Patent Grant
9854519
Field of the Invention
The present invention relates to a handheld device, a base station and transmission control methods thereof. More particularly, the handheld device of the present invention transmits an uplink signal with an uplink dedicated physical data channel (UL DPDCH) in which only first 15 non-transmission gap (non-TG) data slots within two radio frames carry user data.
Descriptions of the Related Art
With the development of wireless communication technologies, wireless devices have been widely used. To satisfy users' demand for speech service, various telecommunication standards have been developed. Universal mobile telecommunications system frequency division duplex (UMTS-FDD) Release 99 is a version of the third generation (3G) communication system. The UMTS-FDD Release 99 provides circuit-switched speech service in which a circuit-switched connection is established between a user device and a base station. User data and physical layer control information are carried on dedicated physical channels (DPCHs) of the uplink signal and the downlink signal, and the uplink signal and the downlink signal are respectively transmitted in different frequency bands at the same time.
However, power saving is a critical issue for the user device. Accordingly, an urgent need exists in the art to provide a transmission mechanism for reducing the power consumption in the user device.
The objective of the present invention is to provide a transmission control mechanism for circuit-switched speech services in which the minimum TTI is two radio frames. By the transmission control mechanism of the present invention, the user device only use the first 15 non-transmission gap (non-TG) data slots within two radio frames of UL DPDCH to carry user data. Therefore, the present invention can reduce the power consumption in the user device in such a case that a downlink data frame is successfully and early decoded or the base station also use the first 15 non-transmission gap (non-TG) data slots within two radio frames of DL DPDCH to carry the downlink data.
To achieve the aforesaid objective, the present invention discloses a handheld device which comprises a processor and a transceiver. The processor is configured to generate an uplink signal according to a transmission type. The transceiver is electrically connected to the processor and configured to transmit the uplink signal to a base station. The uplink signal comprises an uplink dedicated physical data channel (UL DPDCH) having 15 non-transmission gap (non-TG) data slots within two radio frames to carry user data.
In addition, the present invention further discloses a transmission control method for use in a handheld device. The handheld device comprises a processor and a transceiver. The transceiver is electrically connected to the processor. The transmission control method comprises the following steps:
Besides, in order to achieve the aforesaid objective, the present invention further discloses a base station which comprises a transceiver and a processor. The transceiver is configured to receive an uplink signal from a handheld device. The uplink signal comprises an uplink dedicated physical data channel (UL DPDCH) having 15 non-transmission gap (non-TG) data slots within two radio frames to carry user data. The processor is electrically connected to the transceiver and configured to retrieve the user data from the 15 non-transmission gap (non-TG) data slots.
Moreover, the present invention further discloses a transmission control method for use in a base station. The base station comprises a transceiver and a processor. The processor is electrically connected to the transceiver. The transmission control method comprises the following steps:
The detailed technology and preferred embodiments implemented for the subject invention are described in the following paragraphs accompanying the appended drawings for people skilled in this field to well appreciate the features of the claimed invention.
The present invention provides a handheld device, a base station and transmission control methods thereof. In the following description, the present invention will be explained with reference to embodiments thereof. It shall be appreciated that, theses embodiments of the present invention are not intended to limit the present invention to any specific environment, applications or implementations described in these embodiments. Therefore, the description of these embodiments is only for purpose of illustration rather than to limit the present invention and the scope claimed in this application shall be governed by the claims. Additionally, in the following embodiments and the attached drawings, elements unrelated to the present invention are omitted from depiction; and dimensional relationships among individual elements in the attached drawings are illustrated only for ease of understanding, but not to limit the actual scale.
The first embodiment of the present invention is depicted in
The handheld device 2 comprises a processor 201 and a transceiver 203. The transceiver 203 is electronically connected to the processor 201. When the handheld device 2 communicates with the base station 5, the processor 201 generates an uplink signal 202 according to a transmission type (hereinafter called the first transmission type). The transceiver 203 transmits the uplink signal 202 to the base station 5 and receives a downlink signal 204 from the base station 5 simultaneously. The uplink signal 202 comprises an uplink dedicated physical data channel (UL DPDCH). In the first transmission type, the UL DPDCH has only 15 non-transmission gap (non-TG) data slots within two radio frames to carry user data.
