Reference will now be made in detail to the exemplary embodiments of the present invention with reference to the accompanying drawings. The following detailed description includes specific details in order to provide a thorough understanding of the present invention. However, it will be apparent to those skilled in the art that the present invention may be practiced without such specific details. In the following description of the present invention, a detailed description of known functions and configurations incorporated herein will be omitted when it may obscure the subject matter of the present invention.
The present invention provides a method for generating a visible frame in a VLC system. A VLC device, that corresponds to a transmitter, determines a visible frame output scheme according to various communication environments using VLC terminals, illumination or infra. The VLC device transmits the determined visible frame output scheme to a counterpart VLC device, that corresponds to a receiver. The VLC device of the receiver receives and confirms the visible frame output scheme. The VLC devices of the transmitter and receiver communicate with each other. If the VLC device of the receiver is permitted to output the visible frame, the VLC device of the receiver generates the visible frame.
The visible frame output scheme includes schemes in which only a transmitter generates a visible frame, only a receiver generates the visible frame, both the transmitter and receiver generate the visible frame, and neither the transmitter nor the receiver uses the visible frame. The visible frame may be generated when neither the transmitter nor the receiver transmits data, when a link is misaligned while the transmitter and receiver communicate with each other, or when a Nack signal occurs due to a data problem during communication between the transmitter and receiver.
The present invention proposes a visible frame output scheme considering various communication environments. Namely, a visible frame output method and device will be described in which a transmitter determines a visible frame output scheme and transmits the determined scheme to a receiver, and the receiver generates a visible frame according to the determined visible frame output scheme.
Prior to the description of the present invention, a case where a determination as to whether to generate a visible frame should be made will be described in brief.
In a Peer-to-Peer (P2P) environment of a unicast type, much power is necessary to transmit a visible frame in a VLC device. If the visible frame is selectively transmitted in need of power saving, continuous data transmission between VLC devices will be possible. This will be described in conjunction with FIG. 13 later on.
When generating a visible frame while a transmitter and a receiver do not transmit data, a VLC device other than a VLC device which receives data using time slot allocation transmits the visible frame in a Virtual Local Area Network (VLAN) environment of a unicast, multicast or broadcast type. Such transmission of the visible frame serves as interference with respect to a VLC device which is performing data communication.
Namely, a VLC device transmits the visible frame at time slots which are not allocated thereto and the transmission of the visible frame becomes interference to other VLC devices that are performing data communication. Visible frames are increased in proportion to the number of VLC devices. Accordingly, as the number of VLC devices is increased, the visible frames are increased and interference is also increased.
In a VLAN environment, if there is only one VLC device of a receiver, the VLC device operates as in a unicast type and a transmitter and the receiver can perform data communication using a visible frame without any interference. However, if two or more VLC devices of a receiver are present, the visible frame is needed to be selectively transmitted. An environment in which there are multiple VLC devices will be described in detail with reference to FIG. 5.
FIG. 5 illustrates a configuration of a VLC system according to an exemplary embodiment of the present invention. Referring to FIG. 5, a VLC system supporting multiple communication modes includes a VLC device 200 performing VLC through one or more light sources 210, 220 and 230 and includes VLC terminals 101, 102, 103, 104, 105, 106, 107, 108 and 109 each having a visible light transceiver for transmitting and receiving a visible light signal.
The multiple VLC terminals 101 to 109 transmit and receive data using time slots, such as uplink time slots and downlink time slots, allocated thereto by the VLC device 200. The respective VLC terminals 101 to 109 transmit and receive data only at time slot periods allocated thereto.
Referring to FIG. 5, the first and second user terminals 101 and 102 communicate with the first light source 210 using a first time slot TS1, the third user terminal 103 communicates with the second light source 220 using a fourth time slot ST4, the fourth user terminal 104 communicates with the second light source 220 using a second time slot ST2, the fifth user terminal 105 communicates with the second light source 220 using a third time slot TS3. The sixth and seventh user terminals 106 and 107 communicate with a third light source 230 using the first time slot ST1, the eighth user terminal 108 communicates with the third light source 230 using a fifth time slot ST5, and the ninth user terminal 109 communicates with the third light source 230 using a sixth time slot ST6.
