JP2013118587A - Communication terminal and response control unit - Google Patents

Abstract

PROBLEM TO BE SOLVED: To suppress repeated transmission of an identical packet because of non-arrival of an acknowledgement signal.SOLUTION: A communication terminal comprises: a transmitter unit for transmitting a response signal to a base station; a receiver unit for receiving a reception signal from the base station; and a response control unit for controlling the transmitter unit to transmit an acknowledgement signal to the base station when the reception signal is received normally. After the reception signal is received normally and the acknowledgement signal is transmitted with first transmission power, if there is the retransmission of a normally received reception signal, the response control unit controls to retransmit the acknowledgement signal with second transmission power larger than the first transmission power.

Description

  The present invention relates to a communication terminal and a response control unit.

  For communications that are prone to errors (for example, wireless communications), if a packet is not normally received, a mechanism that requests that the packet be retransmitted (retransmitted) (automatic repeat request, ARQ (Automatic Repeat Request) ) Is provided.

  In this mechanism (automatic retransmission request), when the packet is normally received, the receiving side returns (transmits) an ACK (Acknowledgements) signal to the transmitting side. The transmitting side to which the ACK signal is returned transmits the next packet to the receiving side.

  On the other hand, if the packet is not normally received, the receiving side returns a NACK (Negative Acknowledgments) signal to the transmitting side. The transmitting side to which the NACK signal is returned retransmits the packet that has not been normally received.

  If neither the ACK signal nor the NACK signal (hereinafter referred to as a response signal) is returned after a predetermined time has passed after the packet is transmitted, the transmitting side retransmits the same packet to the receiving side.

  By such a procedure, the packet is reliably transmitted from the transmission side to the reception side.

JP 2006-262357 A

  If the transmission power of response signals (ACK signal and NACK signal) is low, the response signal may deteriorate in the propagation path, and the ACK signal may not be demodulated on the transmission side. In this case, although the packet is normally received by the receiving side, the transmitting side determines that the response signal has not been transmitted, and the same packet is retransmitted to the receiving side many times. As a result, communication efficiency is significantly reduced. This problem is likely to occur in a wireless terminal such as WiMAX (World Interoperability for Microwave Access).

  In order to solve the above problem, according to one aspect of the present apparatus, a communication terminal including a transmission unit, a reception unit, and a response control unit is provided.

  The transmitter transmits a response transmission to the base station. The reception unit receives a reception signal from the base station. The response control unit controls the transmission unit to transmit an acknowledgment signal to the base station when the reception signal is normally received.

  Further, the response control unit may receive the first signal when the received signal is normally received after the received signal is normally received and the acknowledgment signal is transmitted with the first transmission power. Control is performed so that the acknowledgment signal is retransmitted at a second transmission power larger than the transmission power.

  According to this apparatus, repeated transmission of the same packet due to non-arrival of the ACK signal to the base station is suppressed.

It is a block diagram of a communication terminal. It is an example of the more detailed block diagram of a communication terminal. 3 is a diagram illustrating a signal flow in the communication terminal according to Embodiment 1. FIG. It is a figure which shows the flow of the signal in a response control part. It is a flowchart of the response control which a response control part performs. It is a flowchart of the response control which a response control part performs. It is a response sequence of a communication terminal. It is a response sequence of a communication terminal. It is a response sequence of a communication terminal. FIG. 10 is a configuration diagram of a response control unit according to a second embodiment. FIG. 10 is a configuration diagram illustrating a modification of the communication terminal according to the second embodiment. FIG. 10 is a configuration diagram of a response control unit according to a third embodiment. It is explanatory drawing of the correction process which an adjustment value correction | amendment part performs.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings. However, the technical scope of the present invention is not limited to these embodiments, but extends to the matters described in the claims and equivalents thereof. In addition, the same code | symbol is attached | subjected to the corresponding part even if drawings differ, and the description is abbreviate | omitted.

(Embodiment 1)
FIG. 1 is a configuration diagram of the communication terminal 2. As illustrated in FIG. 1, the communication terminal 2 includes an antenna 4, a reception unit 6, a transmission unit 8, a response control unit 10, and a data processing unit 12.

  The receiving unit 6 receives a received signal such as a packet (hereinafter referred to as a received packet) or a control signal transmitted from a base station (not shown) via the antenna 4.

  The data processing unit 12 processes received packets and input data, and generates packets and control signals to be transmitted to the base station. The transmission unit 8 transmits a radio signal obtained by frequency-converting a transmission signal such as a packet (hereinafter referred to as a transmission packet) or a control signal (including a response signal) generated by the data processing unit 12 via the antenna 4. Send to base station.

  The response control unit 10 controls the transmission unit 8 to send an ACK signal (acknowledgment signal) to the base station when the received packet is normally received (the transmission unit transmits the ACK signal to the base station). To control.) On the other hand, when the received packet is not normally received, the response control unit 10 controls the transmission unit 8 to transmit a NACK signal (negative acknowledgment signal) to the base station (so as to transmit the NACK signal to the base station). To control the transmitter.)

  Further, when the received packet is normally received and the ACK signal is transmitted (transmitted) with the first transmission power and then the normally received received packet is retransmitted from the base station, the response control unit 10 Control is performed to return the ACK signal to the transmitter again with a second transmission power higher than the first transmission power. That is, in the above case, the response control unit 10 controls the transmission unit to return the ACK signal again with the second transmission power higher than the first transmission power. Returning is to transmit a response signal such as an ACK signal or a NACK signal to the transmission side (the communication apparatus that transmitted the reception signal) in response to the reception signal.

  Hereinafter, the communication terminal 2 will be described in detail when the communication method is mobile WiMax (IEEE802.16e-2005). However, Embodiment 1 is applicable not only to mobile WiMax but also to other communication methods (particularly wireless communication).

(1) Receiving Unit FIG. 2 is an example of a more detailed configuration diagram of the communication terminal 2. FIG. 3 is a diagram illustrating a signal flow in the communication terminal 2.