Compared to the normal mode, the compressed mode has a period of time corresponding to some TG data slots within a minimum TTI and the period of time is used for measurement purpose. In this case, the user data are only carried by the non-TG data slots. For example, in the case that there are three TG data slots within the first 15 data slots (i.e., Slot #12 to Slot #14) in the compressed mode, the UL DPDCH of the uplink signal 202 carries user data in the first 15 non-TG data slot (i.e., Slot #1 to Slot #11 and Slot #15 to Slot #18).
The following description will focus on the configuration of the first transmission type of the present invention. In detail, a spreading factor applied to the UL DPDCH according to the first transmission type may be determined by Equation 1:
where Ndata is a number of data bits carried in a single non-TG data slot of the first 15 non-TG data slots and SF is the spreading factor applied to the UL DPDCH. It can be appreciated that in the first transmission type, user data are only carried in the first 15 non-TG data slots within two radio frames. Thus, in the normal mode, the number of data bits carried in a single non-TG data slot of the first transmission type is double that of the second transmission type. This results in a smaller spreading factor applied to the UL DPDCH in the first transmission type compared to that applied to the UL DPDCH in the second transmission type.
Besides, a nominal power relation in the first transmission type of the present invention may be defined by Equation 2:
Ajp=√{square root over (2)}·Aj (Equation 2),
where Ajp is the nominal power relation in the first transmission type and Aj is a nominal power relation in the UMTS-FDD Release 99 and the second transmission type. Aj is defined by Equation 3:
where βd is a gain factor of the UL DPDCH and βc is a gain factor of the UL DPCCH. Since the nominal power relation Aj in the UMTS-FDD Release 99 has been well appreciated by a person having ordinary skill in this art, it will not be further described herein.
It should be appreciated that, during soft handover, each handheld device can communicate with more than one base station simultaneously with the same UL DPCH. In other words, the handheld device 2 can communicate not only with the base station 5 but also with other base station simultaneously with the same UL DPCH during soft handover.
A second embodiment of the present invention is depicted in
As shown in
In the present invention, each non-TG control slot has three fields which includes the pilot field, the transport format combination indicator (TFCI) field and the transmit power control (TPC) field, but excludes the FBI field. The TFCI field carries 2 bits, the pilot field carries 6 bits and the TPC field carries 2 bits. Since the present invention only focuses on the information carried in the TFCI field, the pilot field and the TPC field are not further described herein.
In the normal mode, the first 10 control slots within the two radio frames of the UL DPCCH carry the TFCI code word. Then, the processor 201 fills the ACK information from Slot #11, depending on whether the downlink data frame of the downlink signal 204 has been successfully decoded. The situation I in
Similarly,
It is note that the TFCI code word in the present invention is a truncated 20-bit TFCI code word from a 32-bit TFCI code word corresponding to a 10-bit TFCI information. For example, the 10-bit TFCI information may be encoded with the Reed-Muller code into the 32-bit TFCI code word, and then each TFCI field of the first 10 non-TG control slots carries 2 bits of the truncated 20-bit TFCI code.
A third embodiment of the present invention is depicted in
A fourth embodiment of the present invention is depicted in
Specifically, the processor 201 fills the NACK indication into every non-TG control slot in which the downlink data frame of the downlink signal 204 has not been successfully decoded by the processor 201. By contrast, the processor 201 fills the ACK indication into every non-TG control slot in which the downlink data frame of the downlink signal 204 has been successfully decoded by the processor 201. For example, as shown in the situation I of
In other embodiments, the processor 201 may further boost a transmission power of the ACK indications so that the transmission power of the ACK indications is larger than that of the NACK indications. Due to the power enhancement in the ACK indications, the base station 5 is capable of more accurately detecting the ACK indications so that the base station 5 can terminate the transmission of the downlink data frame of the downlink signal 204 according to the ACK indications.
A fifth embodiment of the present invention is shown in
In other words, for the last non-TG control slot of the remaining non-TG slots, as long as it corresponds to the last slot in the minimum TTI and its previous two successive non-TG control slots filled with the NACK indication, the processor 201 shall always fill the NACK indication regardless of whether the downlink data frame of the downlink signal 204 has been decoded successfully yet since it has no followed up non-TG control slot to constitute an ACK command with it.
In other embodiment, the processor 201 fills the NACK indication or the ACK indication into the last non-TG control slot in the minimum TTI depending on whether the downlink data frame of the downlink signal 204 has been decoded successfully yet. Specifically, the processor 201 further fills the NACK indication into the last non-TG control slot of the remaining non-TG slots which corresponds to the last slot within two radio frames and in which the downlink data frame has not been successfully decoded by the processor, and fills the ACK indication into the last non-TG control slot of the remaining non-TG slots which corresponds to the last slot within two radio frames and in which the downlink data frame has successfully decoded and the previous two successive non-TG control slots are filled with the NACK indication.
