ES2361244T3 - COMPUTER PROGRAM METHODS, SYSTEMS AND PRODUCTS TO REQUEST POWER LEVELS RECEIVED BASED ON RECEIVED BLOCK ERROR RATES USING AN ANTI-SATURATION PROCEDURE AND / OR AN EMERGENCY PROCEDURE. - Google Patents

Abstract

A method of determining a first reference quality measurement value for use in the requested changes in a transmitted power level of a signal received from a communication channel, comprising: comparing (202) a first quality measurement value measured with a predefined range of values associated with a first reference quality measurement value; update (216) the first reference quality measurement value based on a second current estimated quality measurement and a second reference quality measurement if the first measured quality measurement value is within the predefined range; and update (216) the first reference quality measurement value based on the second current estimated quality measurement and the second reference quality measurement if the first measured quality measurement value is outside the predefined range and the update of the First reference quality measurement value brings the first reference quality measurement value closer to the first measured quality measurement value.

Description

Provisional Request Mention

This application claims the benefit of Provisional Application No. 60 / 412,897, made on September 23, 2002, entitled Anti-Windup And Emergency Procedures For Outer Loop Power Controllers Using Filtered Block Error Rates For WCDMA.

Field of the Invention

This invention relates to communication systems, such as wireless communication systems, and operational methods for them, and more particularly for the control of power levels for uplink and / or downlink communications.

Background of the Invention

In conventional communications systems, such as Wideband Code Division Multiple Access (WCDMA) systems, the transmission power can be adjusted by the receiving system by requesting an increase in the transmission power from the transmitter system Thus, for example, a mobile telephone terminal may request that a base station increase its transmission power if the signal-to-interference ratio (SIR) of the received signal is below a predefined threshold. As used herein, the term "mobile telephone terminal" encompasses a wide variety of portable wireless devices that can access a mobile telephone system. The mobile phone terminals. They include, but are not restricted to, a cellular radiotelephone with or without a multi-line display, a Personal Communications System (PCS) terminal that can combine a cellular radiotelephone with data processing, facsimile and / or mobile capabilities. data communications, a Personal Digital Assistant (PDA - Personal Digital Assistant) that can include a radio telephone, pager, Internet / Intranet access, Web browser, organizer, calendar and / or a Global Positioning System (GPS - System receiver) Global Location), and conventional laptop, pocket computer and / or invasive calculation devices that include wireless receivers. In many communication systems, such as a WCDMA system, the transmitted data is organized so that several bits of data are collected in a transport block. Several transport blocks are typically contained in a transmission time interval (TTI). Typically, in order to decode the data transmitted in the transport blocks, the complete TTI must be received. Bits of Cyclic redundancy check (CRC - Cyclic Redundancy Check) are typically added to each transport block. The CRC bits have special coding properties so that if the CRC bits are found to be wrong, the transport block bits are almost certainly incorrectly decoded. Similarly, if the CRC bits are found to be correct, the transport block bits are almost certainly decoded correctly. The block error rate (BLER) for a transport channel can therefore be estimated by filtering the CRC error indicators. (CRC error indicators) filtering of decoded transport blocks. In a conventional power control system for uplink or downlink WCDMA, an inner loop and an outer loop of the power control system are provided. The outer loop sets a reference SIR value based on the deviation of a measured BLER from a reference BLER. The inner loop compares the measured SIR with the reference SIR. If the reference SIR is below the measured SIR, a request is made to increase the received power, and vice versa. In a typical two-loop power control system, the inner loop can be updated at approximately 1500 Hz and the outer loop updated between approximately 10 and approximately 100 Hz. Although requests for changes in power can be made, there is typically no guarantee of that the requested changes are carried out. For example, in a congested system, the base station may not be able to provide the change in the requested transmitted power. If the outer loop power control system bases the measured BLER on the history of the CRC error indicators received, the measured BLER could reach very high levels if the requested power is denied for a prolonged period of time. This increase in the measured BLER may result in an increase in the reference SIR value so that the reference SIR can increase without limits. A potential solution to such an unlimited increase in the reference SIR value is to limit the absolute value. However, in practice it may be difficult to find a sufficiently narrow absolute interval within which the reference SIR value is allowed to operate. In addition to increases in the reference SIR value when higher power requests are not satisfied, when the base station finally provides the requested power increase, the measured BLER can be very high. If a proportional integral derivative controller (PID) is used as the external loop power controller, the reference SIR value could increase at a speed greater than the time of observing the change in the BLER measured as a result of increases in the power of the base station. As a result, an unnecessary amount of power could be requested from the base station. EP 1 067 706 shows a method for improving the performance of a mobile telephone radio communication system using a power control loop, in which the power is controlled according to a transmission quality target value that It is adjusted in an adjustment process using a closed loop power control. The closed loop is executed quickly in order to adjust the transmission quality around the transmission quality target value by returning appropriate power control orders to the transmitter. The transmission quality target value is adjusted in an outer loop that runs more slowly in order to adjust the service quality around a service quality target value. WO 00/65748 shows a power control system in a CDMA mobile phone communication system that uses nested control loops. The external power control loop (slower) controls for example an SIR target value for use in the internal closed power control loop (faster), so that the current Quality of Service is close to Quality of negotiated service. The indoor power control loop estimates the SIR of the broadcast transmission channel, and compares the estimated SIR with the target value of SIR. Based on the results of the comparison, power control orders are transmitted in the return transmission channel, which notify the transmitter of the transmission channel of whether to increase or decrease its transmission power level.

