VIRTUAL RESOURCE BLOCK TO PHYSICAL RESOURCE BLOCK MAPPING IN DUPLEX SLOTS

DETAILED ACTION Notice of Pre-AIA or AIA Status The present application, filed on or after March 16, 2013, is being examined under the first inventor to file provisions of the AIA . Continued Examination Under 37 CFR 1.114 A request for continued examination under 37 CFR 1.114, including the fee set forth in 37 CFR 1.17(e), was filed in this application after final rejection. Since this application is eligible for continued examination under 37 CFR 1.114, and the fee set forth in 37 CFR 1.17(e) has been timely paid, the finality of the previous Office action has been withdrawn pursuant to 37 CFR 1.114. Applicant's submission filed on 04/06/2026 has been entered. Response to Arguments Applicant’s arguments with respect to claim(s) 1-4, 6-12, 15-19, 21-26 and 28-30 have been considered but are moot based on new grounds of rejections. Claim Rejections - 35 USC § 103 The following is a quotation of 35 U.S.C. 103 which forms the basis for all obviousness rejections set forth in this Office action: A patent for a claimed invention may not be obtained, notwithstanding that the claimed invention is not identically disclosed as set forth in section 102, if the differences between the claimed invention and the prior art are such that the claimed invention as a whole would have been obvious before the effective filing date of the claimed invention to a person having ordinary skill in the art to which the claimed invention pertains. Patentability shall not be negated by the manner in which the invention was made. This application currently names joint inventors. In considering patentability of the claims the examiner presumes that the subject matter of the various claims was commonly owned as of the effective filing date of the claimed invention(s) absent any evidence to the contrary. Applicant is advised of the obligation under 37 CFR 1.56 to point out the inventor and effective filing dates of each claim that was not commonly owned as of the effective filing date of the later invention in order for the examiner to consider the applicability of 35 U.S.C. 102(b)(2)(C) for any potential 35 U.S.C. 102(a)(2) prior art against the later invention. Claim(s) 1-4, 7-10, 16-19, 21-24 and 29-30 rejected under 35 U.S.C. 103 as being unpatentable over Su et al. (US 2023/0102171; hereinafter Su) in view of Kim et al. (US 2022/0046606; hereinafter Kim). Regarding claim 1, Su shows a method (Figures 24-25 shows a method performed in part by a UE.) for wireless communication at a user equipment (UE), comprising: receiving, from a network device, scheduling information for an uplink transmission and a downlink transmission (Figures 24-25; Par. 0376, 0385, 0393, 0405; the UE obtains the physical resource configuration of the physical downlink shared channel, and determines whether there is or may be a full-duplex (i.e. downlink and uplink) transmission on the obtained physical resources of the physical downlink shared channel.); determining that a slot is configured for full duplex communications with the network device based at least in part on the scheduling information (Figures 24-25; Par. 0376, 0393, 0405; it is determined that there is or may be a full-duplex transmission on the obtained physical resources of the physical shared channel in the first transmission direction according to at least the obtained time domain resources of the physical shared channel in the first transmission direction being located in a subframe/OFDM symbol/time slot in which a full duplex transmission is enabled; sist at least in the time domain resources of the physical downlink shared channel obtained by the UE are located in the subframe/OFDM symbol/time slot in which the full duplex transmission is enabled.); and communicating with the network device in the slot based at least in part on an interleaving configuration (Figures 24-25; Par. 0336; the UE performs transmission according to the obtained at least one of the transmission resource configuration for uplink and/or downlink transmission waveform, the transmission resource configuration for uplink and/or downlink resource allocation type, the transmission resource configuration for uplink and/or downlink transmission and mapping method.) wherein the interleaving configuration is based at least in part on the scheduling information (Figure 25; Par. 0331-0335, 0360-0362, 0405, 0475; the UE obtains, from the scheduling grant, whether to enable the indicated transmission and mapping method (i.e. interleaved mapping).) and determining that the slot is configured for full duplex communications (Figures 24-25; Par. 0331-0335, 0376, 0405; it is determined that there is or may be a full-duplex transmission on the obtained physical resources of the physical shared channel in the first transmission direction.). Su shows all of the elements as discussed above. Su does not specifically show wherein the interleaving configuration is selected from a plurality of interleaving configurations based at least in part on a downlink resource bandwidth for downlink transmission. However, the above-mentioned claim limitations are well-established in the art as evidenced by Kim. Specifically, Kim shows wherein the wherein the interleaving configuration is selected from a plurality of interleaving configurations based at least in part on a downlink resource bandwidth for downlink transmission (Figures 5 and 8; Par. 0068, 0084-0089; UE selects a particular interleaver from a plurality of interleavers based on a DL BWP configured by the