is, the two antennas used for the best overall performance are responsible for the mobile terminal 108 Will be received. The phase of the two best functioning antennas is adjusted to reduce the error rate on the downlink band of frequencies f _DL .

The fourth optimization scheme, S ₄ , is similar to the third optimization scheme S ₃ . However, both the gain and the phase of the two best functioning antennas are adjusted to reduce the error rate on the downlink band of frequencies f _DL .

The fifth Optimization scheme involves adjusting the gain and Phase of all antennas in the antenna array to maximize the output.

Although the above optimization schemes with respect to the first, second and third antenna 250 . 252 . 254 The optimization schemes are not limited to any group of three antennas and the antenna array may comprise a larger number of antennas. Likewise, more than two best functioning antennas can be selected for the optimization schemes described above. For example, the best functioning antennas can be identified using unique training bits to identify each antenna.

A lower threshold T ₁ is predetermined and is an error rate related to a maximum amount of capacitance available on the uplink band of frequencies f _UL at a given time. An upper threshold T ₂ is predetermined and is an error rate relating to a minimum amount of capacitance available on the uplink band of frequencies f _UL at a given time.

It will open 4 Reference is made therein to the selection unit 222 a variable U to the value "1" when the base station 102 initializing, indicating that the first optimization scheme is to be used initially. The value of the variable U is sent to the mobile terminal 108 transfer (step 400 ), so that the mobile terminal 108 knows which optimization scheme to implement. If the other mobile devices 112 with the base station 102 they also receive the variable U.

The uplink quality unit 220 estimates (step 402 ) estimates the error rate p of communications on the uplink band of frequencies f _UL by any technique known to those skilled in the art, for example bit error rate, word error rate or frame error rate techniques. The error rate p is a quality _measure related to the capacity available on the uplink band of frequencies f _UL .

The uplink quality unit 220 determined (step 404 ), whether the error rate p is below the threshold T ₁ . If the error rate p is below the threshold T ₁ , it increments (step 406 ) the uplink quality unit 220 the variable U by 1, provided that the value of the variable U does not exceed the maximum number of optimization schemes, in this case five. The base station 102 then transmits (step 408 ) the updated value of the variable U to the mobile terminal 108 and to the other mobile devices 112 ,

If the error rate p is not below the threshold T ₁ , determined (step 410 ) the uplink quality unit 220 whether the error rate p is above the lower threshold T ₂ . If the error rate p is above the threshold T ₂ , it decrements (step 412 ) the uplink quality unit 220 the value of the variable U by 1, provided that it does not fall below the minimum number of optimization schemes. The base station 108 then transmits (step 408 ) the updated value of the variable U. If the error rate p is not above the threshold T ₂ , the base station transmits 108 (Step 408 ) the current, unchanged value of the variable U.

The base station 102 then implements (step 414 ) the optimization scheme selected in the following manner. The base station 102 awaits receipt of a confirmation from the mobile terminal 108 in that the value of the variable U has been received when the value of the variable U has changed. The selection unit 222 then selects the first, second, third, fourth or fifth optimization scheme according to the value of the variable U. The derivation unit 224 based on the selection unit 222 selected optimization scheme S ₁ , S ₂ , S ₃ , S ₄ , S ₅ through the first, second and N th weight and delay network 256 . 258 . 260 weight and deceleration values to be used. The derived weight and delay values are translated to the first, second and Nth weight and delay networks 256 . 258 . 260 transferred.

The uplink quality unit 220 then repeats the above procedure, so that the capacity of the uplink band of frequencies f _{UL is} frequently monitored.

It will open 5 Reference is made in receiving (step 502 ) the mobile terminal 108 the value of the variable U passing through the base station 102 has been transferred (step 508 ). From the other base stations 104 in an active sentence au and corresponding values of variables equivalent to the variable U are received.