The respective light sources 210, 220 and 230 have unique light source identifications (IDs) and transmit data received from the VLC device 200 to the VLC terminals 101 to 109 located in their service areas. The light sources 210, 220 and 230 transmit uplink data received from the VLC terminals 101 to 109 to the VLC device 200. The light sources 210, 220 and 230 periodically broadcast frame synchronization so that the VLC terminals 101 to 109 located in their service areas may establish synchronization therewith.
The VLC device 200 constructs a cell including any light source according to a user service to be provided by the light source and allocates a time slot, such as an uplink time slot or a downlink time slot, according to the user service to be provided in each cell, data, and a user located in each cell.
FIG. 6 illustrates an exemplary method for transmitting a visible frame between a transmitter 401 and a receiver 403. The transmitter 401 and the receiver 403 set up a link for communication and then the transmitter 401 transmits control information 402 to the receiver 403. The transmitter 401 transmits a visible frame 405 to the receiver 402. Meanwhile, the receiver 403 transmits an Acknowledgement (Ack) signal 407 to the transmitter 401 in response to the received control information. In this case, the transmitter 401 continues to transmit the visible frame 405 to the receiver 403 until it transmits a data frame 411. Similarly, the receiver 403 transmits a visible frame 409 to the transmitter 401 after transmitting the ACK signal 407. The receiver 403 continues to transmit the visible frame 409 to the transmitter 401 until it transmits the ACK signal transmitted in response to the reception of the data frame 411.
As described above, the transmitter 401 and the receiver 403 transmit the visible frame except when they transmit the data frame or the ACK signal, thereby ensuring the visibility of a VLC system. Namely, since the intensity of a light source of the VLC system becomes weak and thus the visibility of the VLC system is low during an information or data non-transmission interval, it may be possible to evenly maintain brightness by transmitting the visible frame. Furthermore, since the transmitter and receiver of the VLC system operate in a Line-of-Sight (LOS) communication environment, the visible frame may be transmitted even during the misalignment of the transmitter and receiver and upon occurrence of a Nack signal for the data transmission of the transmitter and receiver.
However, since the visible frame which is not related to data is transmitted during a data non-transmission interval, energy consumption of a terminal may be increased. As illustrated in FIG. 7, in a VLC system for providing services to multiple users by dividing a communication frame into time slots in order to accommodate multiple users, the visible frame is transmitted during a data non-transmission interval, thereby resulting in interference with another terminal user.
FIG. 7 illustrates a VLC system using virtual time slots for accommodating multiple users.
Referring to FIG. 7, there is illustrated a system which is connected to an access point 503 and can perform communication using a network, especially a system which provides a network accessible service through VLC such as an illumination in a VLC device 501. Alternatively, the VLC device 501 may be a system equipped with a transceiver which can perform VLC such as an illumination. Assuming that there are user terminals U1, U2, U3, U4, U5 and U6 which are accessible to a network using the VLC device 501, a first area 509 becomes a light source area of a cell unit which can perform VLC. Each of the user terminals in the first area 509 is connected to the VLC device 501 at a virtual time slot (vs) which is a communication time allocated thereto.
The VLC device 501 includes a visible light transceiver for transmitting and receiving a visible light signal, and a controller for determining a visible frame output scheme considering a VLC environment and for controlling the visible light transceiver to transmit the visible frame output scheme to a counterpart VLC device.
