JP2007116209A - Radio lan device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a radio LAN device capable of suppressing power consumption by changing/optimizing data processing speed in the device according to the transmission speed of data to be transmitted and received. <P>SOLUTION: A local CPU 11 changes the clock signal of clock generation circuits 22-25, thus changing the data processing speed of a MAC 12, a PLCP 13, an AD/DA circuit 14, and an RF circuit 15 according to the transmission speed of the data to be transmitted and received being determined by the state of radio waves, or the like. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to a wireless LAN device, and more particularly to power saving of the wireless LAN device.

In recent years, wireless LANs have become widespread as means for connecting to networks. A standard of the wireless LAN system is, for example, IEEE 802.11, and this standard has a power management function for suppressing power consumption of the system. In one function of power management, the system state is an awake state in which power is completely supplied to the transmission / reception circuit and transmission / reception is possible, and a dose (DOZE) in which transmission / reception is impossible by operating with a minimum amount of power. The power consumption is suppressed by defining two states of the (pause) state and switching between the awake state and the doze state as necessary.
The standard also allows radio stations to support multiple transmission rates, and the radio transmission rate can be changed according to the communication status such as the distance from the base station to the terminal station and the influence of disturbance. It is possible. Normally, when a terminal station receives beacon and probe response management frames transmitted from a base station (terminal station participating in the network when the network is in ad hoc mode) when joining the network, the terminal station wirelessly uses the signal strength. The base station (or other terminal stations participating in the network when the network is in the ad hoc mode) is notified by a support frame that is a component of the association request transmitted when participating in the network. Then, after joining the network, wireless communication is performed when transmitting from the support frame notified according to the change in the signal strength of the frame received from the base station (or other terminal station participating in the network when the network is in the ad hoc mode). Determine the transmission rate. Usually, the signal strength is detected by the intensity of the received radio wave, and the transmission speed is determined by the installed firmware program.

FIG. 16 is a block diagram showing a main configuration of a conventional wireless LAN device.
In the figure, 1 is a wireless LAN device, 2 is an antenna for wireless communication with a wireless LAN system 1 such as another STA (Station) or AP (Access Point), 3 is a main CPU of a user circuit, Reference numeral 4 denotes a memory, and reference numeral 5 denotes a bus that connects the main CPU 3 of the user circuit to the wireless LAN device 1, the memory 4, and other interfaces such as communication. A user circuit is a circuit of a device to which a wireless LAN device is connected. For example, when a wireless LAN device (for example, a wireless LAN board) is connected to a personal computer (hereinafter abbreviated as a PC), the circuit of the PC is used. Is the user circuit.
The wireless LAN device 1 includes a baseband unit 10 and an RF (high frequency) unit 9. In the baseband unit 10, 11 is a local CPU, 12 is a MAC (Medium Access Control), 13 is a PLCP (Physical Layer Convergence Protocol), 14 is an AD / DA circuit, and 16 is equipped with firmware for operating the local CPU 11. Reference numeral 17 denotes a work RAM of the local CPU 11, 18 denotes an I / F (interface) circuit with a device to which the wireless LAN device 1 is connected, and 21 to 24 denote clock generation circuits that supply the circuits 11 to 14. As for the RF unit 9, 15 is an RF circuit, and 25 is a clock generation circuit of the RF circuit 15.
Next, the operation of each module in the wireless LAN device 1 will be described. First, regarding the procedure for transmitting user circuit data from the wireless LAN device 1 as a data frame, the main CPU 3 of the user circuit transmits the data to the MAC 12 via the I / F circuit 18 from the memory 4 on the bus 5 or another module (not shown). Output data. In the MAC 12, management data (header) determined by the standard is added to transmission data input from the user circuit, and further, data encryption processing and fragment processing (data subdivision) as necessary. The data frame is converted into a data frame conforming to the wireless LAN standard and output to the PLCP 13. The PLCP 13 modulates the data frame input from the MAC 12 by a method determined for each transmission speed by the wireless LAN standard, and outputs the modulated data frame to the AD / DA circuit 14. The AD / DA circuit 14 converts the digital signal of the modulated data frame input from the PLCP 13 into an analog signal and outputs the analog signal to the RF circuit 15. The RF circuit 15 performs processing such as amplification and frequency conversion on the data frame converted into an analog signal by the AD / DA circuit 14 and transmits the data frame from the antenna 2.