Compendium of the Invention

Embodiments of the present invention provide methods, systems and / or computer program products for determining a reference signal to interference ratio (SIR) value for use in requesting changes in a transmitted power level of a signal received from a communications channel as cited in the appended claims, determining the reference SIR value based on a current estimated block error rate of the communications channel, a reference block error rate and a value of SIR measured from the signal received from the communications channel. As used herein, the term "reference SIR value" refers to a single SIR value and / or a range of approved SIR values corresponding to a reference SIR value. Thus, for example, references to update a reference SIR value or move a reference SIR value may refer to updating or moving a single reference SIR value and / or a range of approved SIR values corresponding to a value of SIR reference. In other embodiments of the present invention, the reference SIR value is determined by comparing the measured SIR value with a predefined range of values associated with a current reference SIR value. The reference SIR value is selectively updated based on the current estimated block error rate, the reference block error rate and the comparison of the measured SIR value with the predefined interval. For example, the reference SIR value can be selectively updated by updating the reference SIR value if the measured SIR value is within the predefined range. The reference SIR value could also be selectively updated by updating the reference SIR value if the measured SIR value is outside the predefined range and the update of the reference SIR value about the reference SIR value to the measured SIR value . The reference SIR value can be determined using a proportional integral derivative determination (PID - Derivative Integral Proportional). In yet other embodiments of the present invention, it is determined whether the reference SIR value was not updated in an immediately prior determination of whether to update the reference SIR value. The current estimated block error rate is initialized if it is determined that the reference SIR value was not updated in an immediately prior attempt to update the reference SIR value. The current estimated block error rate can be updated by limiting the current estimated block error rate with respect to at least one of a reference block error rate and / or a previous estimated block error rate. In addition, the current estimated block error rate can be stored if a prior determination of whether updating the reference SIR value determined not to update the reference SIR value. The current estimated block error rate can be stored by storing the current estimated block error rate if an immediately previous determination of whether to update the reference SIR value updated the reference SIR value and a current determination of whether to update the value Reference SIR does not update the reference SIR value. Also, if an immediately prior determination of whether updating the reference SIR value did not update the reference SIR value and if a current determination of whether updating the reference SIR value updates the reference SIR value, the error rate The current estimated block rate can be updated by adjusting the current estimated block error rate to the lowest of a value based on a reference block error rate, a value based on a stored estimated block error rate and a value based at the current estimated block error rate. As will be apparent to those skilled in the art in light of the present description, the present invention can be realized as methods, systems, computer program products and / or control circuits. In addition, particular embodiments of the present invention may provide mobile terminals and / or base stations.

Brief Description of the Drawings

Figure 1 is a block diagram of mobile phone terminals and / or base stations of

according to some embodiments of the present invention.

Figure 2 is a more detailed block diagram of mobile phone terminals and / or station stations. base in accordance with some embodiments of the present invention. Figure 3 is a block diagram of a power controller according to embodiments of the present invention Figure 4 is a flow chart illustrating operations in accordance with embodiments of the present. invention.

