Patent Description:
A conventional initial random access procedure is classified into a non-contention-based (Non-contention-based) random access procedure and a contention-based (Contention-based) random access procedure. If a random access procedure is a contention-based random access procedure, user equipment (User Equipment, UE for short) randomly selects a random access preamble sequence locally. If the random access procedure is a non-contention-based random access procedure, the UE may obtain a random access preamble sequence from scheduling information of a random access preamble sent by a base station by using a physical downlink control channel (Physical Downlink Control Channel, PDCCH) order (order).

In a Long Term Evolution (Long Term Evolution, LTE) system, a contention-based random access procedure is shown in <FIG>, and mainly includes four steps:.

Considering scenario requirements such as low delay, high reliability, and large-scale terminal access of a future communication protocol (for example, a fifth-generation mobile communication technology, English: Fifth-generation, <NUM> for short) low delay, in these scenarios, an access resource preempted by the UE for data transmission is relatively valuable, the existing random access procedure has become complex and inefficient, and new technologies are urgently needed to improve the existing random access procedure. <CIT> describes that transmit power is controlled for a first uplink data transmission on Physical Uplink Shared Channel (PUSCH) during random access channel (RACH) procedure. Power control adjustment for the first PUSCH transmission is performed relative to the power spectral density used for successful PRACH transmission as adjusted for bandwidth difference. <CIT> describes a terminal device arranged to communicate with a base station via a relay device in a wireless communications system. <CIT> describes coverage enhancement of channels in a wireless communication system such as Long Term Evolution and LTE-Advanced. <CIT> a wireless device that receives a control message configuring cell groups comprising a primary cell group and a secondary cell group.

Embodiments of the present invention provide a transmission method and apparatus, to improve an existing random access procedure, and help enable the random access procedure to be adapted to scenario requirements such as low delay, high reliability, and large-scale terminal access.

According to a first aspect, the present invention provides a transmission method according to appended claim <NUM>.

According to a second aspect, the present invention provides another transmission method according to appended claim <NUM>.

To describe technical solutions in embodiments of the present invention or in the background more clearly, the following briefly describes the accompanying drawings for describing the embodiments of the present invention or the background.

The following describes embodiments of the present invention with reference to the accompanying drawings in the embodiments of the present invention. Terms used in the implementations of the present invention are merely used to explain specific embodiments of the present invention.

First, a system architecture to which the embodiments of the present invention are applied is described. Referring to <FIG> is a schematic structural diagram of a wireless communication system according to an embodiment of the present invention. The wireless communication system includes at least a base station and a terminal described in the following embodiments. The base station and the terminal may communicate with each other (uplink transmission and downlink transmission) by using an air interface technology. The air interface technology may include existing <NUM> (for example, Global System for Mobile Communications (Global System for Mobile Communications, GSM)), <NUM> (for example, UMTS), Wideband Code Division Multiple Access (Wideband Code Division Multiple Access, WCDMA), Time Division-Synchronous Code Division Multiple Access (Time Division-Synchronous Code Division Multiple Access, TD-SCDMA), <NUM> (for example, FDD LTE and TDD LTE), and a new radio access technology (New Radio Access Technology, New RAT) system, for example, future <NUM> and <NUM> systems.

The base station is a device configured to communicate with the terminal, and the base station may be a BTS (Base Transceiver Station) in GSM or CDMA, or may be an NB (NodeB) in WCDMA, or may be an evolved NodeB (evolved NodeB, eNodeB) in LTE, a relay station, a vehicle-mounted device, an access network device in a future <NUM> network, an access network device in a future evolved public land mobile network (Public Land Mobile Network, PLMN) network, or the like.

The terminal is a device configured to communicate with the base station, and the terminal may include a relay (Relay) in a broad sense. In the present invention, a terminal in a general sense is described. The terminal may also be referred to as a mobile station, an access terminal, user equipment, a subscriber unit, a subscriber station, a mobile station, a remote station, a remote terminal, a mobile device, a user terminal, a terminal, a wireless communication device, a user agent, a user apparatus, or the like. The terminal may be a mobile phone, a Session Initiation Protocol (Session Initiation Protocol, SIP) phone, a wireless local loop (Wireless Local Loop, WLL) station, a tablet computer, a personal digital assistant (Personal Digital Assistant, PDA), user terminal CPE (Customer Premise Equipment), a handheld device with a wireless communication function, a computing device or another processing device connected to a wireless modem, a vehicle-mounted device, a wearable device, a transmission reception point (Transmission Reception Point, TRP), a network device (for example, gNB) in a future <NUM> network, or a device in a future evolved PLMN network. The base station may support communication of a plurality of terminals simultaneously.

It should be noted that, the technical solutions in the embodiments of the present invention may be applied to an initial random access scenario. The random access scenario may include a scenario of a four-step random access procedure (for example, as shown in <FIG>), or may include a scenario of a two-step random access procedure (for example, as shown in <FIG>), or may be a scenario of any other variable random access procedure. For ease of description, in the embodiments of the present invention, a two-step random access procedure is mainly used as an example for description. It may be understood that the technical solutions/technical ideas of the present invention may alternatively be applied to other random access procedures, and details are not described herein.

The following describes a two-step random access procedure in the present invention Referring to <FIG> is a schematic flowchart of a two-step random access procedure according to the present invention. The procedure mainly includes two steps:.

It can be learned that, compared with the related-art procedure shown in <FIG>, the two-step random access procedure can reduce an access delay of the terminal in radio access, and improve transmission efficiency in the random access procedure.

In the related-art procedure shown in <FIG>, the PUSCH and a PRACH use independent and different power control mechanisms, and UE neither reports a path loss value measured by the UE nor reports an actual transmit power value of the UE. In other words, the eNodeB does not know power information of the UE, for example, the path loss value measured by the UE, the actual transmit power of the UE, whether the UE is full power, and a calculated power of the UE.

In the two-step random access procedure, the PUSCH and the PRACH may be sent simultaneously. For example, the PUSCH and the PRACH may be sent in a same slot. In other words, time division multiplexing or frequency division multiplexing may be performed on the PUSCH and the PRACH in the same slot (for details, refer to the following description), and a random access preamble sent on the PRACH may be multiplexed as a demodulation reference signal of the PUSCH. Therefore, the base station needs to know transmit power information related to the PUSCH and the PRACH of the terminal, so that the base station can correctly demodulate the PUSCH, thereby improving processing performance of the base station.

In addition, in scenarios such as an unlicensed spectrum scenario and a non-orthogonal multiple access (Non orthogonal multiple access, NOMA) scenario in which an access resource is relatively valuable, a radio access resource preempted by the terminal for data transmission is relatively valuable. Resource utilization and resource transmission efficiency can be further improved based on the two-step random access procedure, and the random access procedure is adapted to large-scale terminal access.

