Patent Description:
Along with the development of mobile communication technology, the fourth generation of mobile phone mobile communication technology standards (<NUM>) and the fifth generation of mobile phone mobile communication technology standards (<NUM>) have been provided. The ultra-reliable and low latency communications (uRLLC) standard is a future standard of the mobile communication technology and will be used in the application fields having high requirements of latency and reliability such as IoT, self-driving, smart grid, VR, and factory automation. <CIT> describes to provide a user equipment for a mobile communication network. The mobile communication network has a radio access network including a plurality of cells and being configured to serve the user equipment within a cell. To receive a data packet from the radio access network, the user equipment is configured to receive a plurality of different versions of the data packet transmitted by the radio access network to the user equipment in parallel via different physical resources. To provide a data packet to the radio access network, the user equipment is configured to provide a plurality of different versions of the data packet and to transmit the plurality of different versions of the data packet to the radio access network in parallel via different physical resources. <CIT> discloses a pre-5th-Generation (<NUM>) or <NUM> communication system to be provided for supporting higher data rates Beyond 4th-Generation (<NUM>) communication system such as Long Term Evolution (LTE). Wherein embodiments of the document provide a method for triggering a transmission of a UE-to-Network relay indication comprising receiving, by UE, one of UE-to-Network relay criteria broadcasted by a base station, measuring, at the UE, a link quality parameter between the UE and the base station, detecting, by the UE, that the link quality parameter meets the UE-to-Network relay criteria, and transmitting, by the UE, the UE-to-Network relay indication (i.e. discovery message indicating itself as the UE-to-Network relay) on a Device to Device (D2D) discovery channel.

However, when the transmission channel is in a poor condition, the communication system needs to spend a considerable amount of time to repeatedly transmit the packets and therefore can hardly meet the requirement of low latency. Besides, when the transmission channel is in a poor condition, several packets may be lost, and it is difficult to meet the requirement of ultra-reliability.

Therefore, it has become a prominent task for the industries to provide a communication technology to maintain ultra-reliable and low latent communications.

The present invention relates to a communication system, a data transmission method and a base station thereof capable of collaborating a first base station and a second base station to reduce latency and increase reliability to meet the requirements of the ultra-reliable and low latency communications (uRLLC).

According to one embodiment of the present invention, a communication system is provided. The communication system includes a first base station and a second base station. The first base station includes a physical layer unit, a media access control layer unit (MAC layer unit) and a packet data convergence protocol layer unit (PDCP layer unit). The physical layer unit is configured to transmit with a user equipment through a transmission channel. The MAC layer unit is configured to determine whether a retransmission ratio of the transmission channel is higher than a first threshold and to determine whether a transmission speed of the transmission channel is lower than a second threshold. If the retransmission ratio of the transmission channel is higher than the first threshold and/or the transmission speed of the transmission channel is lower than the second threshold, the MAC layer unit of the first base station emits a co-transmission activation command for enabling the first base station to copy a packet and then transmit the copied packet to the second base station, which accordingly transmits the copied packet to the user equipment.

According to another embodiment of the present invention, a data transmission method of a communication system is provided. The communication system includes a first base station and a second base station. The data transmission method includes the following steps. Whether a retransmission ratio of a transmission channel between the first base station and a user equipment is higher than a first threshold is determined by the first base station. Whether a transmission speed of the transmission channel is lower than a second threshold is determined by the first base station. If the retransmission ratio of the transmission channel is higher than the first threshold and/or the transmission speed of the data is lower than the second threshold, the first base station emits a co-transmission activation command to copy a packet and then transmit the copied packet to the second base station, which accordingly transmits the copied packet to the user equipment.

According to an alternate embodiment of the present invention, a base station is provided. The base station includes a physical layer unit, a media access control layer unit (MAC layer unit) and a packet data convergence protocol layer unit (PDCP layer unit). The physical layer unit is configured to transmit with a user equipment through a transmission channel. The MAC layer unit is configured to determine whether a retransmission ratio of the transmission channel is higher than a first threshold and to determine whether a transmission speed of the transmission channel is lower than a second threshold. If the retransmission ratio of the transmission channel is higher than the first threshold and/or the transmission speed of the transmission channel is lower than the second threshold, the MAC layer unit emits a co-transmission activation command for enabling the base station to copy a packet and then transmit the copied packet to a co-transmitting base station, which accordingly transmits the copied packet to the user equipment.