gNB.). In view of the above, having the system of Su, then given the well-established teaching of Kim, it would have been obvious before the effective filing date of the claimed invention to modify the system of Su as taught by Kim, in order to provide motivation for efficiently providing hybrid broadcast using both a broadcast network and an IP network (Par. 0005 of Kim). Regarding claim 2, modified Su shows determining a downlink bandwidth part and a downlink resource bandwidth for the downlink transmission based at least in part on the scheduling information, wherein the interleaving configuration is selected based at least in part on the downlink bandwidth part and the downlink resource bandwidth (Kim: Figures 5 and 8; Par. 0068, 0084-0089; UE selects a particular interleaver from a plurality of interleavers based on a DL BWP configured by the gNB.). Regarding claim 3, modified Su shows selecting the interleaving configuration based at least in part on a location of the downlink bandwidth part and the downlink resource bandwidth within a set of bands configured for downlink communications (Su: Par. 0361; the UE obtains an indication about the transmission and mapping method in the full-duplex transmission configuration parameter, which may be a 1-bit indication field (distributed mapping, frequency hopping transmission), and the full-duplex transmission configuration parameter may be a high-level configuration parameter for a bandwidth part allowed for the full-duplex transmission, or a configured bandwidth allowed for the full-duplex transmission, or a system bandwidth allowed for the full-duplex transmission. Further, the UE obtains, from the scheduling grant, whether to enable the indicated transmission and mapping method. For example, if the transmission and mapping method of the uplink physical channel and the downlink physical channel transmitted on the full duplex bandwidth part that is firstly obtained by the UE according to the full duplex configuration parameter is the interleaved mapping, the UE then obtains the indication of whether to enable the interleaved mapping or not according to the downlink control information, so as to perform the uplink and/or downlink physical channel transmission.). Regarding claim 4, modified Su shows wherein selecting the interleaving configuration comprises: determining an uplink bandwidth part and an uplink resource bandwidth for the uplink transmission based at least in part on the scheduling information (Su: Figure 25; Par. 0381-0386; it is determined that there is a full-duplex transmission on the obtained physical resources of the physical shared channel in the first transmission direction according to at least one of following criteria: an obtained transmission subframe of the physical shared channel in the first transmission direction being a subframe in a second transmission direction, wherein the first transmission direction is different from the second transmission direction; for example, the first transmission direction is uplink, and the second transmission direction is downlink; or the first transmission direction is downlink, and the second transmission direction is uplink; an obtained transmission bandwidth of the physical shared channel in the first transmission direction being a bandwidth in the second transmission direction; obtained frequency domain resources of the physical shared channel in the first transmission direction being located in a bandwidth part/configured bandwidth/system bandwidth in which the full duplex transmission is enabled.); and selecting the interleaving configuration based at least in part on a location of the downlink bandwidth part relative to the uplink bandwidth part in a frequency domain or a location of the downlink resource bandwidth relative to the uplink resource bandwidth in the frequency domain (Su: Figure 25; Par. 0381-0386; it is determined that there is a full-duplex transmission on the obtained physical resources of the physical shared channel in the first transmission direction according to at least one of following criteria: an obtained transmission subframe of the physical shared channel in the first transmission direction being a subframe in a second transmission direction, wherein the first transmission direction is different from the second transmission direction; for example, the first transmission direction is uplink, and the second transmission direction is downlink; or the first transmission direction is downlink, and the second transmission direction is uplink; an obtained transmission bandwidth of the physical shared channel in the first transmission direction being a bandwidth in the second transmission direction; obtained frequency domain resources of the physical shared channel in the first transmission direction being located in a bandwidth part/configured bandwidth/system bandwidth in which the full duplex transmission is enabled.). Regarding claim 7, modified Su shows determining multiple downlink bandwidth parts for the downlink transmission based at least in part on the scheduling information; and selecting the interleaving configuration based at least in part on respective locations of the multiple downlink bandwidth parts within a set of bands configured for downlink communications (Su: Figure 25; Par. 0381-0386; it is determined that there is a full-duplex transmission on the obtained physical resources of the physical shared channel in the first transmission direction according to at least one of following criteria: an obtained transmission subframe of the physical shared