The following describes related power information for sending the preamble and the PUSCH by the terminal.

It should be understood that in this embodiment of the present invention, the PRACH is a physical channel used by the terminal to send the random access preamble preamble, and the PUSCH is a physical channel used by the terminal to send to-be-transmitted uplink information. A transmit power of the PRACH may also be referred to as a transmit power or the like of the random access preamble.

In this embodiment of the present invention, an actual transmit power (the actual transmit power herein may also be referred to as a first transmit power) of the PRACH or the preamble is a smaller value between a maximum transmit power (which may also be referred to as a full power, Pmax) of the terminal and a calculated power (the calculated power herein may also be referred to as a first calculated power). For example, the actual transmit power of the PRACH can be set as shown in the following formula (<NUM>): <MAT>.

In specific implementation, if the terminal sends the preamble to the base station at the foregoing P, but does not receive feedback from the base station, the terminal may increase transmit power to send the preamble again.

In this embodiment of the present invention, the actual transmit power of the PUSCH is a smaller value between a maximum transmit power (which may also be referred to as a full power) of the terminal, PCMAX,c(i)) and a calculated power (the calculated power herein may also be referred to as a second calculated power). For example, the actual transmit power of the PUSCH may be set as shown in the following formula (<NUM>): <MAT>.

In specific implementation, the terminal sends the PUSCH to the base station at the foregoing PPUSCH,c(i).

To ensure the two-step random access procedure to be implemented, in this embodiment of the present invention, the two-step random access procedure is further improved, to improve transmission reliability and performance in the two-step random access procedure, so that the random access procedure is adapted to scenario requirements such as low delay, high reliability, and large-scale terminal access.

The following separately describes some specific improvement solutions in the embodiments of the present invention based on the embodiments in <FIG>, <FIG>, <FIG>, <FIG>, <FIG>, and <FIG>.

Referring to <FIG> is a schematic flowchart of a transmission method according to an embodiment of the present invention. The method is described from a terminal side and a base station side. The method includes but is not limited to the following steps.

Step <NUM>: A terminal sends a preamble at a first transmit power, and sends a PUSCH at a second transmit power. Correspondingly, a base station receives the preamble and the PUSCH.

In a specific embodiment, in a case of time division multiplexing on the preamble and the PUSCH, the terminal may separately send the preamble at the first transmit power and send the PUSCH at the second transmit power on different symbols in a same slot.

In another specific embodiment, in a case of frequency division multiplexing on the preamble and the PUSCH, the terminal may need to perform power scaling processing, to ensure that a sum of the first transmit power and the second transmit power is less than or equal to a maximum transmit power of the terminal. Then, on a same symbol in the same slot, the preamble may be sent at the first transmit power, and the PUSCH may be sent at the second transmit power separately. For specific implementation of this case, refer to related descriptions in the embodiment in <FIG> below.

For a slot in the time division multiplexing or the frequency division multiplexing, for example, in a system frame structure, a <NUM> frame is divided into two <NUM> half-frames, and each half-frame includes four data subframes and one special subframe. Each subframe is divided into two <NUM> slots, and each slot is further divided into seven OFDM symbols. For another example, the slot may alternatively be a time interval TTI and/or a time unit and/or a subframe and/or a mini-slot for signal transmission in a subcarrier spacing.

In this embodiment of the present invention, a PRACH (Physical random access Channel) is a physical random access channel, a mapping relationship is formed between the PRACH and the random access preamble (Preamble), and the PRACH is a channel used to transmit the preamble.

The PUSCH (physical uplink shared channel) is a physical uplink shared channel. The PUSCH may be used to transmit uplink data of a UL-SCH. In specific implementation, the terminal may send PUSCH data on an uplink resource notified or specified by the base station, or on an uplink resource defined by the terminal.

Step <NUM>: The terminal indicates a power deviation between the first transmit power and the second transmit power to the base station by using indication information. In other words, the indication information is used to enable the base station to determine the power deviation between the first transmit power and the second transmit power. Correspondingly, the base station obtains the indication information.

It should be noted that there is no necessary order between step <NUM> and step <NUM>.

According to the invention, the terminal adds the indication information to the PRACH or the PUSCH and transmits the indication information to the base station. In this case, step <NUM> and step <NUM> may be combined into a same step.

For another example, in another specific embodiment, the terminal sends the indication information to the base station by using a communication channel independent of the PRACH and the PUSCH. In this case, step <NUM> may be performed after S101, or may be performed before step <NUM>, or step <NUM> and step <NUM> may be performed simultaneously.

In a specific embodiment, the indication information is specifically used to indicate an attribute of the first transmit power and an attribute of the second transmit power. The attribute of the first transmit power is a maximum transmit power of the terminal or a first calculated power of the preamble; and the attribute of the second transmit power is the maximum transmit power of the terminal or a second calculated power of the PUSCH. In other words, in this case, the terminal indicates, to the base station by using the indication information, that power usage states of the PUSCH and the preamble are respectively a full power or a calculated actual power. A possible power usage state combination formed by the power usage states includes at least one of the following combinations:.

In another specific embodiment, the indication information is specifically used to indicate a quantized value of a difference between the first transmit power and the second transmit power. In other words, in this case, the terminal can directly report an index of a power difference between the PUSCH and the preamble. The power difference herein is, for example, a quantized power deviation value predefined between the base station and the terminal. For example, candidate values of the quantized power deviation may be {-<NUM>, -<NUM>, -<NUM>, <NUM>, +<NUM>, +<NUM>, +<NUM>, +<NUM>}, and corresponding reported indexes may be <NUM>, <NUM>, <NUM>, <NUM>, <NUM>, <NUM>, <NUM>, and <NUM> respectively. The base station derives a power deviation value between the first transmit power and the second transmit power based on a mapping relationship between the reported indexes and corresponding candidate values of the power deviation.

It should be noted that the foregoing examples are merely used to explain the present invention.

The base station sends a random access response and/or a contention resolution message to the terminal.

In a specific embodiment, when the random access procedure described in this embodiment belongs to a contention-based random access procedure, the base station generates a random access response, and the random access response is used as a response to the preamble. The base station generates a contention resolution message, and the contention resolution message is used to notify the terminal that the terminal can be accessed. Then, the base station sends the random access response and the contention resolution message to the terminal in a same slot.

In a specific embodiment, when the random access procedure described in this embodiment belongs to a non-contention-based random access procedure, the base station generates a random access response, and the random access response is used as a response to the preamble. Then, the base station sends the random access response to the terminal.