  As shown in FIG. 2, the receiving unit 6 includes a radio frequency integrated circuit (RF IC) 14, an analog-digital converter (ADC) 16, a fast Fourier transformer (FFT) 18, and a demodulator 20. And have.

  As shown in FIG. 3, when a radio signal (received packet, control signal, etc.) transmitted from the base station enters the antenna 4, the high-frequency integrated circuit 14 converts the frequency of the received radio signal to generate an analog baseband signal 22a. Is supplied to the analog-digital converter 16. The analog-digital converter 16 converts the supplied analog baseband signal 22 a into a digital signal 24 and supplies it to the fast Fourier transformer 18.

  The fast Fourier transformer 18 Fourier-transforms the digitized baseband signal 24, and frequency domain data 26 (combination of frequency, amplitude, and phase) for each time slot (one section obtained by dividing a frame by time). Convert to The converted frequency domain data 26 is supplied to the demodulator 20.

  The demodulator 20 converts (demodulates) the frequency domain data into time domain data (bit string). However, packets transmitted to other communication terminals are not demodulated.

  Of the demodulated data, data corresponding to the control signal (demodulated control signal) is supplied to the reception unit 6, the transmission unit 8, the response control unit 10, and the like, and is used for control of reception and transmission of radio signals. The Data 28a (demodulated received packet) corresponding to the received packet among the demodulated data is supplied to the response control unit 10.

  Thus, the receiving unit 6 receives a packet (received packet) and a control signal transmitted from the base station.

  Radio signal modulation schemes include quadrature phase shift keying (QPSK) and quadrature amplitude modulation (QAM). The radio signal may be modulated in a different manner for each combination of time slot and frequency domain. The same applies to the modulation method of the transmitter 8 described later.

(2) Data Processing Unit The data processing unit 12 includes, for example, a CPU (Central Processing Unit) 30, a memory 32, a DL (Downlink) memory 34, and a UL (Uplink) memory 36. The configuration of the memory is an example, and may be configured by one memory. The data processing unit 12 is further connected to an upper layer data processing unit (not shown).

  As will be described later, the response control unit 10 performs error correction (decoding) and error detection for correcting an error occurring during transmission or reception on the demodulated reception packet 28a. The received packet having no error and the received packet 38 in which the error is correctly corrected are stored in the DL memory 34.

  The CPU 30 processes the received packet 38 recorded in the DL memory 34 and the data supplied from the input unit according to the program recorded in the memory 32, and is supplied to the transmission data and output unit transmitted to the base station. Output data is generated. The generated transmission data is divided into transmission packets and recorded in the UL memory 36.

  In addition to the program, the memory 32 stores data in the middle of calculation and data for storage.

(3) Transmitter As shown in FIG. 2, the transmitter 8 includes a subcarrier allocation unit 40, an inverse fast Fourier transform (IFFT) unit 42, a digital-analog converter 44, and a high-frequency integrated circuit. 14. The subcarrier allocation unit 40 includes, for example, a logic circuit and a memory (including a buffer). The subcarrier allocation unit 40 may have a CPU instead of the logic circuit.

  As shown in FIG. 3, the transmission packet 46 recorded in the UL memory 36 is supplied to the response control unit 10. As will be described later, the supplied transmission packet 46 is added with an error detection code (for example, CRC (Cyclic Redundancy Check) code) and further encoded (for example, turbo encoded) so that error correction can be performed. The encoded transmission packet 48 is supplied to the subcarrier allocation unit 40.

  The subcarrier allocation unit 40 converts (modulates) the transmission packet 48 and the response code 50 into frequency domain data (a combination of frequency, amplitude, and phase) 52.

  At this time, one bit or a plurality of consecutive bits (bit string) of the transmission packet 48 and the response code 50 are allocated to one of the plurality of frequencies (subcarriers). Each subcarrier is time-divided in a common time slot.

  The transmission packet 48 and the response code 50 modulated to the frequency domain data 52 are supplied to the inverse fast Fourier transform unit 42. The inverse fast Fourier transform unit 42 performs inverse Fourier transform on the supplied frequency domain data 52 for each time slot to generate time domain data 54. The generated time domain data 54 is supplied to the digital-analog converter 44.

  The digital-analog converter 44 converts the supplied time-domain data 54 into an analog baseband signal 22b and supplies it to the RFIC 14.

  The RFIC 14 mixes the supplied analog baseband signal 22b with a carrier wave to convert it into a radio signal, and transmits it to the base station via the antenna 4. Through the above procedure, the transmission unit 8 transmits the transmission packet 46 and the response signal (response code) 50 to the base station.

  Communication between the base station and the communication terminal 2 is performed using a TDD (Time Division Duplexing) frame having a downlink subframe and an uplink subframe.

  First, the base station transmits a downlink subframe including a control signal and a received packet to a plurality of communication terminals. When the transmission of the downlink subframe is completed, the plurality of communication terminals transmit the transmission packet 48 and the response signal 50 to the base station using the common uplink subframe.

  Data transmitted from the base station is assigned to regions (preamble, FCH (Frame Control Header), MAP, burst, etc.) in the downlink subframe. On the other hand, data transmitted from the communication terminal 2 to the base station is assigned to a region (ACKCH, burst, etc.) in the uplink subframe.

  The response signal transmitted from the communication terminal 2 is transmitted on the ACKCH (ACK channel) of the uplink subframe. A transmission packet transmitted from the communication terminal 2 is transmitted in bursts of uplink subframes.

(4) Response Control Unit (i) Response Control FIG. 4 is a diagram illustrating a signal flow in the response control unit 10. 5 and 6 are flowcharts of response control executed by the response control unit 10. 7 to 9 are response sequences of the communication terminal 2.

  2 and 4, the response control unit 10 includes a downlink error correction unit 56, a downlink HARQ (Hybrid Automatic Repeat Request) processing unit 58, a HARQ_SN determination unit 60, an ACKCH processing unit 62, and an uplink HARQ process. Part 64 and an uplink error correction part 66. FIG. 4 also shows the subcarrier allocation unit 40 of the transmission unit 8.