Detailed Description of Accomplishments

The present invention will now be described more fully in the following with reference to the accompanying drawings, in which embodiments of the invention are shown. However, this invention should not be construed as limited by the embodiments explained herein. On the contrary, these embodiments are provided so that this description will be thorough and complete, and will fully bring the scope of the invention to the experts. Equal numbers refer to equal elements throughout the document. It should also be understood that, as used herein, the term "comprising" is open to, and includes one or more elements, stages and / or functions indicated without excluding one or more elements, stages and / or functions not indicated. The present invention is described below with reference to block diagrams and / or flowchart illustrations of mobile telephone methods and terminals according to embodiments of the invention. It should be understood that each block of the block diagrams and / or flow chart illustrations, and block combinations in the block diagrams and / or flow chart illustrations, can be implemented by radio frequency, analog and / or hardware hardware digital, and / or computer program instructions. These computer program instructions may be provided to a processor of a general purpose computer, special purpose computer, digital signal processor and / or other programmable data processing apparatus, for example, to a mobile telephone terminal or station of base, so that the instructions, which are executed by the computer processor and / or other programmable data processing device, create a circuit and / or means to implement the functions / acts specified in the block diagrams and / or block or flowchart blocks. These computer program instructions can also be stored in a computer readable memory that can direct a mobile telephone terminal to operate in a particular way, so that the instructions stored in the computer readable memory produce an article of manufacture that includes instructions that implement the functions / acts specified in the block diagrams and / or block or blocks of the flow chart. The computer program instructions can also be loaded into a computer or another programmable data processing apparatus to generate a series of operational steps to be performed in the computer or another programmable apparatus in order to produce a process implemented in a computer, so that the instructions that are executed on the computer or on another programmable device provide steps to implement the functions / acts specified in the block diagrams and / or in the blocks or blocks of the flow chart. It should also be noted that in some alternative implementations, the functions / acts denoted in the blocks may occur outside the order denoted in the flowcharts. For example, two blocks shown in succession may actually be executed substantially concurrently or the blocks may sometimes be executed in reverse order, depending on the functionality / acts involved. Embodiments of the present invention will now also be described with reference to the illustration of the schematic block diagram of a communication device 100 in Figure 1, such as a terminal and / or mobile telephone base station. Figure 1 illustrates a device 100 that may comprise a network transceiver 125, and a memory 130 that communicates with a processor 140. As also illustrated in Figure 1, the communication device 100 may also include one or more of the keyboard / numeric keypad 105, a display 110, a speaker 115 and / or a microphone 120. The network transceiver 125 typically includes a transmitter circuit 150 and a receiver circuit 145, which respectively transmit outgoing radio frequency signals to / from a base station or wireless terminal and receive incoming radio frequency signals to / from the base station or wireless terminal via an antenna 165. Although a single antenna 165 is shown in Figure 1, it should be understood that multiple antennas and / or different types can be used of antennas based on the types of signals that are received. The radio frequency signals transmitted between the communication device 100 and a mobile telephone base / terminal station may comprise both traffic and signal control (for example, pager signals / messages for incoming calls), which are used to establish and maintain communication with another partner or destination, and may provide uplink and / or downlink communications. However, the present invention is not limited to such bi-directional communication systems. The above components of the communication device 100 may be included in many conventional mobile telephone terminals and their functionality is generally known to experts. It should also be understood that, as used herein, the term "mobile telephone terminal" may include, but is not limited to, a mobile radio telephone with or without a multi-line display; a Personal Communications System (PCS) terminal that can combine a mobile radiotelephone with data processing, facsimile and data communications capabilities; a Personal Data Assistant (PDA - Personal Data Assistant) that may include a radio telephone, pager, Internet / Intranet access, Network explorer, organizer, calendar and / or a Global Positioning System (GPS - Global Location System receiver) ); and a conventional laptop and / or pocket computer receiver or other application that includes a radio transceiver. Mobile telephony terminals can also be called "extended calculation" devices. Although the present invention may be realized in communication devices or systems, such as the communication device 100, the present invention is not limited to such devices and / or systems. On the contrary, the present invention can be realized in any method, transmitter, communication device, communication system or computer program that uses subsequent provisioning messages initiated in the network. Figure 2 is a block