For example, as shown in the situation I of
The situation II in
Similarly, as shown in situation II of
In addition, the situation I of
As shown in the situation II of
In other embodiment, due to the performance of the processor 201, the processor 201 might not be able to fill the 2-bit ACK indications into two successive non-TG control slots in which the downlink data frame of downlink signal 204 has just been successfully decoded. In this case, the processor 201 would fill the 2-bit NACK indications into two successive non-TG control slots.
For example, in the situation I of
A sixth embodiment of the present invention is shown in
In this embodiment, regarding the normal mode, the processor 201 fills the ACK indications and the NACK indications by the same way as described in the fifth embodiments. However, regarding the compressed mode, there are various situations based on the number of the TG control slots. For those slots of a command unit which are fully occupied by TG or TFCI transmission and fail to constitute an ACK command, the processor 201 ignores the ACK command insertion. Beside, for those slots of a command unit which are partially occupied by TG or TFCI and fails to constitute an ACK command, the processor 201 fills the NACK indications into the non-occupied slots of these slots.
Specifically, the processor 201 fills the NACK indications into the two consecutive non-TG control slots in which the downlink data frame of the downlink signal 204 has not been successfully decoded by the processor 201. Moreover, the processor 201 executes the following operations: (a) filling the ACK indications into the two consecutive non-TG control slots which correspond to two non-TG data slots of the 15 non-TG data slots and in which the downlink data frame of the downlink signal 204 has been successfully decoded by the processor 201; (b) filling the ACK indication into the two consecutive non-TG control slots which are without corresponding to two non-TG data slots of the 15 non-TG data slots and in which the downlink data frame of the downlink signal 204 has been successfully decoded by the processor 201 unless the previous two consecutive non-TG control slots are filled with the ACK indication; (c) filling the ACK indication into a last non-TG control slot of the remaining non-TG slot which corresponds to a last non-TG data slot of the 15 non-TG data slots and in which the previous two consecutive non-TG control slots are filled with the ACK indication. In addition, the processor 201 further fills the NACK indication into the a non-TG control slot of the remaining non-TG slot which is an odd-numbered slot and has no follow-up non-TG control slot, and fills the NACK indication into a non-TG control slot of the remaining non-TG slot which is an even-numbered slot and without a preceding non-TG control slot of the remaining non-TG slots.
In this embodiment, the processor 201 fills the NACK indication into a non-TG control slot of the remaining non-TG slot, which is an even-numbered slot and without a preceding non-TG control slot of the remaining non-TG slot, or which is an odd-numbered slot and without a follow-up non-TG control slot of the remaining non-TG slots, regardless of whether the downlink data frame of the downlink signal 204 has been successfully and early decoded yet. As a result, the base station 5 may ignore the ACK commands in these slots and can take each ACK command which starts from an odd-numbered slot.
For example, the situation I in
Furthermore, the situation III in
Similarly, as shown in the situation IV of
As previously described, in other embodiment, due to the performance of the processor 201, the processor 201 might not be able to fill the 2-bit ACK indications into two consecutive non-TG control slots in which the downlink data frame of downlink signal 204 has just been successfully decoded. In this case, the processor 201 would fill the 2-bit NACK indications into two consecutive non-TG control slots too late.
For example, in the situation I of
A seventh embodiment of the present invention is shown in
In detail, the processor 201 fills a NACK indication into a non-TG control slot of the remaining non-TG slot which is an odd-numbered slot and has no follow-up non-TG control slot and in which the downlink data frame of the downlink signal 204 has not been successfully decoded by the processor 201, and fills an ACK indication into a non-TG control slot of the remaining non-TG slot which is an odd-numbered slot and has no follow-up non-TG control slot and in which the downlink data frame of the downlink signal 204 has successfully decoded by the processor 201. In addition, the processor 201 further fills a NACK indication into a non-TG control slot of the remaining non-TG slot which is an even-numbered slot and without a preceding non-TG control slot of the remaining non-TG slots and in which the downlink data frame of the downlink signal 204 has not been successfully decoded by the processor 201. Conversely, the processor 201 fills an ACK indication into a non-TG control slot of the remaining non-TG slot which is an even-numbered slot and without a preceding non-TG control slot of the remaining non-TG slots and in which the downlink data frame of the downlink signal 204 has been successfully decoded by the processor 201.