It should be noted that the random access response and/or the contention resolution message in this embodiment of the present invention may be different from the random access response and/or the contention resolution message in the related art. For example, the random access response in this embodiment of the present invention may not include uplink resource location indication information and a temporary C-RNTI that are allocated to the terminal.

It can be learned that, in this embodiment of the present invention, the terminal transmits the indication information to the base station in a two-step random access procedure, so that the base station can determine a transmit power deviation between the preamble and the PUSCH based on the indication information, thereby completing correct reception and demodulation of the PUSCH. In this way, reliability and performance of uplink transmission in the two-step random access procedure can be greatly improved, and it is ensured that the two-step random access procedure is implemented successfully, thereby reducing an access delay of the terminal in radio access, and improving efficiency and reliability of resource transmission in the random access procedure.

Referring to <FIG> is a schematic flowchart of another transmission method according to an embodiment of the present invention. The method is described from a terminal side and a base station side. The method includes but is not limited to the following steps.

Step <NUM>: A terminal sends, at a first transmit power, a random access preamble preamble carried in a PRACH, and sends a PUSCH at a second transmit power. Correspondingly, a base station receives the random access preamble preamble carried on the PRACH and the PUSCH.

The preamble is used as a demodulation reference signal (Demodulation RS, DMRS) of the PUSCH.

In addition, the PRACH or the PUSCH is further used to carry indication information, and the indication information is used to enable the base station to determine a power deviation between the first transmit power and the second transmit power.

For example, in a possible embodiment, the random access preamble carries the indication information. In other words, the indication is carried by using different preambles. In another possible embodiment, the indication information may be carried on a time domain resource and/or a frequency domain resource corresponding to the random access preamble. In still another possible embodiment, the indication information may be carried on a PUSCH resource (uplink data).

In a specific embodiment, the indication information is specifically used to indicate an attribute of the first transmit power and an attribute of the second transmit power. The attribute of the first transmit power is a maximum transmit power of the terminal or a first calculated power of the preamble; and the attribute of the second transmit power is the maximum transmit power of the terminal or a second calculated power of the PUSCH. In this case, the terminal indicates, to the base station by using the indication information, that power usage states of the PUSCH and the preamble/PRACH are respectively a full power or a calculated actual power. A possible power usage state combination formed by the power usage states includes at least one of the following combinations: {PRACH_max, PUSCH_max}, {PRACH_required, PUSCH_required}, {PRACH_max, PUSCH_required}, and {PRACH_required, PUSCH_max}.

In this case, the indication information may be indicated in one or more of the following manners: The indication information is indicated by a mapping relationship corresponding to the indication information and a time domain resource of the preamble; the indication information is indicated by a mapping relationship corresponding to the indication information and a frequency domain resource of the preamble; or the indication information is indicated by a mapping relationship corresponding to the indication information and the random access preamble.

In other words, the terminal may establish a mapping relationship between a time domain resource, and/or a frequency domain resource, and/or a preamble corresponding to the PRACH and a power usage state combination, and indicate the power usage state combination to the base station by using the mapping relationship.

For example, referring to <FIG> shows a scenario of establishing a mapping relationship between a frequency domain resource corresponding to a PRACH and a power usage state combination. As shown in <FIG>, in the frequency domain resource corresponding to the PRACH, one power usage state combination corresponds to a frequency domain resource of one PRACH (different frequency domain resources in the figure may be represented by using different rectangular patterns), so that {PRACH_max, PUSCH_max}, {PRACH_required, PUSCH_required}, {PRACH_max, PUSCH_ required}, and {PRACH_required, PUSCH_max} may be mapped to frequency domain resources corresponding to different PRACHs. In this way, after receiving the preamble, the base station may determine, based on the frequency domain resource corresponding to the PRACH used by the terminal to transmit the preamble, power usage states of the PUSCH and the preamble, to obtain a power deviation value between the PUSCH and the preamble, and may further receive and demodulate the PUSCH based on the preamble.

For another example, similarly, a mapping relationship between the time domain resource corresponding to the preamble and the power usage state combination may be established. Specifically, one power usage state combination may be set to correspond to the time domain resource of one PRACH, so that {PRACH_max, PUSCH_max}, {PRACH_required, PUSCH_required}, and {PRACH_max, PUSCH_ required}, and {PRACH_required, PUSCH_max} may be mapped to time domain resources corresponding to different PRACHs. In this way, after receiving the preamble, the base station may determine respective power usage states of the PUSCH and the preamble based on a time (namely, time domain resource) for transmitting the preamble by the terminal, to obtain a power deviation value between the PUSCH and the preamble, and may further receive and demodulate the PUSCH based on the preamble.

For another example, a mapping relationship between the preamble and the power usage state combination may be further predefined. For example, different preamble codes correspond to different power usage state combinations. In this way, after receiving the preamble, the base station may determine respective power usage states of the PUSCH and the preamble based on a preamble code transmitted by the terminal, to obtain a power deviation value between the PUSCH and the preamble, and may further receive and demodulate the PUSCH based on the preamble.

In this case, the indication information may also be indicated in one or more of the following manners: The indication information is indicated by a mapping relationship corresponding to the indication information and a time domain resource of the PRACH; the indication information is indicated by a mapping relationship corresponding to the indication information and frequency domain resource of the PRACH; or the indication information is indicated by a mapping relationship corresponding to the indication information and the random access preamble.

In other words, the terminal may establish a mapping relationship between a time domain resource, or a frequency domain resource, or a preamble code of the PRACH and a quantized power deviation value, and indicate the quantized power deviation value to the base station by using the mapping relationship.

For example, a mapping relationship between the frequency domain resource corresponding to the PRACH and the quantized power deviation value may be established. One quantized power deviation value corresponds to a frequency domain resource of one PRACH, so that different power deviation values may be mapped to frequency domain resources corresponding to different PRACHs. In this way, after receiving the preamble, the base station may determine a quantized power deviation value between the PUSCH and the preamble based on the frequency domain resource used by the terminal to transmit the preamble, and further obtain a difference between the first transmit power and the second transmit power.

For another example, similarly, a mapping relationship between the time domain resource corresponding to the PRACH and the quantized power deviation value may be established. Specifically, one quantized power deviation value may be set to correspond to the time domain resource of one PRACH, so that different quantized power deviation values may be mapped to time domain resources corresponding to different PRACHs. In this way, after receiving the preamble, the base station may determine a quantized power deviation value between the PUSCH and the preamble based on a time (namely, a time domain resource) for transmitting the preamble by the terminal, and further obtain a difference between the first transmit power and the second transmit power.