Next, a procedure for outputting the data frame received by the wireless LAN device 1 as data to the user circuit will be described. An analog signal of a data frame transmitted from a wireless LAN system such as another STA or AP input to the antenna 2 is subjected to processing such as amplification and frequency conversion by the RF circuit 15 and output to the AD / DA circuit 14. The AD / DA circuit 14 converts the analog signal input from the RF circuit 15 into a digital signal and outputs the digital signal to the PLCP 13. The PLCP 13 demodulates the signal input from the AD / DA circuit 14 by a method determined for each transmission speed of the wireless LAN standard, and outputs the demodulated signal to the MAC 12. In the MAC 12, the data frame input from the PLCP 13 is subjected to data decoding processing and defragment processing (reconstruction of fragmented data) based on management data (header), and finally the I / F The data is output as data to the memory 4 on the bus 5 or another module (not shown) via the circuit 18.
In addition to the processing related to the data frame, the MAC 12 also performs processing such as control frame generation / transmission / reception processing for controlling the wireless LAN, and time management related to the timing of data transmission based on the received control frame. Do. Control frame transmission / reception operations are the same as the operations of the MAC 12, PLCP 13, AD / DA circuit 14, and RF circuit 15 for transmitting and receiving data frames. The MAC 12 also performs the power management function described above.
The local CPU 11 is connected to the main CPU 3 of the user circuit via the bus 5 of the user circuit, while the MAC 12, PLCP 13, AD / DA circuit 14, RF circuit 15, memory 16 with firmware and work RAM 17 are also dedicated or They are connected by a common bus (dedicated bus in the figure), and control the operation of each module based on an instruction from the main CPU 3 or firmware loaded in the memory 16. In particular, the MAC 12 may perform many processes such as setting, interrupt processing, error processing, fragment processing, and defragment processing. Here, the work RAM 17 is used for the purpose of temporarily storing data when the local CPU 11 performs processing on the MAC 12.
By the way, regarding the suppression of power consumption in wireless communication, it is possible to supply power from an external power source and a battery (secondary battery), and in an electronic device having a plurality of wireless means with different power consumption, depending on the power supplied. There is also an electronic device that operates by switching wireless means (see, for example, Patent Document 1).
JP 2004-227438 A

However, in the conventional wireless LAN system, the data processing speed of the system is constant regardless of the transmission speed. For this reason, even when the transmission speed is low and the data processing speed of the system may be low, the system is operated at the same data processing speed as when the transmission speed is high, which consumes more power than necessary.
Further, in the conventional wireless LAN system, the transmission speed set by the firmware may not necessarily be a transmission speed that matches the usage status of the user of the device connected to the wireless LAN system. For example, when operating on a battery, the wireless transmission speed may be lowered, so even if you want to keep the power consumption low, using the wireless transmission speed as high as possible consumes more power than necessary. Even if the radio wave condition is unstable, by setting the wireless transmission speed as high as possible, the rate at which the reception side frequently receives errors and becomes unable to receive normally increases, resulting in a decrease in throughput. There was a problem to do.
Further, the method of Patent Document 1 requires a plurality of wireless means, and there are problems in both the size and cost of the apparatus.
The present invention has been made in consideration of the above-described circumstances, and can reduce power consumption by changing and optimizing the data processing speed in the apparatus according to the transmission speed of data to be transmitted and received. An object of the present invention is to provide a simple wireless LAN device.
Another object of the present invention is to enable the user to change the transmission speed in preference to the wireless transmission speed set by the firmware of the wireless LAN device. It is an object of the present invention to provide a wireless LAN device capable of suppressing power consumption and improving data transmission throughput.