For VLC, time slots are allocated to the respective terminals based on a communication frame 507 used in the VLC system. A second area 505 illustrates a multicast communication environment in which multiple terminals U1, U2 and U3 communicate with a light source using one time slot ‘vs n’. When the terminals U4, U5 and U6 performs communication using time slots ‘vs n+1’, ‘vs n+2’ and ‘vs n+n’ of the communication frame 507, respectively, the VLC device 501 should transmit the visible frame output scheme in consideration of interference with other user terminals. The possible case where the visible frame is transmitted is when a transmitter and a receiver do not transmit data, when the transmitter and receiver are misaligned, or when the transmitter and receiver generate a Nack signal.
After multiple user terminals in the second area 505 perform communication using the same time slot ‘vs n’ in FIG. 7, if a user terminal, that is, the terminal U4 using the next time slot ‘vs n+1’ performs communication, the terminals in the second area 505 transmit a visible frame and thus may cause interference with the terminal U4. Namely, the transmission of the visible frame by the multiple terminals in the second area 505 under the state that the VLC device 501 transmits data to the terminal U4 at the time slot ‘vs n+1’ generates uplink interference with respect to the user terminal U4 and interrupts communication of the terminal U4.
In the above process, the terminals U5 and U6 which do not participate in communication at a time slot during which the terminal U4 performs communication transmit the visible frame, like the terminals in the area 505. As the number of terminals in a cell which transmit the visible frame is increased, the amount of interference is also increased. When the VLC device 501 provides a downlink service to the terminal U5 at the next time slot ‘vs n+2’, the terminals in the second area 505 using the time slot ‘vs n’, the terminal U4 using the time slot ‘vs n+1’, and the terminal U6 using the time slot ‘vs n+n’ do not transmit data and transmit the visual frame in an uplink direction, thereby generating communication interference with the terminal U5.
The above method for transmitting the visible frame when no data is transmitted has a disadvantage because uplink interference is increased in proportion to the number of user terminals transmitting the visible frame. Moreover, when the terminal U1 generates a Nack signal or a misaligned state while the multiple terminals in the second area 505 perform communication using the same time slot, the VLC device 501 should transmit the visible frame to the terminal U1 but does not need to transmit the visible frame to the other user terminals U2 and U3. Therefore, a method for transmitting the visible frame according to a VLC environment is demanded.
The following Table 1 lists a method for determining a visible frame transmission scheme in a visible communication environment.
Referring to Table 1, when no data is transmitted in a VLC system that communicates on a time slot basis, since the transmission of the visible frame creates interference with respect to other users, it may be desirable not to transmit the visible frame. Further, the transmission of the visible frame when no data is transmitted increases the power consumption of a terminal. Accordingly, in a communication system based on a time slot, transmission prohibition of the visible frame may be applied when no data is transmitted.
In a communication system using an illumination environment, when a transmitter and a receiver are misaligned or generate a Nack state, since a light source does not have an illumination effect according to an on/off phenomenon of light caused by the transmission of the visible frame, a light source of a transmitter should be limited not to transmit the visible frame. In the case of misalignment state of the transmitter and receiver, the transmission of the visible frame is limited for unicast (UCAST), multicast (MCAST) and broadcast (BCAST) to reduce interference with respect to other terminals. The transmission prohibition of the visible frame may be applied in any VLC environment.
Accordingly, in a VLC system using an illumination, it is necessary to control a receiver to or not to transmit the visible frame.
A VLC system using P2P may have a construction for transmission between terminals and for infra such as a kiosk. Since a kiosk system is an infra system which can be constructed using P2P, interference with other users should be considered when transmitting a visible frame. Table 2 shows a method for transmitting a visible frame according to a communication environment. Since a kiosk system can communicate with other users using infra, the transmission of the visible frame is not permitted in consideration of interference with other users but the visible frame may be transmitted in P2P. The transmission of the visible frame when no data is transmitted in a communication environment between terminals using P2P increases the power consumption of a terminal and thus a method for reducing the power consumption of the terminal using the transmission limitation of the visible frame is required. Accordingly, it is necessary to selectively apply the transmission of the visible frame according to a communication environment as shown in Table 2. In Table 2, a method for applying the transmission of the visible frame is as in Table 1.