For another example, similarly, a mapping relationship between the time domain and frequency domain resource corresponding to the PRACH and the quantized power deviation value may be established. Specifically, one quantized power deviation value may be set to correspond to the time domain and frequency domain resource of one PRACH, so that different quantized power deviation values may be mapped to time domain and frequency domain resources corresponding to different PRACHs. In this way, after receiving the preamble, the base station may determine a quantized power deviation value between the PUSCH and the preamble based on a time (namely, a time domain resource) and a frequency (namely, a frequency domain resource) for transmitting the preamble by the terminal, and further obtain a difference between the first transmit power and the second transmit power.

For another example, a mapping relationship between the preamble and the quantized power deviation value may be further predefined. For example, different preamble codes correspond to different quantized power deviation values. In this way, after receiving a preamble code transmitted by the terminal, the base station may determine a quantized power deviation value between the PUSCH and the preamble, and further obtain a difference between the first transmit power and the second transmit power.

Step <NUM>: The base station performs channel estimation and demodulation on the PUSCH by using the random access preamble based on the indication information.

Specifically, the preamble is used as a demodulation reference signal when the base station receives uplink data (PUSCH data). Because there is a power difference between the PUSCH and the preamble, the base station cannot directly perform channel estimation and uplink data demodulation on the PUSCH by using the random access preamble, but first determines a power deviation between the PUSCH and the preamble by using the indication information, and then performs channel estimation and uplink data demodulation on the PUSCH by using the random access preamble based on the power deviation.

Step <NUM>: The base station sends a random access response and/or a contention resolution message to the terminal. For a specific implementation of this step, refer to related descriptions of step <NUM> in the embodiment in <FIG>.

Optionally, after an RRC connection succeeds, the terminal may alternatively report a power headroom report (Power Headroom Report, PHR) value of the terminal to the base station, so that the base station derives a path loss value of the terminal by using the PHR reported by the terminal and a full power.

It can be learned that, in this embodiment of the present invention, the random access preamble (Preamble) is used as a Msg3, namely, a demodulation reference signal of the PUSCH. When sending the preamble and the PUSCH, the terminal sends, to the base station, indication information used to indicate the transmit power deviation. In this way, the base station can successfully demodulate uplink data of the PUSCH by using the preamble based on the power deviation. In a future communication protocol (for example, <NUM>) scenario, a radio resource preempted by the terminal for data transmission is relatively valuable. Therefore, implementing the technical solutions of the present invention can improve radio resource utilization and meet a scenario requirement of large-scale terminal access.

Referring to <FIG> is a schematic flowchart of still another transmission method according to an embodiment of the present invention. The method is described from a terminal side and a base station side. The method includes but is not limited to the following steps.

Step <NUM>: A base station configures a higher layer signaling parameter for a terminal.

For example, for a preamble, higher layer signaling parameters of the preamble that are configured by the base station for the terminal include but are not limited to, P<NUM>,pre, Δpre, dPrampup, and the like.

For another example, for a PUSCH, higher layer signaling parameters of the PUSCH that are configured by the base station for the terminal include but are not limited to: ΔTF,c(i), PO_PUSCH,c(j), and αc(j). A candidate value of a path loss compensation factor αc(j) configured by the base station for the terminal is a real number between [<NUM>, <NUM>]. For example, the value is one of <NUM>, <NUM>, <NUM>, <NUM>, <NUM>, <NUM>, <NUM>, <NUM>, <NUM>, <NUM>, and <NUM>.

Step <NUM>: The terminal assumes (or sets) a value of the power compensation factor as <NUM>.

In a specific implementation, when the terminal determines that a current random access procedure is two-step random access, namely, when the preamble and the PUSCH need to be transmitted in a same slot, the terminal assumes the value of the power compensation factor αc(j) of the PUSCH as <NUM> by default.

It may be understood that, in another specific implementation, when the terminal supports both two-step random access and conventional four-step random access, the terminal is also allowed to switch between two random access procedures in this embodiment of the present invention. In this case, in a two-step random access scenario, the terminal assumes the value of the power compensation factor αc(j) of the PUSCH as <NUM>. In a conventional four-step random access scenario, the terminal configures the power compensation factor of the PUSCH for the terminal by using higher layer signaling, and a candidate value of the configured power compensation factor of the PUSCH may be a real number between [<NUM>, <NUM>].

For example, in a two-step random access scenario, the terminal may first determine whether the value of the power compensation factor configured by the base station for the terminal by using higher layer signaling is <NUM>. If the value is not <NUM>, the terminal assumes the value of αc(j) as <NUM>, and then calculates a transmit power of the PUSCH.

For example, in another two-step random access scenario, the terminal may alternatively directly assign <NUM> to αc(j) in a process of calculating a transmit power of the PUSCH.

Specifically, a calculated power (namely, a first calculated power) of the preamble may be determined based on at least one of the higher layer signaling parameters P<NUM>,pre, Δpre, dPrampup, and Npre of the preamble that are configured by the base station, and a path loss value PL measured by the terminal. For a specific calculation process, refer to the description of the calculated power provided in the foregoing formula (<NUM>).

Specifically, a calculated power (namely, a second calculated power) of the PUSCH may be determined based on at least one of the higher layer signaling parameters ΔTF,c(i), PO_PUSCH,c(j), and αc(j) of the PUSCH configured by the base station, and a path loss value PLc measured by the terminal. For a specific calculation process, refer to the description of the calculated power provided in the foregoing formula (<NUM>).

Step <NUM>: The terminal sends, at a first transmit power, a random access preamble carried in a PRACH, and sends a PUSCH at a second transmit power. Correspondingly, the base station receives the PRACH that carries the random access preamble and the PUSCH. The random access preamble is used as a demodulation reference signal (Demodulation RS, DMRS) of the PUSCH. In addition, the PRACH or the PUSCH is further used to carry indication information, and the indication information is used to enable the base station to determine a power deviation between the first transmit power and the second transmit power.

For a specific implementation of this step, refer to detailed descriptions of step <NUM> in the embodiment in <FIG>. For brevity of this specification, details are not described herein again.

Specifically, the base station determines a power deviation between the PUSCH and the preamble by using the indication information, and then performs channel estimation and uplink data demodulation on the PUSCH by using the random access preamble based on the power deviation.

In some embodiments, the indication information is used to indicate power usage states of the PUSCH and the PRACH/preamble. A possible power usage state combination formed by the power usage states includes at least one of the following combinations: {PRACH_max, PUSCH_max}, {PRACH_required, PUSCH_required}, {PRACH_max, PUSCH_required}, and {PRACH_required, PUSCH_max}.