Upon receiving the value of the variable U, the speed of the mobile terminal becomes 102 determined according to any technique known to those skilled in the art. The mobile device 108 then determines (step 504 ), whether the mobile terminal 108 at a high speed, for example 50 km / h, travels. When the mobile terminal is traveling at a high speed, it selects (step 506 ) the mobile terminal 108 the first optimization scheme S ₁ , that is, the optimization _scheme claiming the least capacity on the uplink band of frequencies f _UL , by setting a variable U _k to the same value as the variable U, where k is the mobile terminal 108 identified.

The mobile device 108 then informs (step 512 ) the base station 102 (the other base stations 112 in the active sentence comprising) about the value of the variable U _k , if the value of the variable U _k generated by the mobile terminal 108 was set, deviates from the value of the variable U, that of the base station 102 Will be received. The mobile device 108 then implements (step 516 ) the optimization scheme according to the value of the variable U.

Although on the value of the base station 102 received variable U, the actions described above also apply to the other base stations 112 in the active sentence.

In CDMA systems, a "soft handover" mode is possible. Therefore determines (step 508 ) the mobile terminal 108 when the mobile terminal 108 determined (step 504 ) that the mobile terminal 108 does not travel at a high speed, whether the "soft handover" mode is enabled. When the "soft handover" mode is enabled, the mobile terminal checks 108 the value of the variable U and the corresponding values of the other base stations 112 variable U received in an active set, and sets the value of the variable U _k to the lowest of the received values. The mobile device 108 then informs (step 512 ) the base station 100 (the other base stations 112 in the active set) about the value of the variable U, if by the mobile terminal 108 set value of the variable U from the value of the base station 102 received variable U deviates. The mobile device 108 then implements (step 516 ) the optimization scheme according to the value of the variable U _k .

When the mobile terminal 108 determined (step 508 ), that the "soft handover" mode is not enabled, and if the value of the variable U _{k is} the value of that of the base station 102 variable U deviates, represents the mobile terminal 108 the value of the variable U _k to the value of the base station 102 received variable U (step 514 ) and transmits an acknowledgment to the base station 102 , The mobile device 108 then implements (step 516 ) the optimization scheme according to the value of the variable U _k .

After the optimization scheme has been implemented according to the value of the variable U (step 516 ), expected (step 502 ) the mobile terminal 108 receiving an updated value of variable U.

In a second embodiment of the invention, a new mobile terminal 114 in the supply area 106 enter and need with the base station 102 ( 6 ) to communicate. The base station 102 generates and updates periodically (step 600 ) Statistics on the allocated average bit rate on the downlink band of frequencies f _DL for each mobile terminal that is in communication with the base station 102 located as a function of the bit rate (requested by the mobile terminal 108 or the network where the system is 100 and most frequently of the first, second, third, fourth, and fifth optimization schemes S ₁ , S ₂ , S ₃ , S ₄ , S ₅ , that of the mobile terminal 108 and the other mobile devices 112 that is in communication with the base station 102 assigned for a given requested bitrate.

The uplink error rate p is determined by the uplink quality unit 220 measured (step 602 ). The base station 102 then determines (step 604 ), if there is any new mobile device 114 there, that with the base station 102 must communicate. When the new mobile device 114 must register, the base station leads 102 the method for configuring a new user described below (step 700 ). If the new mobile device 114 does not need to be configured, performs the base station 102 a setting procedure described below (step 800 ).

It will open 7 Referring to this, the execution (step 700 ) of the procedure for configuring a new user results in the following steps. The uplink quality unit 220 determined (step 702 ), whether the error rate p is greater than the upper threshold T ₂ . If the error rate is not greater than the upper threshold T ₂ , the selector will turn off 222 the value of the variable U _k (step 704 ), which by the new mobile terminal 114 Optimization scheme to be used and the assigned bitrate for the new mobile terminal 114 are displayed.