The above and other aspects of the invention will become better understood with regard to the following detailed description of the preferred but non-limiting embodiment(s). The following description is made with reference to the accompanying drawings.

Referring to <FIG>, a relation diagram of a communication system <NUM> and a user equipment <NUM> according to an embodiment is shown. The communication system <NUM> at least includes a first base station <NUM> and a second base station <NUM>. The first base station <NUM> and the second base station <NUM> can be realized by macro cells or small cells. Examples of small cells include femtocell, picocell and microcell. A user equipment <NUM> is within the transmission coverage of the first base station <NUM> and the second base station <NUM>. The user equipment <NUM> can be realized by a mobile phone, a PC tablet or a laptop. A first transmission channel PH1 is disposed between the first base station <NUM> and the user equipment <NUM>. A second transmission channel PH2 is disposed between the second base station <NUM> and the user equipment <NUM>.

The user equipment <NUM> can transmit with the first base station <NUM> through the first transmission channel PH1. When the first transmission channel PH1 is in a good condition, it is easy to meet the requirements of the ultra-reliable and low latency communications (uRLLC). However, when the first transmission channel PH1 is in a poor condition, the first base station <NUM> needs to spend a considerable amount of time to repeatedly transmit the packets and may lose several packets, and it is difficult to meet the requirements of the ultra-reliable and low latency communications (uRLLC).

In the present embodiment, the collaboration technology of the first base station <NUM> and the second base station <NUM> can reduce latency and increase reliability to meet the requirements of the ultra-reliable and low latency communications (uRLLC). Referring to <FIG>, a schematic diagram of the communication system <NUM> and the user equipment <NUM> according to an embodiment is shown. The communication system <NUM> includes a first base station <NUM> and a second base station <NUM>. The first base station <NUM> includes a physical layer unit (PHY layer unit) <NUM>, a media access control layer unit (MAC layer unit) <NUM>, a radio link control layer unit (RLC layer unit) <NUM> and a packet data convergence protocol layer unit (PDCP layer unit) <NUM>. The second base station <NUM> includes a PHY layer unit <NUM>, an MAC layer unit <NUM>, an RLC layer unit <NUM> and a PDCP layer unit <NUM>. The PHY layer units <NUM> and <NUM>, the MAC layer units <NUM> and <NUM>, the RLC layer units <NUM> and <NUM> and the PDCP layer units <NUM> and <NUM> are layers under the communication protocols and can be realized by such as a circuit, a chip, a circuit board, several array codes, or a storage device for storing codes.

A base station inter-channel PH0 is disposed between the first base station <NUM> and the second base station <NUM>. A first transmission channel PH1 is disposed between the first base station <NUM> and the user equipment <NUM>. A second transmission channel PH2 is disposed between the second base station <NUM> and the user equipment <NUM>. When the first transmission channel PH1 is in a good condition, the packet PK received by the first base station <NUM> can be transmitted to the user equipment <NUM> through the first transmission channel PH1. When the first transmission channel PH1 is in a poor condition, the packet PK received by the first base station <NUM> can be transmitted to the second base station <NUM> through the base station inter-channel PH0, then the second base station <NUM> further transmits the packet PK to the user equipment <NUM> through the second transmission channel PH2. Thus, through the collaboration of the first base station <NUM> and the second base station <NUM>, the communication system <NUM> can recue latency and increase reliability to meet the requirement of ultra-reliable and low latency communications (uRLLC).