Therefore, for example, if a power usage state combination currently obtained by the base station is {PRACH_max, PUSCH_max}, the base station directly determines that the power deviation between the PUSCH and the preamble is <NUM>.

For another example, if the power usage state combination currently obtained by the base station is {PRACH_required, PUSCH_required}, and the terminal does not report the path loss value to the base station, the base station may also assume the value of the power compensation factor αc(j) as <NUM>, and eliminates a difference between the preamble and the PUSCH in the power compensation factor (namely, a difference between the path loss value PL of the PRACH and the path loss value αc(j) * PLc of the PUSCH), so that a calculated power difference between the PUSCH and the preamble may be calculated based on the higher layer signaling parameter of the preamble and the higher layer signaling parameter of the PUSCH.

For another example, if the power usage state combination currently obtained by the base station is {PRACH_max, PUSCH_required}, although the calculated power PRACH_required of the preamble is greater than or equal to the maximum transmit power PRACH_max of the terminal, for simplicity, the maximum transmit power may be approximately replaced with the calculated power PRACH_required of the preamble, so that the power deviation value between the PUSCH and the preamble may be calculated based on the same processing manner as the foregoing state combination.

For another example, if the power usage state combination currently obtained by the base station is {PRACH_required, PUSCH_max}, although the calculated power of the PUSCH is greater than or equal to the maximum transmit power of the terminal, for simplicity, the maximum transmit power PUSCH_max may be approximately replaced with the calculated power PUSCH_required of the PUSCH, so that the power deviation value between the PUSCH and the preamble may be calculated based on the same processing manner as the foregoing state combination.

Optionally, after the RRC connection succeeds, the terminal may also report a power headroom report (Power Headroom Report, PHR) value of the terminal to the base station, so that the base station derives the path loss value of the terminal by using the PHR reported by the terminal and the maximum transmit power.

It can be learned that, in this embodiment of the present invention, the random access preamble (Preamble) is used as a Msg3, namely, the demodulation reference signal of the PUSCH, and the terminal assumes the value of the power compensation factor as <NUM>. When sending the preamble and the PUSCH, the terminal sends, to the base station, indication information used to indicate the power usage states of the PUSCH and the preamble. In this way, the base station can determine whether transmit powers of the PUSCH and the preamble of the terminal are respectively a calculated power or a full power, and can also calculate a power deviation between the transmit powers of the PUSCH and the preamble, so that uplink data of the PUSCH can be successfully demodulated by using the preamble. Therefore, implementing the technical solutions of the present invention can improve radio resource utilization, meet a scenario requirement of large-scale terminal access, and improve reliability of the two-step random access procedure.

Referring to <FIG> is a schematic flowchart of a transmission method according to an embodiment of the present invention. The method is described from a terminal side and a base station side. A main difference between the method and the method described in the embodiment in <FIG> lies in: In the embodiment in <FIG>, only the random access preamble is used as a DMRS; but in the method, the random access preamble is used as a front-loaded DMRS (front-loaded DMRS). In addition, a demodulation reference signal of the PUSCH further includes low-density additional DMRSs (additional DMRSs). The low-density herein means that a density of DMRSs of the PUSCH in the method is lower than that of DMRSs of the PUSCH in the related art. Specifically, the method includes but is not limited to the following steps.

Step <NUM>: A terminal sends, at a first transmit power, a random access preamble carried on a PRACH, and sends a PUSCH at a second transmit power. Correspondingly, a base station receives the random access preamble and the PUSCH.

The random access preamble is used as a front-loaded demodulation reference signal of the PUSCH; and the demodulation reference signal of the PUSCH further includes an additional demodulation reference signal of the PUSCH. The front-loaded demodulation reference signal and the additional demodulation reference signal are jointly used for demodulation of the PUSCH.

In addition, the PRACH/preamble or the PUSCH is further used to carry indication information, and the indication information is used to enable the base station to determine a power deviation between the first transmit power and the second transmit power. In a specific embodiment, the indication information is used to indicate an attribute of the first transmit power and an attribute of the second transmit power (namely, respective power usage states of the PRACH/preamble and the PUSCH). In another specific embodiment, the indication information may be used to indicate a quantized value of a difference between the first transmit power and the second transmit power. For a related specific implementation, refer to related descriptions of step <NUM> in the embodiment in <FIG>. For brevity of this specification, details are not described herein again.

When the indication information is carried in the preamble or the PRACH, the indication information is indicated by the terminal in one or more of the following manners: The indication information is indicated by a mapping relationship corresponding to the indication information and a time domain resource of the PRACH; the indication information is indicated by a mapping relationship corresponding to the indication information and a frequency domain resource of the PRACH; or the indication information is indicated by a mapping relationship corresponding to the indication information and a code resource of the preamble. For a related specific implementation, refer to related descriptions of step <NUM> in the embodiment in <FIG>. For brevity of this specification, details are not described herein again.

When the indication information is carried in the PUSCH, the indication information is indicated by the terminal in one or more of the following manners: The indication information is indicated by a mapping relationship corresponding to the indication information and a time domain resource of the PUSCH; the indication information is indicated by a mapping relationship corresponding to the indication information and a frequency domain resource of the PUSCH; or the indication information is indicated by a mapping relationship corresponding to the indication information and an additional demodulation reference signal sequence of the PUSCH.

In other words, when the indication information indicates the respective power usage states of the PRACH/preamble and the PUSCH, the terminal may establish a mapping relationship between a time domain resource, and/or a frequency domain resource of the PUSCH, or a DMRS sequence of the PUSCH and a power usage state combination, and indicate the power usage state combination to the base station by using the mapping relationship.

For example, referring to <FIG> shows a scenario of establishing a mapping relationship between a DMRS sequence of a PUSCH and a power usage state combination. As shown in <FIG>, in the PUSCH, one power usage state combination corresponds to a DMRS sequence of one PUSCH (a gray part in the figure represents the DMRS sequence of the PUSCH), so that {PRACH_max, PUSCH_max}, {PRACH_required, PUSCH_required}, {PRACH_max, PUSCH_ required}, and {PRACH_required, PUSCH_max} may be mapped to DMRS sequences of different PUSCHs (or mapped to different sequences). In this way, after receiving the PUSCH, the base station may determine respective power usage states of the PUSCH and the PRACH based on the DMRS of the PUSCH transmitted by the terminal.

For another example, similarly, a mapping relationship between the time domain resource of the PUSCH and the power usage state combination may be established. Specifically, one power usage state combination may be set to correspond to the time domain resource of one PUSCH, so that different power usage state combinations may correspond to different time domain resources of the PUSCH. In this way, after receiving the PUSCH, the base station may determine the respective power usage states of the PUSCH and the PRACH based on a time (namely, a time domain resource) for transmitting the PUSCH by the terminal.