In P2P, when a transmitter transmits data to a receiver, if the receiver does not transmit data and therefore transmits a visible frame, the visible frame causes interference during a data transmission interval of the transmitter. Namely, in FIG. 7, when a transmitter 513 transmits a data frame to a receiver 515, the receiver 515 transmits a visible frame because it does not transmit data.
However, since the visible frame transmitted by the receiver 515 is transmitted while the transmitter 513 transmits the data frame to the receiver 515, the visible frame functions as an interference source with respect to the data frame transmitted by the transmitter 513. In P2P, the transmission of the visible frame may be selected according to a user and a communication environment. Since the transmission of the visible frame while data is not transmitted in P2P may generate interference, the transmitter and receiver may determine a method for transmitting the visible frame to perform effective communication. Accordingly, frames as shown in FIGs. 8(a) and 8(b) may be used to transmit information, that is, a visible frame transmission scheme, indicating whether to use the visible frame.
FIGs. 8(a) and 8(b) illustrate frame structures used in VLC according to an exemplary embodiment of the present invention. FIG. 8(a) illustrates a frame structure of a time slot allocation scheme for multiple users in VLC according to an exemplary embodiment of the present invention, and FIG. 8(b) illustrates a simplified form of the frame structure shown in FIG. 8(a) when communication is performed in a unicast communication mode.
Referring to FIG. 8(a), a frame used for VLC according to an exemplary embodiment of the present invention includes a beacon field 710 having information for the synchronization and frame interpretation of a transmitter and a receiver, a management field 720 having management information for VLC, and a data frame 730 having data.
The beacon field 710 includes a preamble 711, a header 712, a Header Check Sequence (HCS) 713, a Protocol Data Unit (PDU) 714 and a Frame Check Sequence (FCS) 715. The preamble 711 includes information for determining whether a VLC frame 700 is to perform communication using a plurality of time slots. Accordingly, a receiver receiving the VLC frame 700 may check the preamble 711 of the beacon field 710 when receiving the frame. If time slots are not used, the receiver interprets the frame as a frame form shown in FIG. 8(b).
The management field 720 includes a preamble 721, a header 722, an HCS 723, a Medium Access Control (MAC) header 724, a PDU 725 and an FCS 726. The MAC header 724 includes mode type information indicating whether a communication mode is a unicast mode, a broadcast mode, or a multicast mode, and information indicating a visible frame output device.
The data frame 730 includes one contention slot 731, downlink virtual slots 732-1,..,732-n of a prescribed number, and uplink virtual slots 733-1,…,733-n of a prescribed number. The virtual slots 732-1,…,732-n and 733-1,…,733-n are individually allocated to a plurality of users during an operation of a communication mode as a multicast or broadcast mode.
Each of the virtual slots 732-1,…,732-n and 733-1,…,733-n includes a preamble 741, a header 742, an HCS 743 and a data field 744. The data field 744 includes a MAC header 751, and pairs of a plurality of PDUs 752 and a plurality of FCSs 753.
Referring to FIG. 8(b), a VLC frame in a unicast communication mode, for example, in P2P communication includes a preamble 741, a header 742, an HCS 743 and a data field 744. The header 742 shown in FIG. 8(b) has a structure shown in FIG. 14 and includes information about a visible frame transmission scheme. The data field 744 includes a MAC header 751, and pairs of a plurality of PDUs 752 and a plurality of FCSs 753.
FIG. 9 illustrates a frame structure for applying Table 1 and Table 2 to the frame structures of FIGs. 8(a) and 8(b). FIG. 10 illustrates a detailed structure of a data frame shown in FIG. 9, and FIG. 11 illustrates a detailed structure of a visible frame shown in FIG. 9. In FIG. 9, frames 755 and 757 are frames showing a method for applying the visible frame described in Table 1 by dividing a frame into time slots to support multiple users. A terminal to which a time slot is allocated should reduce interference with other users by transmitting a visible frame during the allocated time slot. If the visible frame is transmitted while no data is transmitted, since interference between terminals occurs due to the transmission of the visible frame at non-allocated time slots, a method is needed for transmitting the visible frame according to a communication environment.