  Each block (downlink error correction unit 56 and the like) of the response control unit 10 has a logic circuit or a CPU. Further, some or all of the blocks have a memory (including a buffer). The same applies to each block in the second to third embodiments described later.

  5 and 6 show a flowchart of packet transmission by the base station (left side) and a flowchart of response control by the communication terminal 2 (right side). 7 to 9 show the response of the communication terminal 2 for each case.

-Case 1 (Fig. 7 (a))-
As shown in FIG. 7A, the base station first transmits a packet (received packet) 28 to the communication terminal 2.

  At that time, as shown in FIG. 5, the base station adds an error detection code (for example, a CRC (Cyclic Redundancy Check) code) to the packet transmitted to the communication terminal 2 (B2). Further, the base station encodes the packet to which the error detection code is added so that error correction can be performed (for example, turbo coding) (B2). The encoded packet 28 (downlink data # 0) is transmitted to the communication terminal 2 (B4). During this time, the communication terminal 2 continues to wait for packet reception (S2).

  As shown in FIG. 4, when the receiving unit 6 of the communication terminal 2 receives a packet (received packet) 28 transmitted from the base station, the receiving unit 28 demodulates the received packet 28 and sends it to the downlink correcting unit 56 of the response control unit 10. Supply.

  The downlink error correction unit 56 decodes (error correction) the demodulated received packet 28a and supplies it to the downlink HARQ processing unit 58 (S4).

  The downlink HARQ processing unit 58 performs error detection using the error detection code added to the decoded received packet 28b (S6). Based on the result of this error check, the downlink HARQ processing unit 58 determines whether or not the received packet 28 has been normally received (S8).

  For example, when no error is detected in the decoded received packet 28b, the downlink HARQ processing unit 58 determines that the received packet has been normally received. On the other hand, when an error is detected in the decoded received packet 28b, the downlink HARQ processing unit 58 determines that the received packet 28 has not been received normally.

  When it is determined that the received packet 28 has been normally received, the downlink HARQ processing unit 58 supplies an instruction 67 a for instructing generation of an acknowledgment code (ACK code) to the ACKCH processing unit 62. In response to this command 67a, the ACKCH processing unit 62 generates an ACK code 70 and supplies it to the sub-carrier allocation unit 40.

  Further, the downlink HARQ processing unit 58 extracts the HARQ identifier sequence number (HARQ Identifier Sequence Number; AI_SN) 69 and the HARQ channel identifier (HACID Channel Identifier; ACID) 71 from the HARQ information (data) transmitted from the base station. To do. The extracted HARQ identification sequence number and HARQ channel identification number are supplied to the HARQ_SN (HARQ sequence number) determination unit 60.

  The HARQ_SN determination unit 60 determines whether the received packet 28 is a received packet based on the HARQ identification sequence number 69 and the HARQ channel identification number 71 (S10). The determination procedure will be described later in “Case 4”.

  If the received packet 28 is not a received packet, the HARQ_SN determination unit 60 supplies a command 73 for transmitting the response code supplied from the ACKCH processing unit 62 with the set transmission power to the sub-carrier allocation unit 40. . The response code is an ACK code 70 and a NACK code 76 described later.

  In response to the instruction 73, the subcarrier allocation unit 40 allocates the ACK code 70 supplied from the ACKCH processing unit 62 to the ACHCH of the uplink subframe, modulates it with the encoded transmission packet 48, and performs frequency domain data 52 (Modulation).

  The modulated ACK code is converted into the ACK signal 72 by the inverse fast Fourier transformer 42 or the like, and then transmitted to the base station as shown in FIG. 7A (S12).

  Note that the ACK signal 72 may be transmitted together with the HARQ identification serial number (number after #) of the received packet 28 as shown in FIG. The same applies to a NACK signal described later.

  As shown in FIG. 5, after transmitting the packet (downlink data # 0) 28 to the communication terminal 2, the base station continues to wait for a response signal (B6). When the base station receives the response signal transmitted by the communication terminal 2 and determines that the response signal is the ACK signal 72, the base station ends the transmission processing of the packet (downlink data # 0) corresponding to the ACK signal 72 (B8 → B10). .

  Thereafter, as shown in FIG. 7A, the base station starts transmission of the next packet 74 (downlink data # 1) (B12). In response to this packet 74 (downlink data # 1), the response control unit 10 executes response control. When the packet 74 is normally received, an ACK signal 72a is sent as shown in FIG. Return it. Such a response is repeated, and a plurality of packets are transmitted from the base station to the communication terminal.

  By the way, the response signals (ACK signal and NACK signal) are transmitted with transmission power corresponding to the modulation strength (“amplitude” of the frequency domain data) set in the sub-carrier allocation unit 40. The modulation intensity of the response signal is constant in the cases of FIGS. 7A to 8A, but is changed in the case of FIG. 8B described later.

  The transmission power of the response signal before the change (hereinafter referred to as the initial value of the transmission power) is intermittently broadcast (broadcast) from the base station as a part of the control signal. The initial value of the transmission power is transmitted using the received packet. The data processing unit 12 sets the transmission power corresponding to the initial value of the transmission power in the sub-carrier allocation unit 40.

  In mobile WiMAX or the like, the initial value of the transmission power (of the response signal) is set lower than the transmission power of the transmission packet 48.

-Case 2 (Fig. 7 (b))-
When the downlink HARQ processing unit 58 detects an error in the decoded received packet 28b, it determines that the received packet 28 has not been normally received (S8). Then, as shown in FIG. 4, the downlink HARQ processing unit 58 supplies an instruction 67b that instructs the ACKCH processing unit 62 to generate a negative acknowledgment code (NACK code).

  Then, the ACKCH processing unit 62 generates a NACK code 76 and supplies it to the sub-carrier allocation unit 40 of the transmission unit 8. Similar to the ACK code 70, the NACK code 76 is assigned to the ACHCH and returned to the base station (S8 → S14). As a result, as shown in FIG. 7B, a NACK signal 78 is returned to the base station.