In order to solve the above-described problem, the invention according to claim 1 is a wireless LAN device that includes a baseband unit and an RF unit, and transmits and receives data by connecting to another device. Of the baseband unit and the RF unit including the local CPU according to the transmission speed of the data transmitted and received by the local CPU wirelessly. Data processing speed changing means for changing the data processing speed is provided.
According to a second aspect of the present invention, in the wireless LAN device according to the first aspect, the data processing speed changing means changes the clock signal generated by the clock generating means and sends the changed clock signal to the baseband unit. And supplying to some or all modules of the RF unit.
According to a third aspect of the present invention, in the wireless LAN device according to the second aspect, the data processing speed changing means changes the data processing speed by changing a frequency dividing ratio of the clock signal generated by the clock generating means. It is characterized by doing.
According to a fourth aspect of the present invention, in the wireless LAN device according to the second aspect, the data processing speed changing means changes the data processing speed by thinning out a clock signal generated by the clock generating means. To do.
According to a fifth aspect of the present invention, in the wireless LAN device according to the second aspect, the data processing speed changing means changes the data processing speed by changing an output frequency of a clock generator of the clock generating means. Features.
According to a sixth aspect of the present invention, in the wireless LAN device according to the first aspect, the data processing speed changing means changes the number of circuits operating in parallel to change the data processing speed.

According to a seventh aspect of the present invention, in the wireless LAN device according to any one of the first to sixth aspects, the control means does not change the data processing speed in accordance with a power supply state. It is characterized by controlling to.
According to an eighth aspect of the present invention, in the wireless LAN device according to any one of the first to sixth aspects, the control means changes the data processing speed according to a CPU usage rate of the other device. It is characterized by controlling not to perform.
The invention according to claim 9 is a wireless LAN device having a baseband unit and an RF unit, and having setting means for setting a data transmission rate according to a communication state when transmitting and receiving data, It is characterized by comprising control means for controlling transmission / reception operations and switching means for changing the set data transmission rate.
Further, the invention of claim 10 displays the effective transmission rate when there are a plurality of transmission rate candidates and valid / invalid of the transmission rate to be changed by the switching means in the wireless LAN device of claim 9. A display means is provided.
The invention according to claim 11 is the wireless LAN device according to claim 10, wherein the display means displays the valid / invalid of the transmission rate and the effective transmission rate by lighting the light emitter.
The invention of claim 12 is used by connecting to another device, has a baseband unit and an RF unit, and sets the data transmission speed according to the communication state when transmitting and receiving data. A switching means for changing a transmission rate of the set data, and a control means for controlling a transmission / reception operation, wherein the control means is connected to the connected apparatus by the switching means. In this case, the effective transmission rate is notified when there are a plurality of transmission rate candidates.

  According to the present invention, it is possible to provide a wireless LAN device that can perform communication at a wireless transmission speed in accordance with the use situation and can operate with low power consumption.

Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.
FIG. 1 is a block diagram showing a main configuration of a wireless LAN device according to the present invention.
In the figure, 1 is a wireless LAN device, 2 is an antenna for the wireless LAN device 1 to wirelessly communicate with a wireless LAN system such as another STA or AP, 3 is a main CPU of a user circuit, 4 is a memory, 5 Is a bus that connects the main CPU 3 of the user circuit to the wireless LAN device 1, the memory 4, and other interfaces such as communication. The user circuit is a circuit of a device to which a wireless LAN device is connected. For example, when the wireless LAN device is connected to a PC, the PC circuit is a user circuit. In this embodiment, the wireless LAN device 1 is in the form of a LAN board or a LAN card that is inserted into a PC slot for use. However, the present invention is not limited to this, and a router or wireless LAN access point is used. It may be a part of a wireless LAN system such as (AP).
The wireless LAN device 1 includes a baseband unit 10 and an RF unit 9. In the baseband unit 10, 11 is a local CPU, 12 is a MAC, 13 is a PLCP, 14 is an AD / DA circuit, 16 is a memory equipped with firmware for operating the local CPU 11, 17 is a work RAM of the local CPU 11, 18 Is an I / F (interface) circuit with a device to which the wireless LAN device 1 is connected, and 21-24 are clock generation circuits for each of the circuits 11-14. As for the RF unit 9, 15 is an RF circuit, and 25 is a clock generation circuit of the RF circuit 15.
The local CPU 11 is connected to a common bus with the clock generation circuits 22 to 25, and performs data processing of the MAC 12, the PLCP 13, the AD / DA circuit 14, and the RF circuit 15 according to the transmission speed of data to be transmitted / received determined by a radio wave state or the like. The speed is changed by changing the clock frequency of the clock generation circuits 22-25.
Next, the operation of each module in the wireless LAN device 1 will be described. First, regarding the procedure for transmitting user circuit data from the wireless LAN device 1 as a data frame, the main CPU 3 of the user circuit transmits the data to the MAC 12 via the I / F circuit 18 from the memory 4 on the bus 5 or another module (not shown). Output data. In the MAC 12, management data (header) determined by the standard is added to transmission data input from the user circuit, and further, data encryption processing and fragment processing (data subdivision) as necessary. The data frame is converted into a data frame conforming to the wireless LAN standard and output to the PLCP 13. The PLCP 13 modulates the data frame input from the MAC 12 by a method determined for each transmission speed by the wireless LAN standard, and outputs the modulated data frame to the AD / DA circuit 14. The AD / DA circuit 14 converts the digital signal of the modulated data frame input from the PLCP 13 into an analog signal and outputs the analog signal to the RF circuit 15. The RF circuit 15 performs processing such as amplification and frequency conversion on the data frame converted into an analog signal by the AD / DA circuit 14 and transmits the data frame from the antenna 2.