For another example, similarly, a mapping relationship between the frequency domain resource of the PUSCH and the power usage state combination may be established. Specifically, one power usage state combination may be set to correspond to the frequency domain resource of one PUSCH, so that different power usage state combinations may be mapped to different frequency domain resources. In this way, after receiving the PUSCH, the base station may determine the respective power usage states of the PUSCH and the PRACH based on a frequency domain resource for transmitting the PUSCH by the terminal.

In addition, when the indication information indicates the quantized value of the difference between the transmit powers of the preamble and the PUSCH, the terminal may establish a mapping relationship between a time domain resource and/or a frequency domain resource of the PUSCH, or a DMRS sequence of the PUSCH and a quantized power deviation value, and indicate the quantized power deviation value to the base station by using the mapping relationship. For a specific implementation process, refer to the foregoing related descriptions.

Step <NUM>: The base station performs channel estimation and demodulation on the PUSCH based on the indication information by using the random access preamble and the additional DMRS of the PUSCH.

In other words, the random access preamble and the additional DMRS of the PUSCH are jointly used as the demodulation reference signal when the base station receives uplink data (PUSCH data). Because there is a power difference between the PUSCH and the PRACH, the base station first determines a power deviation between the PUSCH and the preamble by using the indication information, and then performs channel estimation and uplink data demodulation on the PUSCH based on the power deviation by using the random access preamble and the additional DMRS of the PUSCH.

It can be learned that in this embodiment of the present invention, the preamble and the additional DMRS of the PUSCH are jointly used as a Msg3, namely, the demodulation reference signal of the PUSCH, and the PUSCH only needs to carry low-density DMRSs (namely, additional DMRSs). When sending the preamble and the PUSCH, the terminal sends, to the base station, indication information used to indicate a transmit power deviation. In this way, the base station can successfully demodulate uplink data of the PUSCH by using the preamble and the additional DMRS of the PUSCH based on the power deviation. Therefore, implementing the technical solutions of the present invention can improve radio resource utilization, and meet a scenario requirement of large-scale terminal access.

Referring to <FIG> is a schematic flowchart of a transmission method according to an embodiment of the present invention. The method is described from a terminal side and a base station side. A main difference between the method and the method described in the embodiment in <FIG> lies in: In the embodiment in <FIG>, only the random access preamble is used as a DMRS of the PUSCH; but in the method, the random access preamble is used as a front-loaded DMRS (front loaded DMRS) of the PUSCH, and the PUSCH further carries low-density additional DMRSs (additional DMRSs). The low-density herein means that a density of DMRSs of the PUSCH in the method is lower than that of DMRSs of the PUSCH in the related art. Specifically, the method includes but is not limited to the following steps.

Step <NUM>: A base station configures a higher layer signaling parameter for a terminal. For a specific implementation process, refer to related descriptions of step <NUM> in the embodiment in <FIG>.

Step <NUM>: The terminal assumes a value of the power compensation factor as <NUM>. For a specific implementation process, refer to related descriptions of step <NUM> in the embodiment in <FIG>.

Step <NUM>: The terminal sends, at a first transmit power, a random access preamble carried in a PRACH, and sends a PUSCH at a second transmit power. Correspondingly, a base station receives the random access preamble and the PUSCH.

The random access preamble is used as a front-loaded demodulation reference signal of the PUSCH; and a demodulation reference signal of the PUSCH further includes an additional demodulation reference signal of the PUSCH. The front-loaded demodulation reference signal and the additional demodulation reference signal are jointly used for demodulation of the PUSCH.

For a specific implementation process of this step, refer to related descriptions of step <NUM> in the embodiment in <FIG>.

Step <NUM>: The base station performs channel estimation and demodulation on the PUSCH based on the indication information by using the random access preamble and the additional DMRS of the PUSCH. For a specific implementation process, refer to related descriptions of step <NUM> in the embodiment in <FIG>.

It can be learned that in this embodiment of the present invention, the preamble and the additional DMRS of the PUSCH are used as a Msg3, namely, the demodulation reference signal of the PUSCH, and the PUSCH only needs to carry a low-density DMRS (namely, an additional DMRS). In addition, the terminal assumes the value of the power compensation factor of the PUSCH as <NUM>. When sending the preamble and the PUSCH, the terminal sends, to the base station, indication information used to indicate power usage states of the PUSCH and the preamble. In this way, the base station can determine whether transmit powers of the PUSCH and the PRACH of the terminal are respectively a calculated power or a full power, and can calculate a power deviation between the transmit powers of the PUSCH and the PRACH, so that uplink data of the PUSCH can be successfully demodulated by using the preamble and the additional DMRS. Therefore, implementing the technical solutions of the present invention can improve radio resource utilization, meet a scenario requirement of large-scale terminal access, and improve reliability of the two-step random access procedure.

Referring to <FIG> is a schematic flowchart of a transmission method according to an embodiment of the present invention. The method is described from a terminal side and a base station side. A difference between the method and the method described in the embodiment in <FIG> lies in: The method describes a case of frequency division multiplexing on a PRACH and a PUSCH. The method includes but is not limited to the following steps.

Step <NUM>: A terminal performs scaling processing on a first pre-transmit power of the PRACH and a second pre-transmit power of the PUSCH.

The first pre-transmit power of the PRACH is a smaller value between a first calculated power and a full power (namely, a maximum transmit power) of the PRACH; and the second pre-sent power of the PUSCH is a smaller value between a second calculated power and a full power (namely, a maximum transmit power) of the PUSCH.

Specifically, in a case of frequency division multiplexing on the PRACH and the PUSCH, because the terminal needs to simultaneously send a preamble and the PUSCH on a same symbol in a same slot, the terminal needs to control a sum of transmit powers of the PRACH and the PUSCH to not exceed a maximum transmit power of the terminal.

When a power of the PRACH and a pre-transmit power of the PUSCH are greater than the maximum transmit power, the terminal separately performs scaling processing on the power of the PRACH and the pre-transmit power of the PUSCH, uses the power of the PRACH after the scaling processing as the first transmit power, and uses the power of the PUSCH after the scaling processing as the second transmit power, to ensure that a sum of the first transmit power and the second transmit power is less than or equal to the maximum transmit power of the terminal. Herein, a priority of scaling processing may optionally be: PRACH > PUSCH.

In a specific embodiment, a scale factor (or referred to as a scaling factor) configured by the base station for power allocation between the PRACH and the PUSCH may also be predefined or received. For example, the scale factor is <NUM>%. Because the priority of scaling processing is optionally PRACH > PUSCH, when scaling processing needs to be performed, the power of the PRACH is scaled by <NUM>%, and correspondingly, the power of the PUSCH may be scaled by <NUM>% or another predefined proportion.