  When receiving the NACK signal 78, the base station restarts the packet transmission process and retransmits the packet 28c (downlink data # 0) (B6 → B8 → B2 → B4).

  After returning the NACK signal 78, the communication terminal 2 continues to wait for a retransmitted packet (S14 → S2). When receiving the retransmitted packet 28c, the communication terminal 2 resumes response control.

  When the retransmitted packet 28c is correctly received, the communication terminal 2 returns the ACK signal 72 to the base station (S8 → S10 → B → S16 → D → S12). When the base station receives the ACK signal 72, the transmission process of the packet 28 (downlink data # 0) to which the NACK signal 78 is returned ends (B6 → B8 → B10).

  When returning the ACK signal 72, the communication terminal 2 determines whether the retransmitted packet 28c is returned in response to the NACK signal (S16). This determination procedure will be described later in “Case 4”.

  By the way, when the received packet 28c is retransmitted in response to the NACK signal 78, the communication terminal 2 combines the retransmitted received packet 28c with the previously received received packet 28 after maximum ratio decoding and decodes it (chase). Synthesis).

  For this decoding process, for example, when an error is detected in the decoded received packet 28b, the downlink error correction unit 56 records the received packet 28a supplied from the demodulator 20 without discarding it. The downlink error correction unit 56 combines the received packet to be supplied next and the recorded received packet with a maximum ratio, and decodes the received packet.

-Case 3 (Fig. 8 (a))-
When the base station transmits packet 28 (downlink data # 0), the base station starts an ACK / NACK reception timer. As shown in FIG. 8A, when the response signal is not received even after the measurement time of the ACK / NACK reception timer exceeds a predetermined time 80 (timeout), the base station retransmits the packet 28 without a response ( B6 → A → B10).

  When the retransmitted packet 28d is normally received by the communication terminal 2, as shown in FIG. 8A, an ACK signal 72 is returned to the base station (S2-> S4-> S6-> S8-> S10-> S12). .

  The timeout of the reception waiting time occurs when the packet 28 does not reach the communication terminal 2 due to noise or deterioration of the communication environment (that is, when it is not detected) as shown in FIG.

-Case 4 (Fig. 8 (b))-
As shown in FIG. 8B, the reception waiting time-out also occurs when the ACK signal 72 returned by the communication terminal 2 does not reach the base station. Also in this case, the base station retransmits the packet 28 which is not responded and waits for reception of a response signal again (B6 → A → B10 → C → B6).

  The response control for the retransmitted packet 28d has a procedure common to the response control in cases 1 to 3. Therefore, a part common to the response control of cases 1 to 3 will be briefly described.

  When receiving the retransmitted packet 28d, the communication terminal 2 demodulates the retransmitted packet 28d in substantially the same procedure as in case 1 (S2 → S4 → S6). Thereafter, the communication terminal 2 determines whether or not the retransmitted packet 28d has been normally received (S8).

  The retransmitted packet 28d is normally received by the communication terminal 2 as in the case of the previously transmitted packet 28, unless there is a deterioration in radio wave environment or an increase in noise. In this case, the downlink HARQ processing unit 58 of the communication terminal 2 determines that the retransmitted packet 28d (received packet) has been normally received. The determination procedure is substantially the same as the procedure in Case 1.

  The downlink HARQ processing unit 58 is supplied with HARQ information (data) along with the decoded received packet 28b. The HARQ information is supplied from the demodulator 20 via the downlink error correction unit 56 (or directly).

  The downlink HARQ processing unit 58 extracts the HARQ identification sequence number (AI_SN) and the HARQ channel identification number (ACID) from the HARQ information of the received packet 28b. The extracted HARQ identification sequence number 69 and HARQ channel identification number 71 are supplied to the HARQ_SN (HARQ sequence number) determination unit 60.

  The HARQ channel identification number is an identifier of a channel through which a packet is transmitted. By referring to the HARQ channel identification number, it can be determined whether the packets are divided from the same data. The HARQ identification serial number is a number assigned to packets divided from the same data according to the transmission order. HARQ identification numbers are, for example, “0” and “1”. In this case, “0” and “1” are alternately attached to the packets in the order of transmission.

  By referring to the HARQ identification number and the HARQ identification serial number, it is possible to determine whether or not the received packet 28 (see FIG. 8B) is a received packet. For example, when received packets having the same HARQ channel identification number and the same HARQ identification sequence number are continuously received, the subsequent received packet is a received packet. On the other hand, when received packets having the same HARQ channel identification number and different HARQ identification sequence numbers are continuously received, the subsequent received packet is an unreceived packet (next packet).

  The HARQ information is assigned to the MAP (Map) region of the downlink subframe and transmitted from the base station to the communication terminal 2. MAP is radio resource allocation information and is a part of communication control information. The numbers after “#” shown in FIGS. 7 to 9 are examples of HARQ identification serial numbers.

  The HARQ_SN determination unit 60 determines whether the received packet 28 is a received packet based on the HARQ identification sequence number 69 and the HARQ channel identification number 71 (S10).

  In the case shown in FIG. 8B, the retransmitted packet 28d has already been received by the communication terminal 2. Therefore, the retransmitted packet 28d is determined as a received packet.

  The HARQ_SN determination unit 60 further determines whether or not the retransmitted packet 28d is a received packet that is normally received and an ACK signal is returned (hereinafter referred to as a packet that the ACK signal is returned) (B). → S16).

  In Case 4, the retransmitted packet 28d has no error. Accordingly, since no error is detected in the packet 28d, the downlink HARQ processing unit 58 supplies the ACKCH processing unit 62 with an instruction 67a instructing generation of the ACK code, as in the case 1 (see FIG. 4). In response to this command 67a, the ACKCH processing unit 62 generates an ACK code 70 and supplies it to the sub-carrier allocation unit 40.