In FIG. 9, the visible frame transmission scheme described in Table 2 is shown. As in frames 759 and 761, a visible frame is transmitted over the entire transmission frame. In this case, since the length of the visible frame is long, the transmission of visible frame at an interval during which a terminal does not transmit data increases the dissipated power of the terminal. Therefore, the selective transmission of the visible frame is required.
FIGs. 10 and 11 have the same usage as FIGs. 8(a) and 8(b). FIG. 10 shows a structure in which a frame is divided into time slots allocated to multiple user terminals. FIG. 11 shows a structure in which a frame is not divided into time slots and may be applied to a communication environment such as P2P.
According to an exemplary embodiment of the present invention, in a P2P environment of a unicast type, if any one VLC device determines a visible frame transmission scheme indicating whether to permit the transmission of a visible frame and transmits the determined visible frame transmission scheme, a VLC device receiving the determined visible frame transmission scheme uses or does not use the visible frame at an interval during which data is not transmitted according to the determined visible frame transmission scheme.
Meanwhile, in a VLAN environment using time slots, a receiving VLC device can use a visible frame only when a transmitting VLC device permits to transmit the visible frame. If there are a plurality of receiving VLC devices, brightness of visible frames may be adjusted to reduce interference. In more detail, as the number of receiving VLC devices within the cell is increased, brightness of visible frames may be adjusted to be low. The adjustment of brightness will be described with reference to FIG. 12.
FIG. 12 illustrates visible frame patterns transmitted within a visible frame. In each pattern, ‘%’ indicates brightness of the pattern. As ‘%’ is increased, the brightness of the visible frame is increased and the power consumption of a terminal is also increased. When the visible pattern within the visible frame is constructed as shown in FIG. 12, a visible pattern ‘11111 11111’ shows the brightest pattern.
Brightness depends on how many 1s the visible frame has. As shown in Table 1 and Table 2, if a visible frame transmission scheme at an interval during which data is not transmitted is applied to a time slot frame communication service considering multiple users, for example, a VLAN communication service, a frame pattern of high brightness generates more interference than a frame pattern of low brightness. If multiple terminals use visible frames, the sum of outputs of visible frames transmitted by the terminals appears in a light source, and therefore interference is increased.
As illustrated in FIG. 7, if the terminals in the second area 505 transmit visible frames while they do not transmit data at a time slot allocated to other terminals, since the sum of brightness of the visible frames at the time slot allocated to other terminals functions as interference with respect to other terminals, the amount of interference is increased. Such uplink interference due to the visible frames transmitted by the terminals in the second area 505 operates as visible frame reflection interference with respect to the other user terminals U4, U5 and U6.
A VLC system uses one of the visible frame patterns shown in FIG. 12. As the frame pattern approximates to ‘11111 11111’, the strength of light is increased, the power consumption of a terminal is increased, and interference with other user terminals is increased in a VLC environment using time slots.
Accordingly, in a VLC environment having multiple users in a cell, a visible frame pattern having low brightness may be allocated during the transmission of a visible frame, thereby reducing interference.
As shown in Table 1, a VLC system constructing multiple users by dividing a frame into time slots, interference is reduced and simultaneously the power consumption of a terminal is decreased by lowering the brightness of a visible frame pattern. More specifically, multiple user terminals within a VLC cell that transmit visible frames while data is not transmitted may reduce interference with a terminal, which is transmitting and receiving data, by adjusting brightness of each terminal. Such a brightness adjustment method may be also applied in a P2P communication environment mode.