In another specific embodiment, the terminal may separately predefine or configure respective scale factors (or referred to as a first scaling factor and a second scaling factor) of the PRACH and the PUSCH. For example, a candidate value of a scale factor combination between the PRACH and the PUSCH may be any one of (<NUM>%, <NUM>%), (<NUM>%, <NUM>%), or (<NUM>%, <NUM>%). This is not specifically limited herein.

It should be noted that, in the foregoing example, an example in which the sum of the first transmit power and the second transmit power is equal to the maximum transmit power of the terminal is used for description. However, in actual application, the sum of the first transmit power and the second transmit power may also be less than the maximum transmit power. This is not specifically limited herein.

Step <NUM>: The terminal sends the PRACH at the first transmit power (namely, the first pre-transmit power obtained after the scaling processing), and sends the PUSCH at the second transmit power (namely, the second pre-transmit power obtained after the scaling processing). Correspondingly, the base station receives the PRACH and the PUSCH. For a specific implementation, refer to related descriptions of step <NUM> in the embodiment in <FIG>.

Step <NUM>: The terminal uploads indication information to the base station, and correspondingly, the base station obtains the indication information. For a specific implementation, refer to related descriptions of step <NUM> in the embodiment in <FIG>.

Step <NUM>: The base station sends a random access response and/or a contention resolution message to the terminal. For a specific implementation, refer to related descriptions of step <NUM> in the embodiment in <FIG>.

It can be learned that, according to this embodiment of the present invention, in a case of frequency division multiplexing on the PRACH and the PUSCH, the terminal performs scaling processing on transmit powers of the PRACH and the PUSCH, to avoid damage to transmit performance of the terminal; and then, transmits indication information to the base station in the two-step random access procedure, so that the base station can determine the transmit power deviation between the PRACH and the PUSCH based on the indication information. In this way, it is ensured that the two-step random access procedure is implemented successfully, thereby reducing an access delay of the terminal in radio access, and improving transmission efficiency and service processing reliability of the base station in the random access procedure.

The foregoing describes the method in the embodiments of the present invention in detail, and the following provides a related apparatus in the embodiments of the present invention.

<FIG> is a structural block diagram of a communication system according to an embodiment of the present invention. The communication system includes a terminal <NUM> and a base station <NUM>. The terminal <NUM> and the base station <NUM> may implement wireless communication connections by using respective communication modules.

The terminal <NUM> includes a calculation module <NUM> and a communication module <NUM>. In a specific implementation, data/programs of these function modules may be stored in the following memory <NUM>, and the calculation module <NUM> and the communication module <NUM> may be run on the following processor <NUM>. In addition, function implementation of the communication module <NUM> depends on the following transceiver <NUM> to perform signal transmission and reception on an uplink/downlink channel.

In some embodiments, the calculation module <NUM> is configured to calculate a first transmit power used for sending a random access preamble and a second transmit power used for sending a PUSCH. The communication module <NUM> is configured to: send the random access preamble to the base station at the first transmit power, and send the PUSCH to the base station at the second transmit power, where a power deviation between the first transmit power and the second transmit power is indicated to the base station by using indication information. The communication module <NUM> is further configured to receive a random access response or a contention resolution message from the base station.

In some other embodiments, the communication module <NUM> is configured to receive a higher layer signaling parameter of a random access preamble and a higher layer signaling parameter of a PUSCH that are sent by the base station, where the higher layer signaling parameter of the PUSCH includes a power compensation factor. The calculation module <NUM> is configured to: obtain the higher layer signaling parameter of the random access preamble and the higher layer signaling parameter of the PUSCH, where both the higher layer signaling parameter of the random access preamble and the higher layer signaling parameter of the PUSCH are configured by the base station for the terminal, and the higher layer signaling parameter of the PUSCH includes the power compensation factor; obtain a first calculated power based on the higher layer signaling parameter of the random access preamble and a path loss value obtained by the terminal, and obtain a first transmit power based on the first calculated power; and assume a value of the power compensation factor as <NUM>, obtain a second calculated power based on the higher layer signaling parameter of the PUSCH and the path loss value obtained by the terminal, and obtain a second transmit power based on the second calculated power. The communication module <NUM> is further configured to: send a PRACH that carries the random access preamble to the base station at the first transmit power, and send the PUSCH to the base station at the second transmit power, where the PRACH is used to carry the random access preamble, and the random access preamble is used as a demodulation reference signal or front-loaded demodulation reference signal of the PUSCH. The communication module <NUM> is further configured to receive the random access response or the contention resolution message from the base station.

In still some other embodiments, the calculation module <NUM> is configured to calculate a first pre-transmit power of a random access preamble and a second pre-transmit power of a PUSCH, where the first pre-transmit power is a smaller value between a first calculated power and a maximum transmit power, and the second pre-transmit power is a smaller value between a second calculated power and the maximum transmit power. The calculation module <NUM> is further configured to perform power scaling processing on the first pre-transmit power and the second pre-transmit power based on a scaling factor, to obtain a first transmit power and a second transmit power, where a sum of the first transmit power and the second transmit power is less than or equal to the maximum transmit power, and the scaling factor is predefined or configured by the base station for the terminal. The communication module <NUM> is configured to: send the random access preamble to the base station at the first transmit power, and send the PUSCH to the base station at the second transmit power. The communication module <NUM> is further configured to receive a random access response or a contention resolution message from the base station.

The base station <NUM> includes a communication module <NUM> and a processing module <NUM>. In a specific implementation, data/programs of these function modules may be stored in the following memory <NUM>, and the communication module <NUM> and the processing module <NUM> may be run on the following processor <NUM>. In addition, function implementation of the communication module <NUM> depends on the following transceiver <NUM> to perform signal transmission and reception on an uplink/downlink channel.

In still some other embodiments, the communication module <NUM> is configured to: receive a random access preamble sent by a terminal at a first transmit power, and receive a PUSCH sent by the terminal at a second transmit power. The processing module <NUM> is configured to determine a power deviation between the first transmit power and the second transmit power by using indication information. Specifically, the processing module <NUM> determines a power deviation between the random access preamble and the PUSCH based on the indication information, and performs channel estimation and demodulation on the PUSCH by using the random access preamble; or determines a power deviation between the random access preamble and the PUSCH based on the indication information, and performs channel estimation and demodulation on the PUSCH by using the random access preamble and an additional demodulation reference signal. The communication module <NUM> is further configured to send a random access response or a contention resolution message to the terminal.