  When generating the ACK code 70, the ACKCH processing unit 62 supplies the ACK code 70 not only to the subcarrier allocation unit 40 but also to the HARQ_SN determination unit 60. The HARQ_SN determination unit 60 records the supplied ACK code 70. Even in response control other than Case 4, the generated response codes (ACK code 70 and NACK code 76) are recorded in the HARQ_SN determination unit 60.

  If the HARQ_SN determination unit 60 determines that the retransmitted packet 28d is a received packet, the HARQ_SN determination unit 60 determines whether the retransmitted packet is a packet returned with an ACK signal based on the response code recorded at the time of the previous response. (S10 → S16).

  If the previously recorded response code is an ACK code, it is determined that the retransmitted packet 28d is a packet to which an ACK signal has been returned (YES in S16). If the previously recorded response code is a NACK code, it is determined that the retransmitted packet 28d is a packet to which a NACK signal is returned (NO in S16).

  In case 4 shown in FIG. 8B, the packet 28 transmitted first from the base station is normally received by the communication terminal 2 and an ACK signal 72 is returned. Therefore, in Case 4, the ACKCH processing unit 62 determines that the retransmitted packet (received packet) 28d is a packet to which an ACK signal is returned.

  Then, the HARQ_SN determination unit 60 supplies the subcarrier allocation unit 40 with an instruction 73a to change the transmission power setting value of the response code to a larger value. The subcarrier allocation unit 40 increases the set value of the transmission power according to the instruction 73a, and transmits the ACK code 70 with the increased transmission power. As a result, the transmission unit 10 retransmits the ACK signal with a second transmission power larger than the first transmission power (transmission power before increasing) (S18).

  As described above, when the received packet 28 is normally received and the ACK signal is returned with the first transmission power and the normally received received packet 28d is retransmitted, the response control unit 10 performs the first transmission. Control to retransmit the ACK signal 72 to the transmission unit 8 with the second transmission power larger than the power is performed.

  Since the transmission power increases, the retransmitted ACK signal 72b is likely to reach the base station. When the ACK signal 72b is normally received by the base station, the transmission process of the packet 28 ends (B6 → B8 → B10).

  FIG. 9 shows a case where the ACK signal (ACK # 0) 72c is retransmitted without increasing the transmission power. In this case, since the ACK signal 72c is retransmitted with a small transmission power, the ACK signal 72c retransmitted in the same manner as the ACK signal 72 returned first is difficult to reach the base station. For this reason, the return of the ACK signal is repeated, and the communication speed is reduced.

  For example, in mobile WiMAX, the response signal modulation method is QPSK, which is resistant to noise. However, the transmission power of the response signal is set smaller than the transmission power of the transmission packet 46. For this reason, even if the transmission packet 46 reaches the base station, the ACK signal may not reach the base station.

  In such a case, when the ACK signal is retransmitted without increasing the transmission power, the ACK signal 72 does not reach the base station, and the packet is repeatedly retransmitted from the base station. For this reason, the communication speed between the base station and the communication terminal is significantly reduced. Such a decrease in communication speed is likely to occur when the transmission power of the response signal is 5 dB or more lower than the transmission power of the transmission packet.

  Embodiment 1 is particularly useful in a communication system in which the transmission power of the response signal is set to be smaller than the transmission power of the transmission packet. Therefore, Embodiment 1 is preferably applied to a communication terminal in which the transmission power of a response signal (particularly, ACK signal 72) is smaller than the transmission power of transmission packet 46.

  In Embodiment 1, the transmission power of the ACK signal is increased when retransmitted. Therefore, the “transmission power of the response signal (particularly, ACK signal 72)” is precisely the transmission power of the ACK signal 72 transmitted first (hereinafter referred to as the initial value of the ACK transmission power). is there. That is, it is preferable that the ACK signal transmitted first is transmitted with transmission power smaller than the transmission power of the transmission packet 46.

  Specifically, the first embodiment is preferably applied to a communication terminal in which the initial value of the ACK transmission power is smaller than the transmission power of the transmission packet 46 by about 5 dB or more. However, if the initial value of the ACK transmission power is smaller than the transmission power of the transmission packet by about 9 dB or more, it becomes difficult to make the ACK signal reach the base station (with the initial value of the ACK transmission power). Therefore, the initial value of the ACK transmission power is preferably 5 dB or more and 9 dB or less smaller than the transmission power of the transmission packet 46.

  Note that when the ACK signal 72 is retransmitted only once, the initial value of the ACK transmission power becomes the first transmission power. Incidentally, in mobile WiMAX, the initial value of ACK transmission power is broadcast from the base station.

  As described above, the first embodiment is preferably applied to a communication terminal in which the initial value of the ACK transmission power is 5 to 9 dB lower than the transmission power of the transmission packet 46. Therefore, the power for retransmitting the ACK signal (second transmission power) is preferably 1 to 6 dB (predetermined magnification) larger than the transmission power before the retransmission (initial value of the ACK transmission power).

  If the power to retransmit the ACK signal is small, the ACK signal does not reach the base station. On the other hand, if the power to retransmit the ACK signal is too large, other communication terminals are likely to fail. For this reason, it is preferable that the power for retransmitting the ACK signal is about 1 to 6 dB larger than the transmission power before the retransmission.

(Ii) Encoding of transmission packet As shown in FIG. 4, when the transmission packet 46 is supplied from the UL memory, the uplink HARQ processing unit 64 adds an error detection code (for example, CRC code) to the transmission packet 46. . The transmission packet 46b to which the error detection code is added is supplied to the upstream error correction unit 66.

  The uplink error correction unit 66 encodes the transmission packet 46 b (for example, turbo encoding) and supplies the encoded transmission packet 46 b to the subcarrier allocation unit 40 of the transmission unit 8. The transmission unit 8 transmits the encoded transmission packet 46b.

(5) Modification 1
In the flowcharts shown in FIGS. 5 and 6, the ACK signal is retransmitted every time the normally received packet 28 is received again. However, if the ACK signal does not reach the base station due to a temporary deterioration of the radio wave environment, the ACK signal reaches the base station after a while without increasing the transmission power.