channel in the first transmission direction being a subframe in a second transmission direction, wherein the first transmission direction is different from the second transmission direction; for example, the first transmission direction is uplink, and the second transmission direction is downlink; or the first transmission direction is downlink, and the second transmission direction is uplink; an obtained transmission bandwidth of the physical shared channel in the first transmission direction being a bandwidth in the second transmission direction; obtained frequency domain resources of the physical shared channel in the first transmission direction being located in a bandwidth part/configured bandwidth/system bandwidth in which the full duplex transmission is enabled.). Regarding claim 8, modified Su shows selecting a full duplex interleaving configuration based at least in part on the respective locations being positioned on both sides of an uplink bandwidth part for the uplink transmission in a frequency domain (Su: Figure 25; Par. 0381-0386; it is determined that there is a full-duplex transmission on the obtained physical resources of the physical shared channel in the first transmission direction according to at least one of following criteria: an obtained transmission subframe of the physical shared channel in the first transmission direction being a subframe in a second transmission direction, wherein the first transmission direction is different from the second transmission direction; for example, the first transmission direction is uplink, and the second transmission direction is downlink; or the first transmission direction is downlink, and the second transmission direction is uplink; an obtained transmission bandwidth of the physical shared channel in the first transmission direction being a bandwidth in the second transmission direction; obtained frequency domain resources of the physical shared channel in the first transmission direction being located in a bandwidth part/configured bandwidth/system bandwidth in which the full duplex transmission is enabled.). Regarding claim 9, modified Su shows selecting a full duplex interleaving configuration based at least in part on determining that the slot is configured for full duplex communications (Su: Figure 25; Par. 0381-0386; it is determined that there is a full-duplex transmission on the obtained physical resources of the physical shared channel in the first transmission direction according to at least on obtained time domain resources of the physical shared channel in the first transmission direction being located in a subframe/OFDM symbol/time slot in which a full duplex transmission is enabled.). Regarding claim 10, modified Su shows receiving an indication of the interleaving configuration, wherein selecting the interleaving configuration is based at least in part on the indication and the indication is a one bit indicator within downlink control information (Su: Par. 0347-048, 0381-0386; 1 bit is used for indicating that there is the full-duplex transmission of the uplink and downlink physical channels on the physical resources scheduled by the scheduling grant.). Regarding claim 16, Su shows a method (Figures 30-31 shows a method performed in part by a base station.) for wireless communications at a network device, comprising: determining that a slot is configured for full duplex communications with a user equipment (UE) based at least in part on an uplink transmission and a downlink transmission for the UE (Figures 30-31; Par. 0441, 0462-0467; the base station allocates, to the UE or the UE group, physical resources of a physical shared channel in the first transmission direction, invalid physical resources in allocated physical resources for uplink and/or downlink transmission, on which no transmission is to be performed, and a full-duplex transmission. The scheduling grant indicates the location of the second physical resources by notifying a relative location with reference to a start or end location of physical resources in time domain (i.e. time slot) and/or frequency domain of the physical downlink shared channel.); and communicating the uplink transmission and the downlink transmission with the UE based at least in part on an interleaving configuration (Figures 30-31; Par. 0425; the base station transmits at least one of the configured transmission resources to the UE or the UE group.) wherein the interleaving configuration is based at least in part on determining that the slot is configured for full duplex communications (Figures 24-25; Par. 0331-0335, 0376, 0405; it is determined that there is or may be a full-duplex transmission on the obtained physical resources of the physical shared channel in the first transmission direction.). Su shows all of the elements as discussed above. Su does not specifically show wherein the interleaving configuration is selected from a plurality of interleaving configurations based at least in part on a downlink resource bandwidth for downlink transmission. However, the above-mentioned claim limitations are well-established in the art as evidenced by Kim. Specifically, Kim shows wherein the wherein the interleaving configuration is selected from a plurality of interleaving configurations based at least in part on a downlink resource bandwidth for downlink transmission (Figures 5 and 8; Par. 0068, 0084-0089; UE selects a particular interleaver from a plurality of interleavers based on a DL BWP configured by the gNB.). In view of the above, having the system of Su, then given the well-established