Next, a procedure for outputting the data frame received by the wireless LAN device 1 as data to the user circuit will be described.
An analog signal of a data frame transmitted from a wireless LAN system such as another STA or AP input to the antenna 2 is subjected to processing such as amplification and frequency conversion by the RF circuit 15 and output to the AD / DA circuit 14. The AD / DA circuit 14 converts the analog signal input from the RF circuit 15 into a digital signal and outputs the digital signal to the PLCP 13. The PLCP 13 demodulates the signal input from the AD / DA circuit 14 by a method determined for each transmission speed of the wireless LAN standard, and outputs the demodulated signal to the MAC 12. In the MAC 12, the data frame input from the PLCP 13 is subjected to data decoding processing and defragment processing (reconstruction of fragmented data) based on management data (header), and finally the I / F The data is output as data to the memory 4 on the bus 5 or another module (not shown) via the circuit 18.

In addition to the processing related to the data frame, the MAC 12 also performs processing such as control frame generation / transmission / reception processing for controlling the wireless LAN, and time management related to the timing of data transmission based on the received control frame. Do. The control frame transmission / reception operation is the same as that of the MAC 12, PLCP 13, AD / DA circuit 14, and RF circuit 15 that transmit / receive data frames. The MAC 12 also performs the power management function described above.
The local CPU 11 is connected to the main CPU 3 of the user circuit via the bus 5 of the user circuit, while the MAC 12, PLCP 13, AD / DA circuit 14, RF circuit 15, memory 16 with firmware and work RAM 17 are also dedicated or They are connected by a common bus (dedicated bus in the figure), and control the operation of each module based on a command from the main CPU 3 or firmware loaded in the memory 16. In particular, the MAC 12 may perform many processes such as setting, interrupt processing, error processing, fragment processing, and defragment processing. The work RAM 17 is used for the purpose of temporarily storing data when the local CPU 11 performs processing on the MAC 12.
The local CPU 11 changes the data processing speed of the MAC 12, PLCP 13, AD / DA circuit 14, and RF circuit 15 and the clock frequency of the clock generation circuits 22 to 25 according to the transmission speed of the data to be transmitted / received determined by the radio wave condition or the like. To change.
Therefore, the local CPU 11 changes the data processing speed in the apparatus including the local CPU 11 itself according to the transmission speed of data transmitted / received wirelessly, thereby realizing a wireless LAN apparatus with low power consumption when the transmission speed is low. it can.
In FIG. 1, separate clock generation circuits 21 to 25 are prepared for the local CPU 11, MAC 12, PLCP 13, AD / DA circuit 14, and RF circuit 15, but these modules are not necessarily paired with the clock generation circuit. 1 does not need to be dealt with, and the clock generation circuit does not need to be configured as an independent circuit. Further, the data processing speed is not changed only by changing the output frequency of the clock generation circuit.