Refer to <FIG>. <FIG> are a flowchart of a data transmission method of the communication system <NUM> according to an embodiment. <FIG> is a schematic diagram of a co-transmission pause procedure. <FIG> is a schematic diagram of a co-transmission activation procedure. As indicated in <FIG>, the PDCP layer unit <NUM> includes a header compression module <NUM>, a cyphering module <NUM> and a duplication module <NUM>. The RLC layer unit <NUM> includes an RCL buffer <NUM>. The MAC layer unit <NUM> includes a media access control multiplexer (MAC multiplexer) <NUM>, a media access control scheduler (MAC scheduler) <NUM> and a media access control calculator (MAC calculator) <NUM>. The MAC scheduler <NUM> of the MAC layer unit <NUM> is configured to arrange the transmission of the packet PK. The MAC calculator <NUM> of the MAC layer unit <NUM> is configured to analyze the information of the first transmission channel PH1 (such as the retransmission ratio and the transmission speed). The PHY layer unit <NUM> includes a coding module <NUM> and is configured to transmit with the user equipment <NUM> through the first transmission channel PH1.

The PDCP layer unit <NUM> includes a header compression module <NUM>, a cyphering module <NUM> and a relay module <NUM>. The RLC layer unit <NUM> includes an RCL buffer <NUM>. The MAC layer unit <NUM> includes an MAC multiplexer <NUM>, an MAC scheduler <NUM> and an MAC calculator <NUM>. The PHY layer unit <NUM> includes a coding module <NUM> and is configured to transmit with the user equipment <NUM> through the second transmission channel PH2.

Refer to <FIG> and <FIG>. Firstly, the method begins at step S110, whether the retransmission ratio of the first transmission channel PH1 between the first base station <NUM> and the user equipment <NUM> is higher than a first threshold T1 is determined by the MAC calculator <NUM> of the first base station <NUM>. If the retransmission ratio of the first transmission channel PH1 is higher than the first threshold T1, the method proceeds to step S130; if the retransmission ratio of the first transmission channel PH1 is not higher than the first threshold T1, the method proceeds to step S120.

In step S120, whether the transmission speed of the first transmission channel PH1 is lower than a second threshold T2 is determined by the MAC calculator <NUM> of the first base station <NUM>. If the transmission speed of the first transmission channel PH1 is lower than the second threshold T2, the method proceeds to step S130; if the transmission speed of the first transmission channel PH1 is not lower than the second threshold T2, the method returns to step S110.

That is, when the retransmission ratio of the first transmission channel PH1 is higher than the first threshold T1 and/or the transmission speed of the first transmission channel PH1 is lower than the second threshold T2, the method proceeds to step S130.

The order of step S110 and that of step S120 are exchangeable and are not limited to the exemplification of <FIG>.

In step S130, a co-transmission activation command Al is emitted to the duplication module <NUM> by the MAC calculator <NUM> of the first base station <NUM>.

Then, the method proceeds to step S140, after a packet PK is copied by the duplication module <NUM> of the first base station <NUM>, the copied packet PK is transmitted to the second base station <NUM> through the base station inter-channel PH0.

Afterwards, the method proceeds to step S150, the copied packet PK is received by the relay module <NUM> of the second base station <NUM>.

Then, the method proceeds to step S160, the copied packet PK is transmitted to the user equipment <NUM> by the second base station <NUM> through the second transmission channel PH2.

In the above steps S110 to S160, although the first transmission channel PH1 is in a poor condition, the packet PK received by the first base station <NUM> still can be transmitted to the second base station <NUM> through the base station inter-channel PH0, and then is transmitted to the user equipment <NUM> by the second base station <NUM> through the second transmission channel PH2.

Refer to <FIG> and <FIG>. Then, the method proceeds to step S170, whether the retransmission ratio of the first transmission channel PH1 is lower than a third threshold T3 is determined by the MAC calculator <NUM> of the first base station <NUM>. If the retransmission ratio of the first transmission channel PH1 is lower than the third threshold T3, the method proceeds to step S180; if the retransmission ratio of the first transmission channel PH1 is not lower than the third threshold T3, the method returns to step S180. The third threshold T3 is smaller than the first threshold T1.