teaching of Kim, it would have been obvious before the effective filing date of the claimed invention to modify the system of Su as taught by Kim, in order to provide motivation for efficiently providing hybrid broadcast using both a broadcast network and an IP network (Par. 0005 of Kim). Regarding claim 17, modified Su shows determining a downlink bandwidth part and a downlink resource bandwidth for the downlink transmission, wherein the interleaving configuration is selected based at least in part on the downlink bandwidth part and the downlink resource bandwidth (Kim: Figures 5 and 8; Par. 0068, 0084-0089; UE selects a particular interleaver from a plurality of interleavers based on a DL BWP configured by the gNB.). Regarding claim 18, modified Su shows selecting the interleaving configuration based at least in part on a location of the downlink bandwidth part or the downlink resource bandwidth within a set of bands configured for downlink communications (Su: Par. 0361; the base station configures and transmits an indication about the transmission and mapping method in the full-duplex transmission configuration parameter, which may be a 1-bit indication field (distributed mapping, frequency hopping transmission), and the full-duplex transmission configuration parameter may be a high-level configuration parameter for a bandwidth part allowed for the full-duplex transmission, or a configured bandwidth allowed for the full-duplex transmission, or a system bandwidth allowed for the full-duplex transmission. Further, the UE obtains, from the scheduling grant configured by the base station, whether to enable the indicated transmission and mapping method. For example, if the transmission and mapping method of the uplink physical channel and the downlink physical channel transmitted on the full duplex bandwidth part that is firstly obtained by the UE according to the full duplex configuration parameter is the interleaved mapping, the UE then obtains the indication of whether to enable the interleaved mapping or not according to the downlink control information, so as to perform the uplink and/or downlink physical channel transmission.). Regarding claim 19, modified Su shows determining an uplink bandwidth part and an uplink resource bandwidth for the uplink transmission (Su: Figure 25; Par. 0381-0386; it is determined that there is a full-duplex transmission on the obtained physical resources of the physical shared channel in the first transmission direction according to at least one of following criteria: an obtained transmission subframe of the physical shared channel in the first transmission direction being a subframe in a second transmission direction, wherein the first transmission direction is different from the second transmission direction; for example, the first transmission direction is uplink, and the second transmission direction is downlink; or the first transmission direction is downlink, and the second transmission direction is uplink; an obtained transmission bandwidth of the physical shared channel in the first transmission direction being a bandwidth in the second transmission direction; obtained frequency domain resources of the physical shared channel in the first transmission direction being located in a bandwidth part/configured bandwidth/system bandwidth in which the full duplex transmission is enabled.); and selecting the interleaving configuration based at least in part on a location of the downlink bandwidth part relative to the uplink bandwidth part in a frequency domain or a location of the downlink resource bandwidth relative to the uplink resource bandwidth in the frequency domain (Su: Figure 25; Par. 0381-0386; it is determined that there is a full-duplex transmission on the obtained physical resources of the physical shared channel in the first transmission direction according to at least one of following criteria: an obtained transmission subframe of the physical shared channel in the first transmission direction being a subframe in a second transmission direction, wherein the first transmission direction is different from the second transmission direction; for example, the first transmission direction is uplink, and the second transmission direction is downlink; or the first transmission direction is downlink, and the second transmission direction is uplink; an obtained transmission bandwidth of the physical shared channel in the first transmission direction being a bandwidth in the second transmission direction; obtained frequency domain resources of the physical shared channel in the first transmission direction being located in a bandwidth part/configured bandwidth/system bandwidth in which the full duplex transmission is enabled.). Regarding claim 21, modified Su shows determining multiple downlink bandwidth parts for the downlink transmission; and selecting the interleaving configuration based at least in part on respective locations of the multiple downlink bandwidth parts within a set of bands configured for downlink communications (Su: Figure 25; Par. 0381-0386; it is determined that there is a full-duplex transmission on the obtained physical resources of the physical shared channel in the first transmission direction according to at least one of following criteria: an obtained transmission subframe of the physical shared channel in the first transmission direction being a subframe in a second transmission direction, wherein the first transmission direction is different from the second transmission direction; for example, the first transmission direction