diagram of embodiments of a communications device 100 ’illustrating computer program systems, methods and products in accordance with embodiments of the present invention. The processor 240 communicates with the memory 236 via an address / data bus 248. The processor 240 may be any commercially available or custom-made microprocessor that includes, for example, a digital signal processor. Memory 236 is representative of the global hierarchy of memory devices that contain the software and data used to implement the functionality of the communications device 100 ’. Memory 236 may include one or more of, but is not limited to, the following types of devices: cache, ROM, PROM, EPROM, EEPROM, recording memory, SRAM and DRAM. As shown in Figure 2, memory 236 may include several categories of software and / or data used in the communications device 100 ’: operating system 252; application programs 254; the activators 258 of input / output device (I / O - Input / Output); and 256 data. As will be apparent to the experts, the operating system 252 can be any operating system suitable for use with a terminal and / or mobile phone base station, such as OS / 2, AIX or International System 390 Business Machines Corporation, Armonk, NY, WindowsCE, Windows95, Windows98, Windows2000, WindowsNT or WindowsXP from Microsoft Corporation, Redmont, WA, Unix, Linux, Palm OS, custom or proprietary operating systems. Operating systems can be configured to support a communication protocol connection based on IP or another similar network. Triggers 258 of the I / O device typically include software routines that are accessed through operating system 252 through application programs 254 for communicating with devices such as transceiver 125 and certain memory components 236. Programs 254 of application are illustrative of the programs that implement the different characteristics of the mobile telephone terminal 100 and preferably include at least one application that supports operations in accordance with embodiments of the present invention. Finally, the data 256 represents the static and dynamic data used by the application programs 254, the operating system 252, the I / O device activators 258, and other software programs that may reside in memory 236. As seen Also in Figure 2, the application programs 254 may include a power control module 261. The power control module 261 can perform the operations described herein to determine if a different transmission power is to be requested. by the communication device 100. The data portion 256 of the memory 236, as shown in the embodiments of Figure 2, may include BLER data 262 that stores BLER information as described herein. Although the present invention is illustrated, for example, with reference to the power control module 261 as an application program in Figure 2, as will be apparent to the experts, other configurations can also be used even benefiting from the teachings of the present invention. . For example, the power control module 261 can also be incorporated into the operating system 252, the triggers 258 of the I / O device or other such logical division of the communication device 100. Thus, the present invention should not be construed as limited to the configuration of Figure 2 but is intended to encompass any configuration capable of carrying out the operations described herein. Figure 3 is a block diagram of a power control system 10, such as that which may, for example, be provided by the power control module 261, in accordance with certain embodiments of the present invention. As seen in Figure 3, the power control system 10 receives input pilot symbols as inputs from which an estimate of the SIR of the signal received by the SIR estimator 20 is determined. The estimation of the SIR from the pilot symbols is known to the experts and the SIR estimator 20 can be a conventional SIR estimator such as those used in conventional power control systems. Thus, the SIR estimator 20 will not be described in more detail herein. The power control system 10 also receives as CRC error flags (CRCef - CRC error indicators) input that are provided to a block error rate estimator 22 (BLER). The BLER estimator 22 may carry out operations such as those described herein to estimate the block error rate of the communication channel based on CRC error indicators. The BLER is provided to an external loop control regulator, regulator 124, which also receives a BLER reference value. The regulator 124 determines a reference SIR value based on the BLER from the BLER estimator 22, the measured SIR value and the reference SIR value and provides the reference SIR value to an internal loop control regulator , regulator 226. In certain embodiments of the present invention, the reference SIR value may be generated by regulator 124 based on a filtered block error rate. The regulator 226 generates a transmission power control signal (TPC) based on the relationship between the measured SIR value provided by the SIR estimator 20 and the reference SIR value provided by the regulator 124. They can internal loop control regulator operations are carried out to generate the TCP signal based on the measured SIR value and the reference SIR value in a conventional manner and, therefore, will not be described further herein. Operations of the power control system 10 for a transport channel having a TTI containing B transport blocks will now be described in more detail. The CRC error indicators for the transport channel can be denoted as CRCefb for b from zero to B-1. The last interval of the TTI vessel can be designated k_n. The reference SIR value can be designated SIRref and the measured SIR value filtered in the last interval of the TTI vessel can be designated SIRfilt, k_n. The block error rate filtered at the end of the TTI vessel may be designated BLERn and the reference SIR value may be designated BLERref. In that case, BLERn can be determined by iterating the following equation:

image 1

This equation is iterated B times 0 being the filtered error rate of the previous TTI, BLERn-1. The filtered error rate of the TTI ship, BLERn, is then given by B for the constant λ, which may depend on the BLERref reference block error rate. For example, in certain embodiments of the present invention, λ may range from about BLERref / 40 to about BLERref / 5. In particular embodiments of the present invention, it is BLERref / 20. In addition, in certain embodiments of the present invention, the reference SIR value is updated to provide an updated reference SIR value (SIRref, n) based on a current reference SIR value (SIRref, n1), determining the following :

image 1

where in = BLERn-BLERref and the initial block error rate (BLER0) is equal to BLERref. The value of K is the control constant, as described, for example, in Åstrǒm et al., "Computer-Controlled Systems, Theory and Design." 2nd edition, Prentice Hall, 1984. In particular embodiments of the present invention, K can range from about 1/8 to about 2 and in certain embodiments K is 0.5. In some embodiments of the present invention, an anti-saturation method is provided to update the reference SIR value (SIRref) to selectively update the SIRref based on the ratio of the measured SIR value to the reference SIR. In particular embodiments, the measured SIR is a filtered SIR value for the last interval of the TTI ship. This value can be compared with a predefined range of values associated with the reference SIR value and the reference SIR value is updated if the measured SIR value is within the predefined range, or if the reference SIR value update approach the reference SIR value to the measured SIR value. For example, in the system described above, the values for in, SIRfilt, k_n is greater than the current reference SIR value (SIRref, n-1) and if c1SIRref, n is greater than SIRfilt, k_n. If both conditions are met, then the measured measured SIR value is within 10logc1 dB of the reference value and the reference SIR value is updated, either with a value based on the current reference SIR value, the rate of measured block error and the reference block error rate or, in certain embodiments, a value based on the current reference SIR value as described below with respect to the emergency procedure. In the present example, c1 may be 2. In addition, the measured measured SIR value may be used instead of the instantaneous measured SIR value because the instantaneous value may be associated with a high noise level. Additionally, it can be determined if c1SIRfilt, k_n is less than or equal to the current reference SIR value (SIRref, n-1) and if it is less than 0. If so, then the measured measured SIR value is 10logc1 dB or much greater than (less than) the current reference SIR value and the change in the reference SIR value resulting from (ie, the measured block error rate is less than the reference block error rate) it is close to the reference SIR value to be within 10logc1 dB of the measured measured SIR value. If so, then the reference SIR value is updated as described above. It can also be determined if SIRfilt, k_n is greater than or equal to c1SIRref, n-1 and if in is greater than zero. If so, then the measured measured SIR value is 10logc1 dB or very different from (greater than) the current reference SIR value and the change in the reference SIR value resulting from (ie the error rate of measured block is greater than the reference block error rate) about the reference SIR value to be within 10logc1 dB of the filtered measured SIR value. If so, then the reference SIR value is updated as described above. In further embodiments of the present invention, an anti-saturation method is provided for the measured block error rate. Such anti-saturation procedure of the block error rate can be used alone or in combination with the anti-saturation procedure of the reference SIR. The anti-saturation procedure of the block error rate selectively establishes the block error rate used in updating the reference SIR value based on whether the anti-saturation of the SIR has been used for the preceding TTI. If so, the current block error rate used to determine the reference SIR value can be adjusted to avoid unlimited increases in the reference SIR value. For example, the current block error rate may be limited to the lower of a weighted reference block error rate, a weighted current block error rate and a previously weighted stored block error rate. For example, if the conditions described above with respect to the anti-saturation procedure for the reference SIR value are not met for an attempt to update the reference SIR value, then BLERn can be equalized to:

image 1

(1), (2)

where c2 c2 and c2 (3) are constants associated with the respective BLER values and where BLERfreeze is the BLER value of the previous attempt to update to the reference SIR value. For example, constant values can be equal to c1 (1) = 2, c2 (2) = 1 and c2 (3) = 2. Thus, the BLER value is limited to no more than twice BLERref. In yet another embodiment of the present invention, an emergency procedure is provided if more than a number of consecutive transport blocks have a number of CRC errors that is greater than a predefined threshold. In such a case, the reference SIR value can be matched to a value based on the current reference SIR value without reference to the block error rate in order to take into account severe error conditions in the communications channel. . For example, the quality of the propagation channel can be checked by determining whether the number of transport blocks that have CRC errors is greater than a threshold value for a series of successive TTIs. Thus, for example, CRC error indicators in a TTI can be counted to determine if at least c3B error indicators were established, where c3 is a value from 0 to 1. For example, c3 can be 0.5. If the threshold number of error indicators are set for a TTI, the number of consecutive TTIs can be counted with the threshold level of error indicators and, if a sufficiently high number (c4) is reached, emergency procedures may be performed. The threshold value c4 can be fixed or variable. For example, the value of c4 could vary depending on the reference BLER value. Thus, for example, values of c4 can be provided as c4 = 4 for a BLERref = 0.1, c4 = 3 for BLERref = 0.01 and c4 = 2 for BLERref = 0.001. As described above, if the emergency criteria are met, the reference SIR value can be equal to c5SIRref, n-1, where c5 can be equal to 2 or another value such that it can, for example, be determined empirically In addition, the BLERn value can also be adjusted. For example, BLERn can be considered as

(4) (4)