In other words, based on whether the downlink data frame of the downlink signal 204 has been decoded successfully yet, the processor 201 fills an ACK or a NACK indication into a non-TG control slot of the remaining non-TG slot which is an even-numbered slot and without a preceding non-TG control slot of the remaining non-TG slots, or which is an odd-numbered slot and without a follow-up non-TG control slot of the remaining non-TG slots. It should be appreciated that the base station 5 in this embodiment can also take the ACK command from an odd-numbered slot and its follow-up even-numbered slot as described in the sixth embodiment.
For example, as shown in situation I of
Situation II of
Moreover, the situation III of
As aforementioned, in other embodiment, due to the performance of the processor 201, the processor 201 might not be able to fill the 2-bit ACK indications into a non-TG control slot in which the downlink data frame of downlink signal 204 has just been successfully decoded by the processor 201. In this case, the processor 201 would fill the 2-bit NACK indications into a non-TG control slots too late.
For example, in the situation II of
Likewise, in other embodiments, the processor 201 may further boost a transmission power of the ACK indications so that the transmission power of the ACK indications is larger than that of the NACK indications. Due to the power enhancement in the ACK indications, the base station 5 is capable of more accurately detecting the ACK indications so that the base station 5 can terminate the transmission of the downlink data frame of the downlink signal 204 according to the ACK indications.
An eighth embodiment of the present invention is an extension of the first to seventh embodiments. The TFCI code word on the UL DPCCH in this embodiment has indication information indicating the transmission type of the uplink signal 202. Moreover, in another embodiment, the processor 201 may generates a radio resource control (RRC) message indicating the transmission type of the uplink signal 202 and the transceiver 203 transmits the RRC message to the base station 5 in an initial connection establishment procedure. Accordingly, the base station 5 can be informed of the transmission type via the RRC message or the TFCI code word.
In other embodiments, the processor 201 may further select the transmission type from two transmission types (i.e. the first transmission type and the second transmission type) so as to generate the uplink signal 202. Specifically, the first transmission type of the present invention is depicted in
In addition, the transmission power of the first 15 non-TG data slots in the first transmission type is larger than the transmission power of the non-TG data slots in the second transmission type. Thus, in some situations (e.g. an uplink power limited situation or a function limited situation to the handheld device 2), the processor 201 may select the second transmission type rather than the first transmission type and generate an uplink signal according to the second transmission type.
A ninth embodiment of the present invention is a transmission control method, a flowchart diagram of which is shown in
Firstly, step 901 is executed by the processor to generate an uplink signal according to a transmission type. The uplink signal comprises an uplink dedicated physical data channel (UL DPDCH). The UL DPDCH has only 15 non-transmission gap (non-TG) data slots within two radio frames to carry user data. Afterwards, step 903 is executed by the transceiver of the handheld device to transmit the uplink signal to a base station.
As described earlier, the spreading factor applied to the UL DPDCH according to the first transmission type may be determined by Equation 1. In addition, the nominal power relation in the first transmission type may be defined by Equation 2. In other embodiments, the uplink signal further comprises an uplink dedicated physical control channel (UL DPCCH). The UL DPCCH has at least 15 non-TG control slots within the two radio frames. Each of the at least 15 non-TG control slots has a transport format combination indicator (TFCI) field. The TFCI fields of first 10 non-TG control slots of the at least 15 non-TG control slots carry a TFCI code word, and the TFCI fields of remaining non-TG control slots of the at least 15 non-TG control slots carry acknowledgement (ACK) information for downlink data frame early termination.
In detail, the ACK information comprises a plurality of 2-bit indications. Each of the 2-bit indication is carried in one of the remaining non-TG control slots, and each of the 2-bit indication is one of an acknowledgement (ACK) indication and a negative-acknowledgment (NACK) indication. In the case that each 2-bit indications carried in a single non-TG control slot constitutes an ACK command, step 901 may further comprises the steps of filling the NACK indication into a non-TG control slot in which a downlink data frame has not been successfully decoded by the processor; and filling the ACK indication into a non-TG control slot in which the downlink data frame has been successfully decoded by the processor. On the other hand, step 901 may comprise the step of boosting a transmission power of the ACK indication so that the transmission power of the ACK indication is larger than a transmission power of the NACK indication.