  Therefore, when the normally received packet 28 has been retransmitted continuously a predetermined number of times (≧ 2), the response control unit 10 sends the initial transmission power (first transmission power) to the transmission unit 8. The ACK signal may be returned with a larger transmission power (second transmission power).

  The response control unit 10 controls to retransmit the ACK signal to the transmission unit 8 with the first transmission power until the normally received packet 28 is retransmitted continuously for the predetermined number of times (≧ 2). (The transmission unit 8 is controlled so as to retransmit the ACK signal with the first transmission power). If the radio wave environment recovers during this time, the ACK signal reaches the base station. Therefore, it is not necessary to change the transmission power of the ACK signal sensitively.

(6) Modification 2
By the way, the modulation scheme of the transmission packet is determined for each frame by the base station and transmitted to the communication terminal 2 by the MAP of the downlink subframe. The data processing unit 12 of the communication terminal 2 sets the transmitted modulation scheme in the subcarrier allocation unit 40. The transmission power of the transmission packet is calculated by the data processing unit 12 for each modulation scheme and set in the subcarrier allocation unit 40. At this time, the data processing unit 12 calculates the transmission power of the transmission packet 46 based on the received signal strength indicator (RSSI) of the received signal.

  Thus, since the transmission packet 46 is transmitted with the power calculated based on RSSI, it is easy to reach the base station. Therefore, when the transmission packet 46 and the ACK signal (ACK code 76) have the same modulation method, transmitting the ACK signal with the transmission power of the transmission packet 46 makes it easier for the ACK signal to reach the base station.

  Therefore, the second transmission power (power to be retransmitted) of the ACK signal 72 is set to the transmission power of the transmission packet 46 that is modulated by the modulation method (for example, QPSK) of the ACK signal 72 and transmitted. This makes it easier for the ACK signal to reach the base station.

(Embodiment 2)
The communication terminal according to the second embodiment has a configuration common to the communication terminal 2 according to the first embodiment. Therefore, description of portions common to Embodiment 1 is omitted.

  FIG. 10 is a configuration diagram of the response control unit 10a according to the second embodiment. FIG. 10 also shows a part of a circuit connected to the response control unit 10a.

  As shown in FIG. 10, the communication terminal of the second embodiment includes an RSSI measurement unit 90 and an ACKCH transmission power adjustment unit 92a in addition to each block (downlink correction unit 56 and the like) of the first embodiment. Yes. The ACKCH transmission power adjustment unit 92a is a part of the response control unit 10a.

  The input unit of the RSSI measurement unit 90 is connected to a connection node between the ADC 16 and the FFT 18. On the other hand, the output unit of the RSSI measurement unit 90 is connected to the ACKCH transmission power adjustment unit 92a. The RSSI measurement unit 90 measures RSSI (Reception Signal Strength Indicator) based on the preamble signal included in the downlink subframe. The measured RSSI (RSSI measurement value) is supplied to the ACKCH transmission power adjustment unit 92a.

  The ACKCH transmission power adjustment unit 92 a is provided between the HARQ_SN determination unit 60 and the subcarrier allocation unit 40. The ACKCH transmission power adjustment unit 92a has a memory (not shown) in which an ACKCH transmission power adjustment table is recorded.

  If the HARQ_SN determination unit 60 determines that the packet that the received packet (reception packet) has responded with an ACK signal has been retransmitted (YES in S16), the HARQ_SN determination unit 60 supplies a transmission power adjustment signal to the ACKCH transmission power adjustment unit 92a.

  When the transmission power adjustment signal is supplied, the ACKCH transmission power adjustment unit 92a reads the increase amount of the transmission power (ACKCH transmission power) of the response signal corresponding to the RSSI measurement value from the ACKCH transmission power adjustment table, and assigns subcarriers. To the unit 40. The subcarrier allocation unit 40 increases the modulation strength of the response signal so that the response signal increases by the amount of increase in the supplied ACKCH transmission power.

  Table 1 is an example of an ACKCH transmission power adjustment table.

  In the first column, RSSI (X) of the received signal is recorded. In the second column, the amount of increase in ACKCH transmission power is recorded.

  For example, when the RSSI measurement value X is −90 dBm or less, the ACKCH transmission power adjustment unit 92 a reads the ACKCH transmission power increase amount 6 dB from the ACKCH transmission power adjustment table and supplies it to the subcarrier allocation unit 40. Then, the subcarrier allocation unit 40 increases the modulation strength of the response signal so that the transmission power of the response signal is increased by 6 dB.

  For example, when the transmission power (first transmission power) before the transmission power adjustment signal is supplied is 10 dBm, the ACKCH transmission power adjustment unit 92a has a response signal transmission power (second transmission power) of 16 dBm (= The modulation intensity of the response signal is increased so as to be 10 dBm + 6 dB).

  Specifically, the subcarrier allocation unit 40 increases the set value of the modulation strength, and modulates the response code (ACK code and NACK code) supplied from the ACKCH processing unit 62 with the increased modulation degree. As a result, the transmission power of the response signal increases. The same applies to the following modified example and the third embodiment.

  As the measured value X of RSSI in Table 1, for example, the measured value when the transmission power adjustment signal is supplied (the value measured first after the transmission power adjustment signal is supplied, or the transmission power adjustment signal is supplied). Use the last measured value). The same applies to the measured values X in Tables 2 and 3 described later.

  In the ACKCH transmission power adjustment table, an optimum value of the ACKCH transmission power increase amount obtained through experiments is recorded. Therefore, according to the second embodiment, the retransmitted ACK signal can easily reach the base station.

(Modification)
FIG. 11 is a configuration diagram illustrating a modification of the communication terminal according to the second embodiment.

  As shown in FIG. 11, the communication terminal according to the modification includes a CINR measurement unit 94 instead of the RSSI measurement unit 90. The input unit of the CINR measurement unit 94 is connected to a connection node between the FFT 18 and the demodulator 20. The output unit of the CINR measurement unit 94 is connected to the ACKCH transmission power adjustment unit 92b.