is uplink, and the second transmission direction is downlink; or the first transmission direction is downlink, and the second transmission direction is uplink; an obtained transmission bandwidth of the physical shared channel in the first transmission direction being a bandwidth in the second transmission direction; obtained frequency domain resources of the physical shared channel in the first transmission direction being located in a bandwidth part/configured bandwidth/system bandwidth in which the full duplex transmission is enabled.). Regarding claim 22, modified Su shows selecting a full duplex interleaving configuration based at least in part on the respective locations being positioned on both sides of an uplink bandwidth part for the uplink transmission in a frequency domain (Su: Figure 25; Par. 0381-0386; it is determined that there is a full-duplex transmission on the obtained physical resources of the physical shared channel in the first transmission direction according to at least one of following criteria: an obtained transmission subframe of the physical shared channel in the first transmission direction being a subframe in a second transmission direction, wherein the first transmission direction is different from the second transmission direction; for example, the first transmission direction is uplink, and the second transmission direction is downlink; or the first transmission direction is downlink, and the second transmission direction is uplink; an obtained transmission bandwidth of the physical shared channel in the first transmission direction being a bandwidth in the second transmission direction; obtained frequency domain resources of the physical shared channel in the first transmission direction being located in a bandwidth part/configured bandwidth/system bandwidth in which the full duplex transmission is enabled.). Regarding claim 23, modified Su shows selecting a full duplex interleaving configuration based at least in part on determining that the slot is configured for full duplex communications (Su: Figure 25; Par. 0381-0386; it is determined that there is a full-duplex transmission on the obtained physical resources of the physical shared channel in the first transmission direction according to at least on obtained time domain resources of the physical shared channel in the first transmission direction being located in a subframe/OFDM symbol/time slot in which a full duplex transmission is enabled.). Regarding claim 24, modified Su shows transmitting, to the UE, scheduling information for the uplink transmission and the downlink transmission, wherein the scheduling information comprises a one bit indicator within downlink control information that indicates the interleaving configuration (Su: Par. 0347-048, 0381-0386; 1 bit is used for indicating that there is the full-duplex transmission of the uplink and downlink physical channels on the physical resources scheduled by the scheduling grant.). Regarding claim 29, Su shows an apparatus for wireless communication at a user equipment (UE) (Figure 67 shows device implemented as a UE.), comprising: one or more processors, one or more memories coupled with the one or more processors; and instructions stored in the one or more memories and executable by the one or more processors to cause the apparatus (Figure 67 shows UE including software stored in memory and executed by one or more processors to perform the disclosed method.) to: receive, from a network device, scheduling information for an uplink transmission and a downlink transmission (Figures 24-25; Par. 0376, 0385, 0405; the UE obtains the physical resource configuration of the physical downlink shared channel, and determines whether there is or may be a full-duplex (i.e. downlink and uplink) transmission on the obtained physical resources of the physical downlink shared channel.); determine that a slot is configured for full duplex communications with the network device based at least in part on the scheduling information (Figures 24-25; Par. 0376, 0405; it is determined that there is or may be a full-duplex transmission on the obtained physical resources of the physical shared channel in the first transmission direction according to at least the obtained time domain resources of the physical shared channel in the first transmission direction being located in a subframe/OFDM symbol/time slot in which a full duplex transmission is enabled; the time domain resources of the physical downlink shared channel obtained by the UE are located in the subframe/OFDM symbol/time slot in which the full duplex transmission is enabled.); and communicate with the network device in the slot based at least in part on an interleaving configuration (Figures 24-25; Par. 0336; the UE performs transmission according to the obtained at least one of the transmission resource configuration for uplink and/or downlink transmission waveform, the transmission resource configuration for uplink and/or downlink resource allocation type, the transmission resource configuration for uplink and/or downlink transmission and mapping method.) wherein the interleaving configuration is based at least in part on the scheduling information (Figure 25; Par. 0331-0335, 0360-0362, 0405, 0475; the UE obtains, from the scheduling grant, whether to enable the indicated transmission and mapping method (i.e. interleaved mapping).) and determining that the slot is configured for full duplex communications (Figures 24-25; Par. 0331-0335, 0376, 0405; it is determined that there is or may be a full-duplex transmission