BLERn = min (c2 (4) BLERn, c2 (5) BLERref), where c2 and c2 (5) are constants, such that c2 = c2 (5) = 1. Particular embodiments of the present invention will now be described with reference to the illustration of the flow chart of Figure 4 which is an operation flow chart incorporating reference SIR anti-saturation, BLER anti-saturation and emergency emergency procedures. according to embodiments of the present invention. As seen in Figure 4, a measured SIR value filtered SIRfilt, k_n, a BLERn value and a value of en are determined (block 200). These values can be determined as described above. The measured measured SIR value and / or the en value are evaluated to determine if the filtered measured SIR value is within a predefined range of the reference SIR value and / or if the filtered measured SIR value is outside the range , but resulting in the change in the reference SIR value in which the measured measured SIR value approaches the interval (block 202). Such determination can be made as described above. If the conditions for the measured measured SIR value and / or the en value are not met (block 202), the reference SIR value is not updated (block 204). If the reference SIR value is not updated (block 204), a determination is made as to whether it is the first time that the reference SIR value has not been updated since a valid update (block 206). Such determination can be carried out, for example, by determining whether an indicator has been previously established indicating that a reference SIR value was not updated. If it is not the first time (block 206), then other operations for the current update are ignored. If it is the first time that the reference SIR value has not been updated (block 206), the current BLER value is stored, for example, as BLERfreeze, and an indicator is set (bler_windup) indicating that the SIR value of reference was not updated and that the BLER anti-saturation procedure is going to be used (block 208). After storing the BLER value and setting the indicator, other operations for the current update are ignored. If the conditions for the measured measured SIR value and / or the en value are met (block 202), the BLER anti-saturation indicator (bler_windup) is evaluated to determine if it is set (block 210). If not, a determination is made as to whether a predefined number of consecutive TTIs (c4) have reported more than one threshold value (c3B) of CRC errors (block 212). If so, the emergency procedure is used to update the reference SIR value (block 214). For example, the reference SIR value can be adjusted to a value proportional to the current reference SIR value as described above. The relationship between the updated reference SIR value and the current reference SIR value can be fixed or variable. If a predefined number of consecutive TTIs (c4) have not reported more than one threshold value (c3B) of CRC errors (block 212), the reference SIR value is updated using, for example, the determination of PID or Another suitable regulator. Thus, for example, the reference SIR value can be updated by determining SIRref, n = Ken + SIRref, n-1.

Returning to block 210, if the BLER anti-saturation indicator (bler_windup) is set (block 210), the BLER anti-saturation procedure is carried out by the BLER value that is reset to limit the value range BLER and the BLER anti-saturation indicator is reset (block 218). The reference SIR value is updated using the reset BLER value using the PID determination (block

5 216). Thus, for example, a new value of en can be generated using the reset BLER value and the reference SIR value can be updated by determining SIRref, n = Ken + SIRref, n-1. In addition, the BLER value can, for example, be reset to limit the BLER value range by determining min (c2 (1) BLERfreeze, c2 (2) BLERn-1, c2 (3) BLERref) as described above. A Pseudo-code is provided below for certain embodiments of the present invention incorporating

10 both anti-saturation procedures and the emergency procedure. Such operations can, for example, be carried out by an external loop control regulator on a two-loop power control circuit, such as regulator 124 of Figure 1. As initial values, the values for in, SIRfilt , k_n, BLERn are determined before the start of the Pseudo-code. The value of bler_windup should be initialized to zero.

fifteen

image 1

In this Pseudo-code, the outer “if” condition provides the anti-saturation of SIR and the initial test for the anti-saturation of BLER. The “else” portion of the outer “if” condition equals SIRref, na SIRref, n-1 in order to avoid updating if the conditions are not met and also sets the bler_windup indicator to indicate that an attempt to update the value Reference SIR failed to update the reference SIR value. The first internal “if” condition determines the number of TTIs that have had blocks with CRC errors over a predefined threshold for the emergency procedure. The second inner “if” condition tests to determine the BLER anti-saturation indicator is set and if so, the BLER value is updated. If not, then the emergency procedure threshold c4 is tested by the following "if" condition to determine if the emergency threshold has been reached and, if so, the emergency procedure is carried out. If not, the reference SIR is updated using the PID control value. Embodiments of the present invention have been described with reference to measured values, such as SIR and BLER. However, such term is used in a general sense and includes values that are estimated based on received signals and / or transport blocks and values that are measured directly or indirectly. In addition, the term measured is also intended to include values that have been subsequently processed, for example, by filtration or other treatment. Although the present invention has been described with reference to the communication channel which is a wireless communications medium, embodiments of the present invention can also be used in cable communications means where a receiving device may request changes in the transmission power. In addition, although embodiments of the present invention have been described with reference to particular equations for determining an updated reference SIR value, the present invention should not be considered as limited to such equations but is intended to cover any technique for calculating a value of Reference SIR updated from a previous reference SIR value using error rates of the decoded received signal. Although embodiments of the present invention have been described with reference to a single transport channel, as will be understood by the experts in light of the present description, embodiments of the present invention may also include multiple transport channels. In such embodiments, a reference SIR value may be associated with each transport channel. A final reference SIR value could be determined based on the multiple reference SIR values, for example, by selecting a maximum value, by a linear combination of the reference SIR values or by other combinations of reference SIR values. In addition, although embodiments of the present invention have been described with reference to SIR values, the teachings of the present invention could also be used with other quality measures. In the drawings and specifications, embodiments of the invention have been described and, although specific terms are used, they are used in a generic and descriptive sense and not for purposes of limitation, the scope of the invention being explained in the following claims.

Claims (30)

one.