Then, the method proceeds to step S180, whether the transmission speed of the first transmission channel PH1 is higher than a fourth threshold T4 is determined by the MAC calculator <NUM> of the first base station <NUM>. If the transmission speed of the first transmission channel PH1 is higher than the fourth threshold T4, the method proceeds to step S190; if the transmission speed of the first transmission channel PH1 is not higher than the fourth threshold T4, the method returns to step S170. The fourth threshold T4 is larger than the second threshold T2.

That is, the method proceeds to step S190 only when the retransmission ratio of the first transmission channel PH1 is lower than the third threshold T3 and the transmission speed of the first transmission channel PH1 is higher than the fourth threshold T4.

The order of step S170 and that of step S180 are exchangeable and are not limited to the exemplification of <FIG>.

In step <NUM>, a co-transmission pause command NI is emitted by the MAC calculator <NUM> of the first base station <NUM> to stop the action of copying the packet PK and to transmit the copied packet PK to the second base station <NUM>.

In step S200, the transmission of the copied packet PK is stopped by the second base station <NUM>.

In step S210, the packet PK is transmitted to the user equipment <NUM> by the first base station <NUM> through the first transmission channel PH1.

Through the above steps S170 to S210, when the first transmission channel PH1 is in a good condition, the first base station <NUM> can directly transmit the received packet PK to the user equipment <NUM> through the first transmission channel PH1 instead of copying the received packet PK and then transmitting the copied packet PK to the second base station <NUM>.

After step S210, the method returns to step S110. The state of first transmission channel PH1 is examined again. As long as the first transmission channel PH1 is in poor condition, the second base station <NUM> is used to transmit the copied packet PK to the user equipment <NUM>; as long as the first transmission channel PH1 is in good condition, the first base station <NUM> is used to transmit the packet PK to the user equipment <NUM>.

To put it in greater details, as indicated in <FIG> and <FIG>, the MAC calculator <NUM> of the MAC layer unit <NUM> includes a first thread TD1, a second thread TD2 and a third thread TD3. The first thread TD1 is configured to emit a co-transmission activation command Al when the retransmission ratio of the first transmission channel PH1 is higher than the first threshold T1. The second thread TD2 is configured to emits the co-transmission activation command Al when the transmission speed of the first transmission channel PH1 is lower than the second threshold T2. The third thread TD3 is configured to emit the co-transmission pause command NI when the retransmission ratio of the first transmission channel PH1 is lower than the third threshold T3 and the transmission speed of the first transmission channel PH1 is higher than the fourth threshold T4.

The first thread TD1, the second thread TD2 and the third thread TD3 only need to be loaded to the first base station <NUM> instead of the second base station <NUM>, and the technology of the present embodiment can be implemented by the first thread TD1, the second thread TD2 and the third thread TD3.

To summarize, the collaboration technology of the first base station <NUM> and the second base station <NUM> of the present embodiment can reduce latency and increase reliability to meet the requirements of the ultra-reliable and low latency communications (uRLLC).

Claim 1:
A communication system (<NUM>), characterized in that the communication system (<NUM>) comprises:
a first base station (<NUM>), comprising:
a physical layer unit (<NUM>) configured to transmit with a user equipment (<NUM>) through a transmission channel (PH1);
a media access control layer unit, MAC layer unit, (<NUM>) configured to determine whether a retransmission ratio of the transmission channel (PH1) is higher than a first threshold (T1) and to determine whether a transmission speed of the transmission channel (PH1) is lower than a second threshold (T2); and
a packet data convergence protocol layer unit, PDCP layer unit, (<NUM>); and
a second base station (<NUM>);
wherein if the retransmission ratio of the transmission channel (PH1) is higher than the first threshold (T1) and/or the transmission speed of the transmission channel is lower than the second threshold (T2), the MAC layer unit (<NUM>) of the first base station (<NUM>) emits a co-transmission activation command (Al) for enabling the first base station (<NUM>) to copy a packet (PK) and then transmit the copied packet (PK) to the second base station (<NUM>) which accordingly transmits the copied packet (PK) to the user equipment (<NUM>).