on the obtained physical resources of the physical shared channel in the first transmission direction.). Su shows all of the elements as discussed above. Su does not specifically show wherein the interleaving configuration is selected from a plurality of interleaving configurations based at least in part on a downlink resource bandwidth for downlink transmission. However, the above-mentioned claim limitations are well-established in the art as evidenced by Kim. Specifically, Kim shows wherein the wherein the interleaving configuration is selected from a plurality of interleaving configurations based at least in part on a downlink resource bandwidth for downlink transmission (Figures 5 and 8; Par. 0068, 0084-0089; UE selects a particular interleaver from a plurality of interleavers based on a DL BWP configured by the gNB.). In view of the above, having the system of Su, then given the well-established teaching of Kim, it would have been obvious before the effective filing date of the claimed invention to modify the system of Su as taught by Kim, in order to provide motivation for efficiently providing hybrid broadcast using both a broadcast network and an IP network (Par. 0005 of Kim). Regarding claim 30, Su shows an apparatus (Figure 67 shows device implemented as a base station.) for wireless communications at a network device, comprising: one or more processors, one or more memories coupled with the one or more processors; and instructions stored in the one or more memories and executable by the one or more processors (Figure 67 shows the base station including software stored in memory and executed by one or more processors to perform the disclosed method.) to cause the apparatus to: determine that a slot is configured for full duplex communications with a user equipment (UE) based at least in part on an uplink transmission and a downlink transmission for the UE (Figures 30-31; Par. 0441, 0462-0467; the base station allocates, to the UE or the UE group, physical resources of a physical shared channel in the first transmission direction, invalid physical resources in allocated physical resources for uplink and/or downlink transmission, on which no transmission is to be performed, and a full-duplex transmission. The scheduling grant indicates the location of the second physical resources by notifying a relative location with reference to a start or end location of physical resources in time domain (i.e. time slot) and/or frequency domain of the physical downlink shared channel.); and communicate the uplink transmission and the downlink transmission with the UE based at least in part on an interleaving configuration (Figures 30-31; Par. 0425; the base station transmits at least one of the configured transmission resources to the UE or the UE group.) wherein the interleaving configuration is based at least in part on determining that the slot is configured for full duplex communications (Figures 24-25; Par. 0331-0335, 0376, 0405; it is determined that there is or may be a full-duplex transmission on the obtained physical resources of the physical shared channel in the first transmission direction.). Su shows all of the elements as discussed above. Su does not specifically show wherein the interleaving configuration is selected from a plurality of interleaving configurations based at least in part on a downlink resource bandwidth for downlink transmission. However, the above-mentioned claim limitations are well-established in the art as evidenced by Kim. Specifically, Kim shows wherein the wherein the interleaving configuration is selected from a plurality of interleaving configurations based at least in part on a downlink resource bandwidth for downlink transmission (Figures 5 and 8; Par. 0068, 0084-0089; UE selects a particular interleaver from a plurality of interleavers based on a DL BWP configured by the gNB.). In view of the above, having the system of Su, then given the well-established teaching of Kim, it would have been obvious before the effective filing date of the claimed invention to modify the system of Su as taught by Kim, in order to provide motivation for efficiently providing hybrid broadcast using both a broadcast network and an IP network (Par. 0005 of Kim). Claim(s) 6 is rejected under 35 U.S.C. 103 as being unpatentable over Su in view of Kim and Kundu et al. (US 2021/0037605; hereinafter Kundu). Regarding claim 6, modified Su shows all of the elements as discussed above. Modified Su does not specifically show selecting a full duplex interleaving configuration based at least in part on the downlink bandwidth part being located within a threshold distance in a frequency domain from an uplink bandwidth part for the uplink transmission or the downlink resource bandwidth being located within the threshold distance in the frequency domain from an uplink resource bandwidth for the uplink transmission. However, the above-mentioned claim limitations are well-established in the art as evidenced by Kundu. Specifically, Kundu shows selecting a full duplex interleaving configuration based at least in part on the downlink bandwidth part being located within a threshold distance in a frequency domain from an uplink bandwidth part for the uplink transmission or the downlink resource bandwidth being located within the threshold distance in the frequency domain from an uplink resource bandwidth for the uplink transmission (Par. 0054; cycling of cyclic shifts across PRBs of the interlace may be supported for PUCCH formats. A PUCCH resource configured with interlaced mapping occupies consecutive