It should be noted that, in a specific embodiment of the present invention, the terminal <NUM> may be the terminal in the embodiment in <FIG>, <FIG>, <FIG>, <FIG>, <FIG>, or <FIG>, and the base station <NUM> may be the base station in the embodiment in <FIG>, <FIG>, <FIG>, <FIG>, <FIG>, or <FIG>. That is, in a specific implementation, for function implementation of each module of the terminal <NUM> and the base station <NUM>, refer to descriptions of related method steps in the foregoing embodiments. For brevity of this specification, details are not described herein again.

<FIG> shows still another apparatus <NUM> according to an embodiment of the present invention. The apparatus <NUM> is, for example, the terminal described in the embodiments of the present invention. The apparatus <NUM> includes a processor <NUM>, a memory <NUM>, and a transceiver <NUM>. The processor <NUM>, the memory <NUM>, and the transceiver <NUM> are connected to each other by using a bus <NUM>.

The memory <NUM> includes but is not limited to a random access memory (English: Random Access Memory, RAM for short), a read-only memory (English: Read-Only Memory, ROM for short), an erasable programmable read-only memory (English: Erasable Programmable Read Only Memory, EPROM for short), or a portable read-only memory (English: Compact Disc Read-Only Memory, CD-ROM for short). The memory <NUM> is configured to store related instructions and related data.

The transceiver <NUM> is configured to: receive data (for example, the higher layer signaling, the random access response, and the contention resolution message) sent by the base station, or send data (for example, send the preamble and the PUSCH) to the base station.

The processor <NUM> may be one or more central processing units (English: Central Processing Unit, CPU for short). When the processor <NUM> is one CPU, the CPU may be a single-core CPU or a multi-core CPU.

In some embodiments, the processor <NUM> in the apparatus <NUM> is configured to read program code stored in the memory <NUM>, to perform steps of a related method procedure of the terminal in the embodiment in <FIG>.

<FIG> shows still another apparatus <NUM> according to an embodiment of the present invention. The apparatus <NUM> is, for example, the base station described in the embodiments of the present invention. The apparatus <NUM> includes a processor <NUM>, a memory <NUM>, and a transceiver <NUM>. The processor <NUM>, the memory <NUM>, and the transceiver <NUM> are connected to each other by using a bus <NUM>.

The transceiver <NUM> is configured to: receive data (such as a PRACH resource and a PUSCH resource) sent by the terminal, or send data (such as send higher layer signaling, the random access response, and the contention resolution message) to the terminal.

In some embodiments, the processor <NUM> in the apparatus <NUM> is configured to read program code stored in the memory <NUM>, to perform steps of a related method procedure of the base station in the embodiment in <FIG>, <FIG>, <FIG>, <FIG>, <FIG>, or <FIG>.

In some embodiments, the processor <NUM> in the apparatus <NUM> is configured to read program code stored in the memory <NUM>, to perform steps of a related method procedure of the base station in the embodiment in <FIG>.

Based on a same inventive concept, an embodiment of the present invention provides still another apparatus. In a specific implementation, the apparatus may be a chip. The apparatus includes a processor and a memory coupled to the processor.

The memory is configured to store computer program instructions.

The processor is configured to: execute the computer program instructions stored in the memory, to calculate a first transmit power used for sending a random access preamble and a second transmit power used for sending a physical uplink shared channel PUSCH; generate indication information, to indicate a power deviation between the first transmit power and the second transmit power to a base station; receive and process a random access response or a contention resolution message from the base station.

In a possible embodiment, the chip may be coupled to a transceiver. The transceiver may be configured to send data to the base station or receive data from the base station, for example, configured to send the random access preamble to the base station at the first transmit power, and send the PUSCH to the base station at the second transmit power, and for another example, configured to receive the random access response or the contention resolution message from the base station.

In a possible embodiment, the chip may be used in a terminal. For a specific function implementation of the chip, refer to descriptions of a related function of the terminal in any embodiment in <FIG>, <FIG>, <FIG>, <FIG>, <FIG>, or <FIG>.

The processor is configured to execute the computer program instructions stored in the memory, to determine a power deviation between a first transmit power used for a random access preamble from the terminal and a second transmit power used for a PUSCH; may be configured to: demodulate the PUSCH based on the power deviation and by using the random access preamble or by using the random access preamble and an additional demodulation reference signal of the PUSCH; and may further be configured to generate a random access response or a contention resolution message for the terminal.

In a possible embodiment, the chip may be coupled to a transceiver. The transceiver may be configured to send data to the terminal or receive data from the terminal, for example, may be configured to receive the random access preamble sent by the terminal and receive the PUSCH sent by the terminal. In a possible embodiment, the transceiver is further configured to receive indication information sent by the terminal. For another example, the transceiver is further configured to send the random access response or the contention resolution message to the terminal.

In a possible embodiment, the chip may be used in a base station. For a specific function implementation of the chip, refer to descriptions of a related function of the base station in any embodiment in <FIG>, <FIG>, <FIG>, <FIG>, <FIG>, or <FIG>.

All or some of the foregoing embodiments may be implemented through software, hardware, firmware, or any combination thereof. When software is used to implement the embodiments, the embodiments may be implemented completely or partially in a form of a computer program product. The computer program product includes one or more computer instructions, and when the computer program instructions are loaded and executed on a computer, all or some of the procedures or functions according to the embodiments of the present invention are generated. The computer may be a general-purpose computer, a dedicated computer, a computer network, or another programmable apparatus. The computer instructions may be stored in a computer-readable storage medium or may be transmitted from a computer-readable storage medium to another computer-readable storage medium. For example, the computer instructions may be transmitted from a website, computer, server, or data center to another website, computer, server, or data center in a wired (for example, a coaxial cable, an optical fiber, or a digital subscriber line) or wireless (for example, infrared, radio, or microwave) manner. The computer-readable storage medium may be any usable medium accessible by a computer, or a data storage device, such as a server or a data center, integrating one or more usable media. The usable medium may be a magnetic medium (for example, a floppy disk, a hard disk, or a magnetic tape), an optical medium (for example, a DVD), a semiconductor medium (for example, a solid-state drive), or the like.

Claim 1:
A transmission method, comprising:
sending (S101), by a terminal, a random access preamble to a base station at a first transmit power, characterised by:
sending, in the same slot as the random access preamble, a physical uplink shared channel PUSCH to the base station at a second transmit power, wherein a power deviation between the first transmit power and the second transmit power is indicated (S102) to the base station by using indication information, the indication information being transmitted with the random access preamble or the PUSCH; and
receiving (S103), by the terminal, a random access response or a contention resolution message from the base station.