In FIG. 12,’%’ of each visible frame pattern denotes the brightness of the pattern. A visible frame pattern ‘00000 00000’ does not mean that no visible frames are transmitted. The visible frame pattern ‘00000 00000’ is filled in the visible frame 761 shown in FIG. 9 and is transmitted together with the management frame 720. This is different from a meaning that the transmission of the visible frame is limited. Namely, the limitation of the visible frame means that the visible frame is not transmitted. The visible frame pattern ‘00000 00000’ shown in FIG. 12 represents the transmission of the visible frame having low brightness.
When many terminal users are present in a VLC cell, a visible frame pattern ‘11001 11100’ may be used. When the number of terminals is small and only P2P is considered, a visible frame pattern ‘11111 11111’ having high brightness may be transmitted to effectively reduce interference.
FIG. 12 shows an example of a method for applying a visible frame in such an interference environment. When a visible frame is applied in a communication environment shown in Table 1, low brightness from bits ‘0101 0000’ to ‘0000 0000’ is applied to a multi-terminal communication mode. When interference between terminals is low or no interference occurs, high brightness from bits ‘0110 0100’ to ‘0101 1010’ is applied to a P2P communication mode.
In FIG. 12, an application mode of the visible frame may vary according to a communication environment. Accordingly, a visible pattern having low brightness while reducing interference may be applied to reduce the power consumption of a terminal.
While the brightness adjustment method has been described to reduce interference with other terminals, a method for selectively transmitting a visible frame may be used. This method is to reduce the power consumption of terminals using a power saving mode or a sleep mode and to reduce interference with other terminals during the transmission of the visible frame in a VLC system.
When applying a visible frame pattern, brightness may be expressed as an ID or a bit as shown in FIG. 14 and 15. Namely, brightness of 100% may be expressed as ID 1 (0001), brightness of 90% as ID 1 (0010), brightness of 80% as ID 1 (0011), brightness of 70% as ID 1 (0100), brightness of 60% as ID 1 (0101), brightness of 50% as ID 1 (0110), brightness of 40% as ID 1 (0111), brightness of 30% as ID 1 (1000), brightness of 20% as ID 1 (1001), brightness of 10% as ID 1 (1010), and brightness of 0% as ID 1 (1011).
Hereinafter, a case where one terminal performs VLC with two or more other terminals as illustrated in FIG. 13 will be described.
FIG. 13 illustrates multiple simultaneous association according to an exemplary embodiment of the present invention. In FIG. 13, multiple simultaneous association refers to P2P communication denoted by reference numerals 915 and 920 performed by one terminal 900 with two or more terminals 905 and 910.
When the first terminal 900 transmits and receives data with the second terminal 905, if the third terminal 910 transmits a visible frame, interference occurs in a link between the first and second terminals 900 and 905. In such a multiple simultaneous association environment, the first terminal 900 may designate the transmission of visible frames of the second and third terminals 905 and 910. That is, the first terminal 900 may select the transmission of visible frames of the second and third terminals 905 and 910 using a field ‘VF info type’ shown in FIGs. 14, 15 and 11. In other words, it is possible to selectively transmit the visible frame.
The ‘VF info type’ information set by the first terminal 900 is applied to the second terminal 905 and has no relation to the transmission of the visible frame of the first terminal 900 which is a transmitter. Accordingly, although the first terminal 900 transmits the visible frame, the second terminal 905 may or may not transmit the visible frame according to the ‘VF info type’ information set by the first terminal 900. On the contrary, even though the first terminal 900 does not transmit the visible frame, the second terminal 905 may or may not transmit the visible frame according to the ‘VF info type’ set by the first terminal 900. Thus, since the second terminal 905 determines whether to transmit the visible frame according to the ‘VF info type’ information irrespective of whether the first terminal 900 transmits the visible frame, the second terminal 905 does not need to recognize whether the first terminal 900 of a transmitter transmits the visible frame.
The above selective visible frame transmission method can reduce uplink interference generated when a communication service is provided to multiple users using time slots and can reduce power consumption.