FIG. 2 is a block diagram showing a main configuration of a wireless LAN device according to another embodiment of the present invention. In the wireless LAN device of FIG. 2, the clock generation circuit 21 is the only clock generation circuit that can be controlled from the local CPU 11, the clock generation circuit 21 is built in the local CPU 11, and further supplies a clock to the local CPU 11 and the MAC 12. The clock generation circuit 23 does not have a one-to-one correspondence between the clock generation circuit and the module that uses the clock, and the MAC 12, the memory 16 with the firmware, and the work RAM 17 share the bus. 1 wireless LAN device.
3 to 6 are diagrams for explaining a method of changing the data processing speed in the wireless LAN device of the present invention. Of these, FIGS. 3 to 5 change the data processing speed by changing the clock signal.
In the example shown in FIG. 3, the data processing speed is changed by dividing the clock signal and changing the division ratio. In FIG. 3, 101 is the same clock generating circuit as described in FIGS. 1 and 2, and 102 is a clock frequency dividing circuit capable of changing the frequency dividing ratio by a control signal from the local CPU 11. A is an output signal waveform of the clock generation circuit 101 and is also an input signal waveform to the clock frequency dividing circuit 102 at the same time. A ′ is an output signal waveform of the clock frequency dividing circuit 102, and this signal is supplied to a module in the wireless LAN device. FIG. 7 shows signal waveforms of clock signals A and A ′.
By changing the frequency division ratio with a control signal from the local CPU 11, the clock operating frequency of the module in the wireless LAN apparatus to which the clock generation circuit 101 is connected can be changed, and the data processing speed of the module can be changed. .

In the example shown in FIG. 4, the data processing speed is changed by thinning out clock signals at regular intervals. In FIG. 4, 101 is the same clock generation circuit as described in FIGS. 1 and 2, and 103 is a clock thinning circuit that can change the interval at which the clock signal is thinned by the control signal from the local CPU 11. B is an output signal waveform of the clock generation circuit 101, and at the same time, an input signal waveform of the clock thinning circuit 103. B ′ is an output signal waveform of the clock thinning circuit 103, and this signal is supplied to a module in the wireless LAN device. The clock signal waveforms of B and B ′ are shown in FIG.
By changing the interval at which the clock is thinned by the control signal from the local CPU 11, the clock operating frequency of the module in the wireless LAN device to which the clock generation circuit 101 is connected can be changed, and the data processing speed of the module can be changed. it can.
In the example shown in FIG. 5, the frequency itself output from the clock generation circuit 101 is changed by a control signal from the local CPU 11. In FIG. 5, reference numeral 101 denotes a clock generation circuit (same as described in FIGS. 1 and 2) that can change the output frequency by a control signal from the outside (local CPU) such as a PLL circuit. C is an output signal waveform of the clock generation circuit 101, which is supplied to a module in the wireless LAN device. The signal waveform of C is as shown in FIG. 9. By changing the output frequency by the control signal from the local CPU, the clock operating frequency of the module in the wireless LAN device to which the clock generation circuit 101 is connected is changed. The data processing speed of the module can be changed.

On the other hand, FIG. 6 changes the data processing speed by changing the number of circuits to be operated when signal processing circuits performing the same processing are operated in parallel. 6, 104 is a signal distribution circuit, 105a, 105b,..., 105n are signal processing circuits, and 106 is a signal synthesis circuit.
The signal distribution circuit 104, the signal processing circuits 105a, 105b,..., 105n, and the signal synthesis circuit 106 are each controlled by the local CPU 11. The signal processing circuits 105a, 105b,..., 105n are controlled by the local CPU 11 to individually operate / stop. For the signal distribution circuit 104, the signal is distributed to the operating signal processing circuits 105a, 105b,..., 105n, and for the signal synthesis circuit 106, the signal processing circuits 105a, 105b. ,..., 105n is controlled so as to synthesize a signal from the operating one.
Thus, the data processing speed can be changed by changing the number of signal processing circuits 105a, 105b,.
By the way, the method of changing the data processing speed shown in FIGS. 3 to 6 is a load on the local CPU 11. For this reason, there are cases where it is better to turn off the data processing speed changing function, for example, when the power supply is stable or when the usage rate of the local CPU 11 is high. In the description so far, the supply of power has not been described, but the wireless LAN device of the present invention is used by connecting to another device so that the power is supplied from the other device. It has become. A connected device (for example, a PC or the like) often operates with a battery (usually a rechargeable secondary battery). A device that can be used with a battery usually has a management program for predicting and calculating the remaining battery level. In the present invention, the local CPU 11 inquires about the type of power source currently used and the remaining battery level.