  The CINR measurement unit 94 measures CINR (carrier (carrier wave) to interference noise ratio) based on the preamble signal included in the downlink subframe. The measured CINR is supplied to the ACKCH transmission power adjustment unit 92b.

  Instead of Table 1, for example, the ACKCH transmission power adjustment table in Table 2 is recorded in the memory of the ACKCH transmission power adjustment unit 92b.

  In the first row of Table 2, CINR (X) of the received signal is recorded instead of RSSI. In the second row, the increase amount of the transmission power of the response signal is recorded.

  When the transmission power adjustment signal is supplied to the ACKCH transmission power adjustment unit 92b, an increase amount (for example, 6 dB) of transmission power (ACKCH transmission power) corresponding to the measured value of CINR (for example, 0 dB) from the ACKCH transmission power adjustment table. Is supplied to the subcarrier allocation unit 40. The subcarrier allocation unit 40 increases the modulation strength of the response signal so that the increase amount (for example, 6 dB) of the supplied ACKCH transmission power increases.

  As described above, the communication terminal according to Embodiment 2 changes the second transmission power (increased transmission power) of the response signal according to the characteristics (RSSI, CINR, etc.) of the downlink signal transmitted from the base station. The predetermined magnification is set to be larger than the first transmission power of the response signal (transmission power before increasing).

(Embodiment 3)
The communication terminal according to the second embodiment has a configuration common to the communication terminal 2 according to the second embodiment. Therefore, description of portions common to Embodiment 2 is omitted.

  FIG. 12 is a configuration diagram of the response control unit 10c according to the third embodiment. FIG. 12 also shows a part of a circuit connected to the response control unit 10c.

  As shown in FIG. 12, the communication terminal of the third embodiment has an RSSI / CINR measurement unit 96 instead of the RSSI measurement unit 90. Furthermore, the communication terminal of Embodiment 3 has an adjustment value correction unit 98.

  The first input unit of the RSSI / CINR measurement unit 96 is connected to a connection node between the ADC 16 and the FFT 18. The second input unit of the RSSI / CINR measurement unit 96 is connected to a connection node between the FTT 18 and the demodulator 20.

  The first output unit of the RSSI / CINR measurement unit 96 is connected to the ACKCH transmission power adjustment unit 92c. The second output unit of the RSSI / CINR measurement unit 96 is connected to the adjustment value correction unit 98.

  The RSSI / CINR measurement unit 96 measures the RSSI and CINR of the received signal and supplies the measured values to the ACKCH transmission power adjustment unit 92c. Further, the RSSI / CINR measurement unit 96 calculates the measured RSSI and CINR change amounts and supplies them to the adjustment unit 98.

  When the transmission power adjustment signal is supplied from the HARQ_SN determination unit 60, the ACKCH transmission power adjustment unit 92c reads the increase amount of the transmission power (ACKCH transmission power) from the ACKCH transmission power adjustment table and supplies it to the subcarrier allocation unit 40. To do. The subcarrier allocation unit 40 increases the modulation strength of the response signal so that the response signal increases by the amount of increase in the supplied ACKCH transmission power.

  Table 3 is an example of an ACKCH transmission power adjustment table.

  In the first column, the sum (X) of RSSI and CINR of the received signal is recorded. In the second column, the amount of increase in ACKCH transmission power is recorded.

  For example, when the sum X of the RSSI measurement and the CINR measurement value is greater than −90 dBm and less than or equal to −70 dBm, the ACKCH transmission power adjustment unit 92c reads the ACKCH transmission power adjustment amount from the ACKCH transmission power adjustment table and increases the subcarrier allocation by 5 dB. To the unit 40.

  The increase amount (for example, 5 dB) of the ACK transmission power is supplied to the subcarrier allocation unit 40 via the adjustment value correction unit 98. The subcarrier allocation unit 40 increases the modulation strength of the response signal so that the response signal increases (for example, 5 dB) by increasing the ACKCH transmission power. At this time, the adjustment value correction unit 98 records the increase amount of the ACKCH transmission power in a memory (not shown).

  The transmission power adjustment signal generated by the HARQ_SN determination unit 60 is also supplied to the RSSI / CINR measurement unit 96 via a signal line (not shown). The RSSI / CINR measurement unit 96 records RSSI and CINR measurement values in a memory (not shown) in response to the transmission power adjustment signal.

  In Embodiments 1 and 2, even after the retransmitted ACK signal arrives at the base station, the transmission power of the response signal does not return (see the flowcharts in FIGS. 5 and 6). Therefore, even if the radio wave environment is improved, the transmission power of the response signal remains high. If the transmission power of the response signal remains high, communication failure may occur in other communication terminals.

  Therefore, the response control unit 10c responds to the improvement in the characteristics of the downlink signal (RSSI and CINR) when the characteristics of the downlink signal are improved after the transmitter 8 retransmits the ACK signal with the second transmission power. Thus, the transmission power of the ACK signal is reduced.

  FIG. 13 is an explanatory diagram of the correction process performed by the adjustment value correction unit 98. The RSSI / CINR measurement unit 96 records the RSSI measurement value and the CINR measurement value when the transmission power adjustment signal is supplied as described above.

  The RSSI / CINR measurement unit 96 calculates an RSSI change amount (= measurement value−reference value) using the recorded RSSI as a reference value. The calculated RSSI change amount is supplied to the adjustment value correction unit 98. Similarly, the RSSI / CINR measurement unit 96 calculates the CINR change amount based on the recorded CINR change amount. The calculated change amount of CINR is supplied to the adjustment value correction unit 98.

  As illustrated in FIG. 13, the adjustment value correction unit 98 calculates an average value 104 of the supplied RSSI change amount 100 and CINR change amount 102. The adjustment value correcting unit 98 corrects the increase amount of the ACKCH transmission power by subtracting the average value 104 from the recorded increase amount 106 of the ACKCH transmission power. The corrected increase amount (hereinafter referred to as a correction value) 108 is supplied to the subcarrier allocation unit 40.