In the case where the "soft handover" mode is enabled, the selection unit points 222 the value of the variable U _k that the new mobile terminal 114 corresponds to "1"to; This indicates that the new mobile device 114 will use the first optimization scheme S ₁ claiming the least capacity on the uplink band of frequencies f _UL . When the new mobile device 114 moving at a low speed and the "soft handover" mode is not enabled, a bit rate on the downlink band of frequencies f _DL becomes the new mobile terminal 114 assigned according to the statistics that are generated to ensure that the new mobile terminal 114 assigned bitrate is comparable to mobile devices that have similar bitrate needs, and the new mobile device 114 is assigned the same optimization scheme by the mobile terminal 108 and the other mobile devices 112 is used. If the new mobile device 114 traveling at high speed and the "soft handover" mode is not released, the new mobile terminal will 114 a bit rate assigned in the same manner as for the low-speed mobile terminals described above and the variable U _{k of} the new mobile terminal 114 the value "1" is assigned according to the first optimization scheme S ₁ , which claims the least capacity on the uplink band of frequencies f _UL .

If the value of the error rate p is greater than the upper threshold T ₂ , the base station instructs 102 the value of the variable U _k , corresponding to the new mobile terminal, "1" (step 706 ), which indicates that the new mobile device 114 will use the first optimization scheme S ₁ claiming the least capacity on the uplink band of frequencies f _UL and the new mobile terminal 114 is assigned a bit rate in the same manner as for the above-described low-speed mobile terminals.

It will open 8th With reference to this, the embodiment (step 800 ) of the recruitment procedure as follows.

The base station 102 determined (step 802 ), whether the error rate p is less than the upper threshold T ₁ . If the error rate p is lower than the upper threshold T ₁ , it identifies (step 804 ) the base station 102 a user set. A user set includes all at the base station 102 registered mobile terminals traveling at low speed, having no released "soft handover" mode and requesting higher capacity on the downlink band of frequencies f _DL . The base station then dials (step 806 ) M ₁ mobile terminals from the user set, which use the first, second, third or fourth optimization scheme S ₁ , S ₂ , S ₃ , S ₄ . The base station 102 then assigns the next highest optimization scheme, that is, the optimization _{scheme that} claims the next highest amount of capacity on the uplink band of frequencies f _UL , for example the fifth optimization scheme S ₅ , to the M ₁ selected mobile terminals.

For everyone at the base station 102 registered mobile devices (step 808 ) the base station 102 the changes in the values of the variable U _{k of} the corresponding mobile terminals. In addition, the base station provides 102 the capacity of the control channels of the uplink band of frequencies f _UL , releases the optimization schemes assigned to the selected mobile terminals and adjusts the data rates on the downlink band of frequencies f _DL .

If the error rate p is not less than the upper threshold T ₁ , determines (step 810 ) the base station 102 whether the error rate p is greater than the lower threshold T ₂ . If the error rate p is greater than the lower threshold T ₂ , the base station selects 102 M ₂ mobile devices off (step 812 ) using a different optimization scheme than the first optimization scheme S ₁ . The base station 102 reduces this value of the variable U _k for the M ₂ mobile terminals by one, so that the next lowest optimization scheme is assigned to the selected mobile terminals. This process occurs when there is insufficient capacity on the uplink band of frequencies f _UL .

For everyone at the base station 102 registered mobile devices communicates with the base station 102 (Step 808 ) the changes of the changed values of the variable U _k . In addition, the base station provides 102 the capacity of the control channels of the uplink band of frequencies f _UL , releases the optimization schemes assigned to the selected mobile terminals and adjusts the data rates on the downlink band of frequencies f _DL . This step (step 808 ) is also executed in the case where the error rate p is not larger than the lower threshold T ₂ .

From the examples described above, it can be seen that using a capacity on the uplink band of frequencies f _UL can be used to send feedback data to improve communications on the downlink band of frequencies f _DL and thus the capacity of these communications to increase.

Although the above examples are in the context have been described using a capacitance available on the uplink band of frequencies f _UL to account for an increase in the load on the downlink band of frequencies f _DL , an opposite arrangement is possible, that is, one Using a capacity available on the downlink band of frequencies f _DL to account for an increase in load on the uplink band of frequencies f _UL .