FIG. 10 to FIG. 12 are flowcharts when the on / off of the data processing speed changing function is dynamically switched by the user circuit in the wireless LAN device of the present invention. Among these, FIG. 10 is a flowchart in the case of switching on / off the function of changing the data processing speed of the wireless LAN device in accordance with the power supply state. In the figure, it is checked whether the power is supplied from the battery after the power is turned on (step 11). If the power is supplied from the battery (Y in step 11), the data processing speed changing function is turned on (step 21). ). On the other hand, if not supplied from the battery (N in step 11), the function for changing the data processing speed is turned off (step 31). Then, after a lapse of a certain time (step 41), it is repeatedly determined whether or not power is supplied from the battery (step 11).
Since the type of power supply that the wireless LAN device itself supplies regularly is checked, the user's effort is not required, and in particular when the power is supplied from a battery with a small margin, power consumption can be reduced.

FIG. 11 is obtained by adding the remaining amount of battery to the on / off determination of the data processing speed changing function in the flowchart of FIG. If power is supplied from the battery after the battery power is turned on in FIG. 11 (step 11), if it is supplied from the battery, if the remaining battery level is lower than A% (step 12), The data processing speed changing function is turned on (step 21), and if it is higher, the data processing speed changing function is turned off (step 31). On the other hand, when the power is not supplied from the battery (N in Step 11), the data processing speed changing function is turned off (Step 31). Then, after a certain period of time (step 41), the determination whether the power is supplied from the battery again (step 11) and the determination of the remaining battery level (step 12) are repeated.
As a result, the power consumption can be reduced when the battery runs out.
FIG. 12 is a flowchart for switching on / off the function of changing the data processing speed in the wireless LAN device in accordance with the usage rate of the main CPU 3 of the user circuit. In FIG. 12, after a certain period of time has elapsed since the power was turned on (step 10), whether or not the CPU usage rate is lower than B% (step 13), if low, the data processing speed changing function is turned on (step 21). If so, turn it off (step 31). Then, after a predetermined time has elapsed (step 41), the CPU usage rate determination (step 13) is repeated.
This gives priority to the throughput when the CPU usage rate of the user circuit is high, while when the CPU usage rate is low, the impact on the throughput will be small. Can be reduced. The CPU usage rate is interrupted from the local CPU 11 and the usage rate of the main CPU 3 is acquired.

Next, an example of power consumption reduction according to an embodiment different from the method described so far will be described.
FIG. 13 is a block diagram showing a main configuration of a wireless LAN device according to another embodiment of the present invention. 1 and 2 differs from FIG. 1 and FIG. 2 in that there is provided a switching means 31 for changing the transmission speed, a valid / invalid transmission speed, and a display means 32 for indicating the setting of the currently effective transmission speed. . For the sake of simplicity, the clock generation circuit and the like are omitted.
In this embodiment, the user operates the switching means 31 according to the use situation, and can change the transmission speed in preference to the wireless transmission speed set by the firmware. The switching means 31 is connected to the PLCP 13 and transmits a change in transmission speed by the user. Further, the switching means 31 is connected to the display means 32. The display means 32 prioritizes the firmware with respect to the user, and the transmission speed to be changed is valid / invalid. The effective transmission rate is displayed. The display means 32 displays whether the transmission speed can be changed or the transmission speed itself by characters or figures as in an LCD (liquid crystal display device), or by turning on / off / flashing an LED (light emitting diode) or the like. May be. For example, when the change is possible, the green light is turned on (when the change is impossible, the light is turned off), and for the transmission speed, an LED corresponding to a predetermined transmission speed may be turned on.
In the procedure in which the wireless LAN device 1 transmits the data of the user circuit as a data frame, the PLCP 13 transmits the data frame of the wireless LAN based on the data for controlling the PLCP 13 included in the header of the data frame input from the MAC 12. The signal is modulated by a method determined for each transmission speed according to the standard and output to the AD / DA circuit 14. At this time, if the transmission rate setting on the header of the data frame input from the MAC 12 is outside the range of the transmission rate of the data frame to be changed by the switching unit 31, modulation is performed at the transmission rate changed by the switching unit 31, and AD / Output to the DA circuit 14. Subsequent operations are the same as those of the embodiments described so far. The procedure for outputting the data frame received by the wireless LAN device 1 as data to the user circuit is the same as in the embodiments described so far.