  The subcarrier allocation unit 40 changes the modulation strength of the response signal so that the ACKCH transmission power increases from the initial value (ACKCH transmission power before increasing) by the correction value. For example, when the average value of the RSSI change amount and the CINR change amount is improved by 1 dB, the modulation intensity of the response signal is corrected so that the ACKCH transmission power is reduced by 1 dB.

  Thus, in Embodiment 3, when the radio wave environment is improved, the increased transmission power is reduced again. For this reason, it becomes difficult for the communication failure of another communication terminal to occur.

  In the example shown in FIG. 13, the ACKCH transmission power is corrected based on the average value of the RSSI change amount and the CINR change amount. However, the ACKCH transmission power may be corrected based only on the RSSI change amount or the CINR change amount.

  The communication system in the first to third embodiments is mobile WiMAX. However, Embodiments 1 to 3 may be applied to other communication methods. For example, the first to third embodiments may be applied to other communication methods such as fixed WiMAX, WiFi (IEEE802.11), and LTE (Long Term Evolution).

  As described above, the retransmission requests in the first to third embodiments are HARQ. However, the retransmission request may be another method such as ARQ.

  Incidentally, in ARQ, error detection is performed on a demodulated received packet, and if no error is detected, it is determined that the received packet has been normally received and an ACK signal is returned. If an error is detected in the demodulated received packet, it is determined that the received packet has not been normally received, and a NACK signal is returned.

  In the first to third embodiments, the transmission power (and modulation strength) of the ACK signal and the NACK signal are the same. However, the transmission power (and modulation strength) of the ACK signal and the NACK signal may be different. For example, when a packet responding with an ACK signal is retransmitted, only the transmission power of the ACK signal may be increased. Even if the transmission power of the NACK signal is not increased, if the packet retransmitted from the base station is normally received, the NACK signal is not repeatedly transmitted over and over again.

  Regarding the above first to third embodiments, the following additional notes are disclosed.

(Appendix 1)
A transmitter for transmitting a response signal to the base station;
A reception unit for receiving a reception signal from the base station;
A response control unit that controls the transmission unit to transmit an acknowledgment signal to the base station when the reception signal is normally received;
When the received signal is normally received after the received signal is normally received and the acknowledgment signal is transmitted with the first transmission power, the response control unit is configured to transmit the first transmission power. A communication terminal that controls to retransmit the acknowledgment signal with a larger second transmission power.

(Appendix 2)
In the communication terminal described in Appendix 1,
The response control unit controls the transmission unit to transmit a negative acknowledgment signal when the reception signal is not normally received.

(Appendix 3)
In the communication terminal according to appendix 1 or 2,
The communication terminal characterized in that the acknowledgment signal transmitted first is transmitted with transmission power smaller than the transmission power of a transmission packet.

(Appendix 4)
In the communication terminal according to any one of appendices 1 to 3,
The response control unit controls to transmit the acknowledgment signal with the second transmission power when the normally received signal is retransmitted continuously twice or more. Terminal.

(Appendix 5)
In the communication terminal according to any one of appendices 1 to 4,
The communication terminal characterized in that the second transmission power is larger than the first transmission power by a predetermined factor.

(Appendix 6)
In the communication terminal according to appendices 1 to 4,
The communication terminal, wherein the second transmission power is a transmission power of a transmission packet that is modulated by the modulation method of the acknowledgment signal and transmitted.

(Appendix 7)
In the communication terminal according to any one of appendices 1 to 4,
The communication terminal, wherein the second transmission power is larger than the first transmission power by a predetermined magnification according to characteristics of a downlink signal transmitted from the base station.

(Appendix 8)
In the communication terminal described in Appendix 7,
The response control unit
The communication terminal, wherein when the characteristic of the downlink signal is improved after the acknowledgment signal is retransmitted with the second transmission power, the transmission power of the acknowledgment signal is reduced.

(Appendix 9)
A retransmission control method in a communication terminal,
If the received signal from the base station is successfully received, send an acknowledgment signal to the base station;
A second transmission greater than the first transmission power when the received signal is successfully retransmitted after the reception signal is successfully received and the acknowledgment signal is transmitted with the first transmission power; A retransmission control method for retransmitting the acknowledgment signal with power.

2 ... Communication terminal 6 ... Reception unit 8 ... Transmission unit 10 ... Response control unit 12 ... Data processing unit 67, 73 ... Command 28 ... Received packet 69 ... HARQ Identification sequence number 71 ... HARQ channel identification number

Claims (6)

A transmitter for transmitting a response signal to the base station;
A reception unit for receiving a reception signal from the base station;
A response control unit that controls the transmission unit to transmit an acknowledgment signal to the base station when the reception signal is normally received;
When the received signal is normally received after the received signal is normally received and the acknowledgment signal is transmitted with the first transmission power, the response control unit is configured to transmit the first transmission power. A communication terminal that controls to retransmit the acknowledgment signal with a larger second transmission power. The communication terminal according to claim 1,
The communication terminal characterized in that the acknowledgment signal transmitted first is transmitted with transmission power smaller than the transmission power of a transmission packet. In the communication terminal according to claim 1 or 2,
The communication terminal, wherein the second transmission power is a transmission power of the response signal that is modulated by the modulation method of the acknowledgment signal and transmitted. In the communication terminal according to claim 1 or 2,
The communication terminal, wherein the second transmission power is larger than the first transmission power by a predetermined magnification according to characteristics of a downlink signal transmitted from the base station. The communication terminal according to claim 4,
The response control unit
The communication terminal, wherein when the characteristic of the downlink signal is improved after the acknowledgment signal is retransmitted with the second transmission power, the transmission power of the acknowledgment signal is reduced. A retransmission control method in a communication terminal,
If the received signal from the base station is successfully received, send an acknowledgment signal to the base station;
A second transmission greater than the first transmission power when the received signal is successfully retransmitted after the reception signal is successfully received and the acknowledgment signal is transmitted with the first transmission power; A retransmission control method for retransmitting the acknowledgment signal with power.

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