FIG. 14 illustrates control header information. A schema of the control header information is as follows. In data transmission and reception between the first and second terminals 900 and 905, a transmitter ID denotes an ID of a terminal which transmits data. If the first terminal 900 transmits data, an ID of the first terminal 900 is set as the transmitter ID and an ID of the second terminal 905 is set as a receiver ID. The terminal transmitting data may use the selective visible frame transmission method.
In FIG. 14, a frame length corresponds to a length for the transmission of a visible frame. When considering resource allocation in units of time slots in FIGs. 6 and 9, a visible frame should be used according to time slots instead of using the entire visible frame as shown in the frames 759 and 761 in FIG. 9.
In FIG. 14, a visible frame pattern may vary according to a communication environment as shown in FIG. 12 or a fixed visible frame pattern may be used. A visible information type ‘VF info type’ is set to one bit and indicates whether to permit a terminal receiving data to transmit a visible frame. For example, when the second terminal 905 receives data from the first terminal 900 in FIG. 13, if the visible frame information type ‘VF info type’ is set to 1, the second terminal 905 recognizes that the transmission of a visible frame to the first terminal 900 is permitted and transmits the visible frame at an interval during which the second terminal 905 does not transmit data to the first terminal 900. If the visible frame information type ‘VF info type’ is set to 0, the second terminal 905 recognizes that the transmission of the visible frame to the first terminal 900 is prohibited and does not transmit the visible frame. In FIG. 14, an example using the visible frame information type of one bit to indicate whether to permit a terminal receiving data to transmit the visible frame is shown but it is apparent that various modifications are possible.
For example, the visible frame information type of 2 bits expressed as 10, 01, 11 and 00 may be designated to indicate methods in which only a transmitter uses a visible frame, only a receiver uses the visible frame, both the transmitter and receiver use the visible frame, and the visible frame is not used. FIGs. 16 and 17 show frame structures illustrating transmission of a transmitter and a receiver, respectively. Namely, FIG. 16 shows a downlink frame and FIG. 17 shows an uplink frame in the time slot structure in which a transmitter uses a downlink and a receiver uses an uplink as shown in FIG. 8(a). FIGs. 16 and 17 may be applied to a frame structure in which the uplink and downlink are not divided as shown in FIGs. 14 and 15. FIGs. 14 to 17 may be applied to beacon information, control information, and information about a Mobile Station (MS) ID (user terminal ID) or a specific user.
FIG. 18 illustrates a frame structure showing another application of FIG. 14. The frame structure of FIG. 18 is a structure of the management field 720 in FIG. 6. As illustrated in FIG. 18, the frame structure defines a frame length, a frame pattern and a visible frame information type and shows a method for variously applying a visible frame. In FIG. 18, MS ID may be optional. For example, when the first terminal 900 and the second terminal 905 communicate with each other, since they are able to know their counterpart, the MS ID may be unnecessary. However, the first terminal 900 communicates with the third terminal 910 while communicating with the second terminal 905, the MS ID for identifying each terminal may be necessary. Accordingly, the MS ID may be designated in consideration of such a case. FIG. 19 is a flow chart illustrating an operation of a transmitter for transmitting a visible frame. FIG. 20 is a flow chart illustrating an operation of a receiver for transmitting a visible frame. The operation of the receiver is similar to the operation of the transmitter and therefore a detailed description thereof will be omitted.
Referring to FIG. 19, a receiver initially accesses a transmitter in step 1101. The transmitter and receiver are synchronized and a transmitter allocates time slot resources for communication in step 1103. The transmitter determines a visible frame transmission scheme in step 1105. In this case, the transmitter determines whether the transmitter is to transmit the visible frame, the receiver is to transmit the visible frame, both the transmitter and receiver are to transmit the visible frame, or neither the transmitter and no the receiver is to use the visible frame. The above process may be determined by a terminal user or by the transmitter according to a VLC environment (illumination, P2P, infra, etc.).