FIG. 14 is a block diagram showing a main configuration of a wireless LAN device according to another embodiment of the present invention. The wireless LAN device shown in the figure is structurally the same as the wireless LAN device shown in FIG. 13 except that the output from the switching means 31 is directly connected to the PLCP 13 and the display means 32 via the transmission rate setting circuit 33. The transmission rate setting circuit 33 is further connected to the interface circuit 18.
The operation of the wireless LAN device of FIG. 14 is the same as that of FIG. 13, but the addition of the transmission rate setting circuit 33 allows the switching means 31 to be operated with a single push switch even when there are a plurality of transmission speed candidates. It is possible to configure so that every time the push switch is pressed, the output to the PLCP 13 and the display means 32 is repeated as “change invalid → change 1 valid → change 2 valid →... Change n valid → change invalid”. The number of parts of the switching means 31 can be reduced. Further, since the transmission rate setting circuit 33 is connected to the interface circuit 18, the transmission rate is enabled / disabled to be preferentially changed over the firmware in the wireless LAN device by means such as interruption to the main CPU 3 of the user circuit. When there are a plurality of transmission rate candidates, the currently effective transmission rate can be notified as necessary. Further, the main CPU 3 of the user circuit also accesses the transmission rate setting circuit 33 via the interface circuit 18, thereby enabling / disabling the transmission speed to be preferentially changed over the firmware in the wireless LAN device, and further selecting a transmission speed candidate. If there are a plurality, it is possible to know the currently effective transmission rate.

FIG. 15 is a block diagram showing a main configuration of a wireless LAN device according to another embodiment of the present invention. In the wireless LAN apparatus shown in FIG. 13, the switching means 31 connected to the PLCP 13 in the wireless LAN apparatus of FIG. 13 is connected to the local CPU 11, and the display means 32 is connected to and controlled by the local CPU 11. Is different. The operation is different as follows.
In the wireless LAN device of FIG. 15, when data of the user circuit of the wireless LAN device 1 is transmitted as a data frame from the wireless LAN device 1, the user operates the switching means 31 to give priority to the wireless transmission rate set by the firmware. When the transmission speed is changed, the following operation is performed by the local CPU 11 to which the switching means 31 is connected.
That is, when the change of the transmission rate by the switching means 31 is invalid before joining the network, the local CPU 11 receives the base station input from the RF circuit 15 when the terminal station joins the network (if the network is in the ad hoc mode, the network (The terminal station participating in the network), the beacon and probe response management frames (in some cases, frames addressed to other stations or broadcast frames), or the signal strength at that time or a certain amount of time The transmission rate to be used is determined from the average value. The determined transmission rate is reflected in the support rate that is a component of the association request when joining the network. The association request created by the local CPU 11 is transmitted through the route of the local CPU 11 → MAC 12 → PLCP 13 → AD / DA circuit 14 → RF circuit 15 → antenna 2 and is sent to the base station (if the network is in ad hoc mode, other networks participating in the network). Terminal station).
After successful association, when the local CPU 11 creates a transmission frame to be output to the MAC 12, a beacon, a probe, and a probe transmitted from a base station (a terminal station participating in the network when the network is in the ad hoc mode) input from the RF circuit 15. One of the transmission rates notified as the support rate based on the value of the signal strength at that time or the average value over a certain period of time when each response management frame (in some cases, a frame addressed to another local station or a broadcast frame) is received. Is selected and set to data for controlling the PLCP 13 on the header added to the transmission frame output to the MAC 12. The transmission speed set by the local CPU 11 is determined by the local CPU 11 in the PLCP 13 when the transmission frame is transmitted through the route of the local CPU 11 → MAC 12 → PLCP 13 → AD / DA circuit 14 → RF circuit 15 → antenna 2. This is reflected by modulation in the transmission of data on the added header.

When the change of the transmission rate by the switching unit 31 is effective before joining the network, the local CPU 11 determines the support rate that is a component of the association request when joining the network based on the change of the transmission rate by the switching unit 31. This is reflected in the actual transmission speed.
When there are a plurality of candidates for changing or changing the transmission rate by the switching means 31 after joining the network, if the currently effective transmission rate is changed, the local CPU 11 supports them as a component of the association request. Create a reassociation request that reflects the rate. A reassociation request is transmitted via the route of the local CPU 11 → MAC 12 → PLCP 13 → AD / DA circuit 14 → RF circuit 15 → antenna 2 to the base station (or other terminal stations participating in the network if the network is in ad hoc mode). By being notified, when the change of the transmission rate by the switching means 31 is valid / invalid or when there are a plurality of candidates, the currently effective transmission rate is reflected in the actual transmission rate.
When the local CPU 11 creates a transmission frame to be output to the MAC 12 after successful reassociation, a beacon and probe transmitted from a base station (terminal station participating in the network when the network is in ad hoc mode) input from the RF circuit 15 -The transmission rate of the support rate newly notified by the current value of the signal strength when receiving each management frame of the response (in some cases, a frame addressed to another local station or a broadcast frame) or an average value over a certain period of time One of them is selected and set to data for controlling the PLCP 13 on the header added to the transmission frame output to the MAC 12. The transmission speed set by the local CPU 11 is determined by the local CPU 11 in the PLCP 13 when the transmission frame is transmitted through the route of the local CPU 11 → MAC 12 → PLCP 13 → AD / DA circuit 14 → RF circuit 15 → antenna 2. This is reflected by modulation in the transmission of data on the added header.