In other embodiments, every two 2-bit indications carried in two successive non-TG control slots of the remaining non-TG control slots constitutes an ACK command. In such a case, step 901 may further comprises the steps of: filling the NACK indications into the two successive slots in which the downlink data frame has not been successfully decoded by the processor; filling the ACK indications into the two successive non-TG control slots which correspond to two non-TG data slots of the 15 non-TG data slots and in which the downlink data frame has been successfully decoded by the processor; filling the ACK indication into the two successive non-TG control slots which are without corresponding to two non-TG data slots of the 15 non-TG data slots and in which the downlink data frame has been successfully decoded unless the previous two successive non-TG control slots are filled with the ACK indication; filling the ACK indication into a last non-TG control slot of the remaining non-TG slot corresponding to a last non-TG data slot of the 15 non-TG data slots when the two successive non-TG control slots previous to the last non-TG control slot are filled with the ACK indications; and filling, by the processor, the NACK indication into the last non-TG control slot of the remaining non-TG slots corresponding to a last slot within two radio frames when the previous two successive non-TG control slots are filled with the NACK indication.
In other embodiments, every two of the 2-bit indications carried in two successive non-TG control slots of the remaining non-TG control slots constitutes an ACK command. In such a case, step 901 may further comprises the steps of: filling, by the processor, the NACK indication into the two successive slots in which a downlink data frame has not been successfully decoded by the processor; filling, by the processor, the ACK indication into the two successive non-TG control slots which correspond to two non-TG data slots of the 15 non-TG data slots and in which the downlink data frame has successfully decoded by the processor; filling, by the processor, the ACK indication into the two successive non-TG control slots which are without corresponding to two non-TG data slots of the 15 non-TG data slots and in which the downlink data frame has successfully decoded by the processor unless previous two successive non-TG control slots are filled with the ACK indication; filling, by the processor, the ACK indication into a last non-TG control slot of the remaining non-TG slot corresponding to a last non-TG data slot of the 15 non-TG data slots when the two successive non-TG control slots previous to the last non-TG control slot are filled with the ACK indications; filling, by the processor, the NACK indication into the last non-TG control slot of the remaining non-TG slots which corresponds to a last slot within two radio frames and in which the downlink data frame has not been successfully decoded by the processor; and filling, by the processor, the ACK indication into the last non-TG control slot of the remaining non-TG slots which corresponds to the last slot within two radio frames and in which the downlink data frame has successfully decoded by the processor and the previous two successive non-TG control slots are filled with the NACK indication.
In other embodiments, every two 2-bit indications carried in two consecutive non-TG control slots of the remaining non-TG control slots constitutes an ACK command. In such a case, step 901 may further comprises the steps of: filling the NACK indications into the two consecutive slots in which a downlink data frame has not been successfully decoded by the processor; filling the ACK indications into the two consecutive non-TG control slots which correspond to two non-TG data slots of the 15 non-TG data slots and in which the downlink data frame has been successfully decoded by the processor; filling the ACK indication into the two consecutive non-TG control slots which are without corresponding to two non-TG data slots of the 15 non-TG data slots and in which the downlink data frame has been successfully decoded by the processor unless the previous two consecutive non-TG control slots are filled with the ACK indication; filling the ACK indication into a last non-TG control slot of the remaining non-TG slot corresponding to a last non-TG data slot of the 15 non-TG data slots when the two consecutive non-TG control slots previous to the last non-TG control slot are filled with the ACK indications; filling the NACK indication into a non-TG control slot of the remaining non-TG slot, which is an odd-numbered slot and has no follow-up non-TG control slot; and filling the NACK indication into a non-TG control slot of the remaining non-TG slot which is an even-numbered slot and without a preceding non-TG control slot of the remaining non-TG slot.