PRBs within at least one interlace within a BWP. The PUCCH resource configuration includes the following: an indication of the allocated interlace; an indication of the location of the PUCCH resource within the allocated interlace (which may not be used for a bandwidth part of 20 MHz or less); and the number of PRBs NPUCCH within the allocated interlace is given by the following: NPUCCH=10 or 11 depending on the allocated interlace for interlaced PF0/1/2 and NPUCCH=10 for interlaced PF3.). In view of the above, having the system of Su, then given the well-established teaching of Kundu, it would have been obvious before the effective filing date of the claimed invention to modify the system of Su as taught by Kundu, in order to provide motivation for improving the interference cancellation capability of the system (Par. 0069 of Su). Claim(s) 11-12, 15, 25-26 and 28 is/are rejected under 35 U.S.C. 103 as being unpatentable over Su in view of Kim and Luo et al. (US 2022/0232615; hereinafter Luo). Regarding claim 11, modified Su shows all of the elements except determining that a set of repetitions of the downlink transmission spans multiple slots including the slot based at least in part on the scheduling information, wherein the interleaving configuration is selected based at least in part on the set of repetitions. However, the above-mentioned claim limitations are well-established in the art as evidenced by Luo. Specifically, Luo shows determining that a set of repetitions of the downlink transmission spans multiple slots including the slot based at least in part on the scheduling information, wherein the interleaving configuration is selected based at least in part on the set of repetitions (Par. 0348; the first indication information includes a maximum repetition quantity Rmax of a downlink control channel; and the processor 1101 is specifically configured to: when Rmax is greater than or equal to a first threshold, determine that the target transmission mode is the interleaved transmission mode; or when Rmax is less than a first threshold, determine that the target transmission mode is the sequential transmission mode.). In view of the above, having the system of Su, then given the well-established teaching of Luo, it would have been obvious before the effective filing date of the claimed invention to modify the system of Su as taught by Luo, in order to provide motivation for implementing symbol-level combination and improve frequency offset tracking performance (Par. 0310 of Luo). Regarding claim 12, modified Su shows selecting a half duplex interleaving configuration for each slot of the multiple slots configured for half duplex communications; and selecting a full duplex interleaving configuration for each slot of the multiple slots configured for full duplex communications (Su: Par. 0348; the indication information may be UE level full-duplex indication information. In an example, when the full duplex indication information obtained by the UE is enabled, the waveforms of the scheduled uplink and/or downlink physical channel may be OFDM for which the transform domain precoding is not enabled; otherwise, the waveform of the scheduled uplink and/or downlink physical channel is obtained according to the half-duplex system configuration.). Regarding claim 15, modified Su shows determining multiple downlink bandwidth parts for a repetition of the set of repetitions in a full duplex slot of the multiple slots; and selecting a full duplex interleaving configuration for the full duplex slot based at least in part on the multiple downlink bandwidth parts being positioned on both sides of an uplink bandwidth part for the uplink transmission in a frequency domain within the full duplex slot (Su: Figure 25; Par. 0381-0386; it is determined that there is a full-duplex transmission on the obtained physical resources of the physical shared channel in the first transmission direction according to at least one of following criteria: an obtained transmission subframe of the physical shared channel in the first transmission direction being a subframe in a second transmission direction, wherein the first transmission direction is different from the second transmission direction; for example, the first transmission direction is uplink, and the second transmission direction is downlink; or the first transmission direction is downlink, and the second transmission direction is uplink; an obtained transmission bandwidth of the physical shared channel in the first transmission direction being a bandwidth in the second transmission direction; obtained frequency domain resources of the physical shared channel in the first transmission direction being located in a bandwidth part/configured bandwidth/system bandwidth in which the full duplex transmission is enabled.). Regarding claim 25, modified Su shows all of the elements except determining that a set of repetitions of the downlink transmission spans multiple slots including the slot, wherein the interleaving configuration is selected based at least in part on the set of repetitions. However, the above-mentioned claim limitations are well-established in the art as evidenced by Luo. Specifically, Luo shows determining that a set of repetitions of the downlink transmission spans multiple slots including the slot, wherein the interleaving configuration is selected based at least in part on the set of repetitions (Par. 0348; the first indication information includes a maximum repetition quantity Rmax of a downlink control channel; and the processor 1101 is specifically