The transmitter judges whether to determine brightness of the visible frame during the transmission of the visible frame according to a communication environment in step 1107. If fixed brightness is used, the transmitter transmits the visible frame transmission scheme to the receiver in step 1109. The transmitter receives an ACK signal for the visible frame transmission scheme from the receiver in step 1111 and exchanges the visible frame with the receiver in step 1113.
Meanwhile, if the transmitter determines that the brightness of the visible frame should be changed according to a communication environment in step 1107, the transmitter transmits the visible frame transmission scheme and visible frame brightness to the receiver in step 1115. The transmitter receives an ACK signal for the visible frame transmission scheme and visible frame brightness from the receiver in step 1117. The transmitter exchanges the visible frame with the receiver in step 1119. The transmitter determines whether there is need of changing the brightness of the visible frame due to interference caused by an increase of users in a VLC environment or other reasons in step 1121.
If the transmitter determines that the brightness of the visible frame should be changed, the transmitter changes the brightness of the visible frame in step 1125 and transmits information about a change of the brightness of the visible frame to the receiver in step 1127. The transmitter receives an ACK signal for the information about a change of the brightness of the visible frame from the receiver in step 1129. The transmitter exchanges the visible frame with the receiver in step 1131. Meanwhile, if there is no need to change the brightness of the visible frame in step 1121, the transmitter exchanges the visible frame having changed brightness with the receiver using the previous brightness of the visible frame in step 1123.
The information about a change of the visible frame and the information about the selection of the brightness of the visible frame use the visible frame pattern shown in FIGs. 9 to 17. FIGs. 9 to 17 illustrate the frame structures showing examples for applying the visible frame. The visible frame information may be exchanged using various transmission frames or signals.
In the above description, a brightness adjustment method has been made for reducing interference generated when the transmitter permits the receiver to transmit the visible frame in a VLC environment of a time slot scheme.
Hereinafter, a process for determining a visible frame transmission scheme and performing communication according to the determined visible frame transmission scheme will be described when any one terminal communicate with another terminal one-to-one as shown in FIG. 13.
FIG. 21 is a flow chart illustrating an operation of a VLC device for determining and transmitting a visible frame transmission scheme, and FIG. 22 is a flow chart illustrating an operation of the VLC device for receiving the determined visible frame transmission scheme and performing communication according to the received visible frame transmission scheme.
Referring to FIG.21, steps 1401 to 1405 are the same as steps 1101 to 1105 shown in FIG.19. If the visible frame transmission scheme is determined, a transmitter transmits the visible frame transmission scheme to a receiver in step 1407. The transmitter performs communication according to the determined visible frame transmission scheme in step 1409. Namely, if the transmitter permits the receiver to transmit the visible frame, the transmitter receives the visible frame from the receiver while data is not transmitted. If the transmitter does not permit the transmission of the visible frame, the transmitter does not receive the visible frame irrespective of the transmission of data.
The operation of the receiver receiving the visible frame transmission scheme is shown in FIG. 22. Referring to FIG. 22, steps 1501 to 1503 are the same as steps 1201 to 1203 in FIG. 20. If the visible frame transmission scheme is received from the transmitter in step 1505, the receiver confirms the visible frame transmission scheme in step 1507. The receiver determines whether it is possible to use the visible frame in step 1509. If the visible frame can be used, that is, if the transmitter permits the receiver to transmit the visible frame, the receiver exchanges the visible frame with the transmitter in step 1511. If the transmitter does not permit the transmission of the visible frame, the receiver performs communication without using the visible frame in step 1513.
Although the exemplary embodiments of the present invention have been disclosed for illustrative purposes, various modifications, additions and substitutions are possible, without departing from the scope and spirit of the invention as disclosed in the accompanying claims. Accordingly, the scope of the present invention should not be limited to the description of the embodiment, but defined by the accompanying claims and equivalents thereof.