In another embodiment, every two of the 2-bit indications carried in two consecutive non-TG control slots of the remaining non-TG control slots constitutes an ACK command. However, in this embodiment, step 901 may further comprise the following steps of filling the NACK indication into the two consecutive slots in which a downlink data frame has not been successfully decoded by the processor; filling the ACK indication into the two consecutive non-TG control slots which corresponds to two non-TG data slots of the 15 non-TG data slots and in which the downlink data frame has been successfully decoded by the processor; filling the ACK indication into the two consecutive non-TG control slots which are without corresponding to two non-TG data slots of the 15 non-TG data slots and in which the downlink data frame has successfully decoded by the processor unless the previous two consecutive non-TG control slots are filled with the ACK indication; filling the ACK indication into a last non-TG control slot of the remaining non-TG slot corresponding to a last non-TG data slot of the 15 non-TG data slots when the two consecutive non-TG control slots previous to the last non-TG control slot are filled with the ACK indications; filling the NACK indication into a non-TG control slot of the remaining non-TG slot which is an odd-numbered slot and has no follow-up non-TG control slot and in which the downlink data frame has not successfully decoded by the processor; filling the ACK indication into a non-TG control slot of the remaining non-TG slot which is an odd-numbered slot and has no follow-up non-TG control slot and in which the downlink data frame has been successfully decoded by the processor; filling the NACK indication into a non-TG control slot of the remaining non-TG slot which is an even-numbered slot and without a preceding non-TG control slot of the remaining non-TG slot and in which the downlink data frame has not been successfully decoded by the processor; and filling the ACK indication into a non-TG control slot of the remaining non-TG slot which is an even-numbered slot and without a preceding non-TG control slot of the remaining non-TG slot and in which the downlink data frame has successfully decoded by the processor.
Besides, in other embodiments, the transmission control method may further comprise the steps of: generating, by the processor, a radio resource control (RRC) message indicating the transmission type; and transmitting, by the transceiver, the RRC message to the base station in an initial connection establishment procedure. Instead of using the RRC message to indicate the transmission type, in another embodiment, the TFCI code word may have the indication information to indicate the transmission type. And, in another embodiment, the transmission control method of the present invention may further comprise the step of: selecting, by the processor, the transmission type from two transmission types so as to generate the uplink signal.
In addition to the aforesaid steps, the transmission control method of the present embodiment can also execute all the operations and corresponding functions set forth in the first to eighth embodiment. How to execute these operations and functions will be readily appreciated by those of ordinary skill in the art based on the explanation of the first to sixth embodiments, and thus will not be further described herein.
A tenth embodiment of the present invention is a transmission control method, a flowchart diagram of which is shown in
In addition, the uplink signal further comprises an uplink dedicated physical control channel (UL DPCCH). The UL DPCCH has at least 15 non-TG control slots within the two radio frames. Each of at least 15 non-TG control slots has a transport format combination indicator (TFCI) field. The TFCI fields of first 10 non-TG control slots of the at least 15 non-TG control slots carry a TFCI code word, and the TFCI fields of remaining non-TG control slots of the at least 15 non-TG control slots carry acknowledgement (ACK) information for downlink data frame early termination. Accordingly, the transmission control method of this embodiment can further comprise the steps of: generating, by the processor, a downlink signal; transmitting, by the transceiver, the downlink signal to the handheld device; and enabling, by the processor, the transceiver to terminate transmission of a downlink data frame of the downlink signal according to the ACK information.
In other embodiments, the transmission control method of the present invention may further comprise the steps of: receiving, by the transceiver, a radio resource control (RRC) message indicating the transmission type from the handheld device in an initial connection establishment procedure. Instead of using the RRC message to indicate the transmission type, in another embodiment, the TFCI code word may have the indication information to indicate the transmission type. As set forth in the sixth embodiments, the handheld device generates the uplink signal based on the transmission type and the transmission type may be selected from two transmission types.
In addition to the aforesaid steps, the transmission control method of the present embodiment can also execute all the operations and corresponding functions set forth in the first to eighth embodiments. How to execute these operations and functions will be readily appreciated by those of ordinary skill in the art based on the explanation of the first to sixth embodiment, and thus will not be further described herein.
According to the above descriptions, the transmission control mechanism of the present invention can reduce the power consumption in the user device in such a case that downlink data is successfully and early decoded or the base station also use the first 15 non-transmission gap (non-TG) data slots in two radio frames of DL DPDCH to carry the downlink data. In addition, based on the ACK information carried in the TFCI fields of the UL DPCCH of the uplink signal received from a handheld device, the base station can terminate the transmission of the downlink data frame of the downlink signal to the handheld device and reallocate the transmission power of different downlink signals for multiple user devices so as to reduce the interference among the downlink signals.
The above disclosure is related to the detailed technical contents and inventive features thereof. People skilled in this field may proceed with a variety of modifications and replacements based on the disclosures and suggestions of the invention as described without departing from the characteristics thereof. Nevertheless, although such modifications and replacements are not fully disclosed in the above descriptions, they have substantially been covered in the following claims as appended.
The present application claims the priority benefit of U.S. provisional application Ser. Nos. 61/932,326, filed Jan. 28, 2014 and 61/954,145, filed Mar. 17, 2014. The contents of both of these provisional applications are incorporated herein by reference.
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