 A method of determining a first reference quality measurement value for use in the requested changes in a transmitted power level of a signal received from a communication channel, comprising:

comparing (202) a first measured quality measurement value with a predefined range of values associated with a first reference quality measurement value; update (216) the first reference quality measurement value based on a second current estimated quality measurement and a second reference quality measurement if the first measured quality measurement value is within the predefined range; and update (216) the first reference quality measurement value based on the second current estimated quality measurement and the second reference quality measurement if the first measured quality measurement value is outside the predefined range and the update of the First reference quality measurement value brings the first reference quality measurement value closer to the first measured quality measurement value.

2.

 The method of Claim 1, wherein the first quality measurement comprises a signal to interference ratio (SIR) and the first reference quality measurement value comprises a reference SIR value and a second Quality measurement comprises a block error rate.

3.

 The method of Claim 2, which also comprises:

determine if the reference SIR value was not updated in an immediately previous evaluation to determine if the reference SIR value is to be updated; and update the current estimated block error rate if it is determined that the reference SIR value was not updated in an immediately prior evaluation to determine if the reference SIR value is to be updated.

Four.

 The method of Claim 3, wherein updating the current estimated block error rate comprises limiting the current estimated error rate with respect to at least one reference block error rate and / or an estimated block error rate previous.

5.

 The method of Claim 4 which also comprises storing the current estimated block error rate if the evaluation to determine if the reference SIR value does not result in updating the reference SIR value.

6.

 The method of Claim 5, wherein storing the current estimated block error rate comprises storing the current estimated block error rate if an immediately prior evaluation to determine if the reference SIR value is to be updated results in updating the reference SIR value and a current evaluation to determine if the reference SIR value is going to be updated does not result in updating the reference SIR value.

7.

 The method of Claim 5, wherein updating the current estimated block error rate comprises adjusting the current estimated block error rate to a lower value of a value based on a reference block error rate, in a value based on the estimated estimated block error rate and a value based on the current estimated block error rate.

8.

 The method of Claim 2, which also comprises:

determine whether a plurality of successive transmission time intervals (TTIs) have a higher value than the threshold of transport blocks having error conditions; and wherein determining the reference SIR value comprises adjusting the reference SIR value to a value independent of the estimated block error rate if it has been determined that a plurality of successive TTIs have a value greater than a block threshold of transport that has error conditions.

9.

 The method of Claim 8, wherein adjusting the reference SIR value comprises adjusting the reference SIR value by scaling the current reference SIR value with a constant value if it has been determined that a plurality of successive TTIs have a value greater than a threshold of transport blocks that have error conditions.

10.

 The method of Claim 8, wherein determining the reference SIR value comprises:

determine the reference value using a proportional integral derivative determination (PID - Derivative Integral Proportional) if it has not been determined that a plurality of successive TTIs have a value greater than a threshold of transport blocks that have error conditions; and determine the reference value without using the PID determination if it is determined that a plurality of successive TTIs have a value greater than a threshold of transport blocks that have error conditions.

eleven.

 The method of Claim 2, wherein updating the reference SIR value comprises updating the reference SIR using a derivative integral proportional determination.

12.

 The method of Claim 2, wherein the measured SIR value comprises a plurality of measured SIR values for different transport channels, the method also comprising updating the reference SIR value based on the plurality of measured SIR values.

13.

 A power control circuit (10) of a communications device comprising:

a power control loop (26) configured to request changes in transmitted power based on a measured signal to interference ratio (SIR) value and a reference SIR value; Y an external power control loop (24) configured to provide the reference SIR value to an indoor control loop, the outer control loop comprising: a control regulator configured to compare the measured SIR value with a predefined range of values associated with a current reference SIR value and selectively update the reference SIR value based on the current estimated block error rate, the rate of reference block error and comparison of the measured SIR value with the predefined interval, to update the reference SIR value if the measured SIR value is within the predefined range and to update the reference SIR value if the value of Measured SIR is out of the predefined range and updating the reference SIR value brings the reference SIR value closer to the measured SIR value.

14.

 The power control circuit of Claim 13, wherein the control regulator is also configured to update the reference SIR value using a proportional integral derivative determination.

fifteen.

 The power control circuit of Claim 13, wherein the control regulator is also configured to determine if the reference SIR value was not updated in an immediately prior evaluation in order to determine whether the reference SIR value It will be updated and update the current estimated block error rate if it is determined that the reference SIR value was not updated as a result of the immediately previous evaluation.

16.

 The power control circuit of Claim 15, wherein the control regulator is configured to update the current estimated block error rate by limiting the current estimated block error rate with respect to at least one block error rate of reference and / or a previous estimated block error rate.

17.

 The power control circuit of Claim 15, wherein the control regulator is also configured to store the current estimated block error rate if an evaluation to determine if the reference SIR value is to be updated does not result in an update of the reference SIR value.