configured to: when Rmax is greater than or equal to a first threshold, determine that the target transmission mode is the interleaved transmission mode; or when Rmax is less than a first threshold, determine that the target transmission mode is the sequential transmission mode.). In view of the above, having the system of Su, then given the well-established teaching of Luo, it would have been obvious before the effective filing date of the claimed invention to modify the system of Su as taught by Luo, in order to provide motivation for implementing symbol-level combination and improve frequency offset tracking performance (Par. 0310 of Luo). Regarding claim 26, modified Su shows selecting a half duplex interleaving configuration for each slot of the multiple slots configured for half duplex communications; and selecting a full duplex interleaving configuration for each slot of the multiple slots configured for full duplex communications (Su: Par. 0348; the indication information may be UE level full-duplex indication information. In an example, when the full duplex indication information obtained by the UE is enabled, the waveforms of the scheduled uplink and/or downlink physical channel may be OFDM for which the transform domain precoding is not enabled; otherwise, the waveform of the scheduled uplink and/or downlink physical channel is obtained according to the half-duplex system configuration.). Regarding claim 28, modified Su shows determining multiple downlink bandwidth parts for a repetition of the set of repetitions in a full duplex slot of the multiple slots; and selecting a full duplex interleaving configuration for the full duplex slot based at least in part on the multiple downlink bandwidth parts being positioned on both sides of an uplink bandwidth part for the uplink transmission in a frequency domain within the full duplex slot (Su: Figure 25; Par. 0381-0386; it is determined that there is a full-duplex transmission on the obtained physical resources of the physical shared channel in the first transmission direction according to at least one of following criteria: an obtained transmission subframe of the physical shared channel in the first transmission direction being a subframe in a second transmission direction, wherein the first transmission direction is different from the second transmission direction; for example, the first transmission direction is uplink, and the second transmission direction is downlink; or the first transmission direction is downlink, and the second transmission direction is uplink; an obtained transmission bandwidth of the physical shared channel in the first transmission direction being a bandwidth in the second transmission direction; obtained frequency domain resources of the physical shared channel in the first transmission direction being located in a bandwidth part/configured bandwidth/system bandwidth in which the full duplex transmission is enabled.). Conclusion The prior art made of record and not relied upon is considered pertinent to applicant's disclosure. US 20210314114 A1 - A method by which a terminal receives a downlink signal according to an embodiment of the present invention includes: receiving configuration information for each of a plurality of CORESETs; mapping each CCE of a control channel candidate to at least one REG bundle by performing interleaving on a first CORESET among the plurality of CORESETs; and attempting the detection of downlink control information of the terminal from the control channel candidate on the basis of the mapping between each CCE and the at least one REG bundle, wherein when the first CORESET on which the interleaving is performed overlaps a second CORESET among the plurality of the CORESETs and an aggregation level of the control channel candidate is 2 or greater, the terminal can perform interleaving so that at least one REG bundle of a first CCE among the different CCEs configuring the control channel candidate and at least one REG bundle of a second CCE are consecutive to each other in the frequency domain. Any inquiry concerning this communication or earlier communications from the examiner should be directed to REDENTOR M PASIA whose telephone number is (571)272-9745. The examiner can normally be reached Mondays-Thursdays - 5am-245pm and Fridays 5am-330pm. Examiner interviews are available via telephone, in-person, and video conferencing using a USPTO supplied web-based collaboration tool. To schedule an interview, applicant is encouraged to use the USPTO Automated Interview Request (AIR) at http://www.uspto.gov/interviewpractice. If attempts to reach the examiner by telephone are unsuccessful, the examiner’s supervisor, Un Cho can be reached at (571)272-7919. The fax phone number for the organization where this application or proceeding is assigned is 571-273-8300. Information regarding the status of published or unpublished applications may be obtained from Patent Center. Unpublished application information in Patent Center is available to registered users. To file and manage patent submissions in Patent Center, visit: https://patentcenter.uspto.gov. Visit https://www.uspto.gov/patents/apply/patent-center for more information about Patent Center and https://www.uspto.gov/patents/docx for information about filing in DOCX format. For additional questions, contact the Electronic Business Center (EBC) at 866-217-9197 (toll-free). If you would like assistance from a USPTO Customer Service Representative, call 800-786-9199 (IN USA OR CANADA) or 571-272-1000. /REDENTOR PASIA/Primary Examiner, Art Unit 2413