Claims (12)

Method for duplex communication via a wireless connection between a first and second terminal ( 102 . 108 ), comprising: transmitting from the first terminal ( 108 ) to the second terminal ( 102 ) over a first band of frequencies and transmitting from the second terminal ( 102 ) to the first terminal ( 108 ) over a second band of frequencies, determining an amount of available capacity on the first band of frequencies, transmitting feedback data from the first terminal ( 108 ) to the second terminal ( 102 ) on the first band of frequencies using a variable perimeter of the capacitance of the first band of frequencies, the variable perimeter being a function of the amount of capacitance that has been determined to be available on the first band of frequencies the feedback data relates to the quality of communications made by the first terminal ( 108 ) from the second terminal ( 102 ), and using the feedback data, if any, to transmit from the second terminal ( 102 ) to the first terminal ( 108 ) on the second band of frequencies, the quality of communications from the second terminal ( 102 ) to the first terminal ( 108 ) is improved with respect to a larger amount of the capacity of the first band of frequencies used by the transmission of the feedback data. The method of claim 1, further comprising: selecting an initial optimization scheme to improve the quality of communications from the second terminal ( 102 ) to the first terminal ( 108 ), the initial optimization scheme being associated with an initial set of feedback data using a corresponding amount of capacity of the first band of frequencies, the selection of the initial optimization scheme being a function of the amount of capacity available in the first band of frequencies , Method according to claim 2, the initial Optimization scheme from a set of at least two optimization schemes is selected the above respective amounts of feedback data feature. Method according to claim 3, the initial Amount of with the initial Linked optimization scheme Feedback data the smallest amount of feedback data which correspond to the optimization schemes of the sentence, thus the smallest extent of a capacity of the first band of frequencies is used. Method according to claim 4, wherein subsequently a second optimization scheme is selected, around the beginning Optimization scheme to replace, where in the first volume of Frequencies consumed by the second optimization scheme greater than which by the initial Optimization scheme is spent capacity. Method according to claim 5, wherein the second optimization scheme is a single increment of the first optimization scheme is removed. Method according to one of Claims 2 to 6, the initial optimization scheme taking into account the speed of movement of the first terminal ( 108 ) is selected. Method according to one the claims 2 to 7, wherein, after registration of a new participant, the for the new participant selected optimization scheme over a comparable amount associated with it Feedback data has existing participants in the same cell. Method according to one of the preceding claims, the scope being available standing capacity in the first band of frequencies is estimated by monitoring error rates. Method according to one of the preceding claims, wherein the first terminal ( 108 ) is a mobile terminal and the second terminal ( 102 ) is a first fixed terminal, wherein the first terminal ( 108 ) is in communication with the first fixed terminal and the second fixed terminal via the first and second bands of frequencies simultaneously, the first and second fixed terminals communicating with the terminal on a respective channel in the first band of frequencies, the perimeter of available capacity for each of the respective channels and the channel having the least amount of available capacity is selected as the basis for selecting the initial optimization scheme. Method according to one of the preceding claims, being, if the amount of available capacity on the first band of frequencies is insufficient to make a transfer of the Feedback data to allow the selected one first optimization scheme no transmission any feedback data requires. Device for duplex communication via a wireless connection between a first and second terminal ( 102 . 108 ) capable of transmitting and receiving on a first and second band of frequencies respectively, the apparatus comprising: a processor for receiving feedback data from the first terminal (10); 108 ) in the first band of frequencies, the feedback data relating to the quality of communications generated by the first terminal ( 108 ) from the second terminal ( 102 ), means for transmitting the feedback data using a variable amount of capacitance of the first band of frequencies, the variable perimeter being a function of the amount of capacitance that has been determined to be available in the first band of frequencies wherein the feedback data is adapted to be a function of the amount of capacity that has been determined to be available on the first band of frequencies, and wherein the processor is adapted to use the feedback data, if present, to transmit data from the second terminal ( 102 ) to the first terminal ( 108 ) on the second band of frequencies, the quality of communications from the second terminal ( 102 ) to the first terminal ( 108 ) is improved with respect to a larger amount of the capacity of the first band of frequencies used by the transmission of the feedback data.