18.

 The power control circuit of Claim 17, wherein the control regulator is also configured to store the current estimated block error rate if an immediately prior evaluation to determine whether the reference SIR value to be updated results in updating the reference SIR value and a current evaluation to determine if the reference SIR value is to be updated does not result in updating the reference SIR value.

19.

 The power control circuit of Claim 17, wherein the control regulator is also configured to adjust the current estimated block error rate to a lower value of a value based on a reference block error rate, in a value based on the estimated block error rate and in a value based on the current estimated block error rate.

twenty.

 The power control circuit of Claim 13, wherein the control regulator is also configured to determine whether a plurality of successive transmit time intervals (TTIs) have a value greater than a block threshold of transport that have error conditions; Y

adjust the reference SIR value to a value independent of the estimated block error rate if it is determined that a plurality of successive TTIs have a value greater than a threshold of transport blocks that have error conditions.

twenty-one.

 The power control circuit of Claim 20, wherein the control regulator is also configured to adjust the reference SIR value by scaling the current reference SIR value with a constant value if it is determined that a plurality of successive TTIs It has a value greater than a threshold of transport blocks that have error conditions.

22

 The power control circuit of Claim 20, wherein the control regulator is also configured to determine the reference value using a proportional integral derivative determination (PID

- Proportional Integral Derivative) if it is not determined that a plurality of successive TTIs have a value greater than a threshold of transport blocks that have error conditions and determine the reference value without using the PID determination if it is determined that a plurality of TTIs They have a value greater than the threshold of transport blocks that have error conditions.

2. 3.

 The power control circuit of Claim 13, wherein the communication device comprises a mobile telephone terminal.

24.

 The power control circuit of Claim 13, wherein the communication device comprises a wireless base station.

25.

 A system for determining a reference signal to interference ratio (SIR) signal for use in requesting changes in a transmitted power level of a signal received from a communications channel, comprising:

means for determining a measured SIR value of the signal received from the communications channel; means for comparing the measured SIR value with a predefined range of values associated with a current reference SIR value; means for updating the reference SIR value based on a current estimated block error rate and a reference block error rate if the measured SIR value is within the predefined range; and means for updating the reference SIR value based on the current estimated block error rate and the reference block error rate if the measured SIR value is outside the predefined range and the update of the reference SIR value brings the reference SIR value closer to the measured SIR value.

26.

 The system of Claim 25, which also comprises:

means to determine if the reference SIR value was not updated in an immediately prior attempt to update the reference SIR value, and means to determine the current estimated block error rate if it is determined that the reference SIR value is not it was updated as a result of an immediately previous evaluation to determine if the reference SIR value is not going to be updated

27.

 The system of Claim 25, which also comprises:

means for determining whether a plurality of successive transmission time intervals (TTIs) have a value greater than the threshold of transport blocks having error conditions; and wherein the means for determining the reference SIR value also comprise means for adjusting the reference SIR value to a value independent of the estimated error rate if it is determined that a plurality of successive TTIs have a value greater than one threshold of transport blocks that have error conditions.

28.

 A computer program product for determining a reference signal to interference ratio (SIR) value for use in requesting changes in a transmitted power level of a signal received from a communications channel, comprising :

computer-readable media having a computer-readable program codec incorporated therein, comprising the computer-readable program code: a computer-readable program code configured to determine a measured SIR value of the signal received from the communications channel ; a computer readable program code configured to compare the measured SIR value with a predefined range of values associated with a current reference SIR value; a computer readable program code configured to determine the reference SIR value based on a current estimated block error rate and a reference block error rate if the measured SIR value is within the predefined range; and a computer-readable program code configured to determine the reference SIR value based on the current estimated block error rate and the reference block error rate if the measured SIR value is outside the predefined range and the update of the reference SIR value about the reference SIR value to the measured SIR value.

29.

 The computer program product of Claim 28, which also comprises:

a computer readable program code configured to determine if the reference SIR value was not updated as a result of an immediately prior evaluation to determine if the reference SIR value is to be updated; and a computer readable program code configured to determine the current estimated block error rate if it is determined that the reference SIR value was not updated as a result of an immediately prior evaluation in order to determine whether the SIR value of Reference will be updated.

30

 The computer program product of Claim 28, which also comprises:

a computer-readable program code configured to determine whether a plurality of successive transmission time intervals (TTIs) have a value greater than a threshold of transport blocks having error conditions; and wherein the computer readable program code configured to determine the reference SIR value also comprises a computer readable program code configured to adjust the reference SIR value to a value independent of the estimated block error rate. if it is determined that a plurality of successive TTIs have a value greater than a threshold of transport blocks that have error conditions.