  Note that the wireless LAN device of FIG. 15 has a plurality of transmission rate candidates that are valid / invalid for the transmission rate that the wireless LAN device of FIG. In some cases, the currently effective transmission speed is notified to the main CPU 3 of the user circuit, whereas the local CPU 11 and firmware installed in the memory 16 are notified to the main CPU 3 of the user circuit. Also, the transmission speed for the display means 32 is displayed based on the input from the switching means 31 by the firmware loaded in the local CPU 11 and the memory 16.

It is a block diagram which shows the principal part structure of the wireless LAN apparatus concerning this invention. It is a block diagram which shows the principal part structure of the wireless LAN apparatus concerning other embodiment of this invention. It is a figure explaining the method of changing the data processing speed in the wireless LAN apparatus of this invention. It is a figure explaining the method of changing the data processing speed in the wireless LAN apparatus of this invention. It is a figure explaining the method of changing the data processing speed in the wireless LAN apparatus of this invention. It is a figure explaining the method of changing the data processing speed in the wireless LAN apparatus of this invention. It is a figure which shows the clock signal waveform in FIG. It is a figure which shows the clock signal waveform in FIG. It is a figure which shows the clock signal waveform in FIG. 6 is a flowchart for switching on / off a data processing speed changing function in the wireless LAN device of the present invention. 6 is a flowchart for switching on / off a data processing speed changing function in the wireless LAN device of the present invention. 6 is a flowchart for switching on / off a data processing speed changing function in the wireless LAN device of the present invention. It is a block diagram which shows the principal part structure of the wireless LAN apparatus concerning other embodiment of this invention. It is a block diagram which shows the principal part structure of the wireless LAN apparatus concerning other embodiment of this invention. It is a block diagram which shows the principal part structure of the wireless LAN apparatus concerning other embodiment of this invention. It is a block diagram which shows the principal part structure of the conventional wireless LAN apparatus.

Explanation of symbols

1 ... Wireless LAN device 2 ... Antenna 3 ... Main CPU
4 ... Memory 5 ... Bus 9 ... RF unit 10 ... Baseband unit 11 ... Local CPU
12 ... MAC
13 ... PLCP
14 ... DA circuit 15 ... RF circuit 16 ... Farm-mounted memory 17 ... Work RAM
DESCRIPTION OF SYMBOLS 18 ... Interface circuit 21, 21, 22, 23, 24, 25, 101 ... Clock generation circuit 31 ... Switching means 32 ... Display means 33 ... Transmission rate setting circuit 102 ... Clock dividing circuit 103 ... Clock thinning circuit 104 ... Signal distribution Circuit 105 ... Signal processing circuit 106 ... Signal synthesis circuit

Claims (12)

  A wireless LAN device that includes a baseband unit and an RF unit and transmits / receives data by connecting to another device, and includes a clock generation unit that generates a clock signal and a local CPU that controls transmission / reception operations Control means, and data processing speed changing means for changing the data processing speed of the baseband unit and the RF unit including the local CPU according to the transmission speed of data transmitted and received by the local CPU wirelessly. A wireless LAN device.   The data processing speed changing means changes the clock signal generated by the clock generating means and supplies the changed clock signal to some or all of the modules of the baseband unit and the RF unit. Item 4. The wireless LAN device according to Item 1.   3. The wireless LAN device according to claim 2, wherein the data processing speed changing means changes the data processing speed by changing a frequency dividing ratio of the clock signal generated by the clock generating means.   3. The wireless LAN device according to claim 2, wherein the data processing speed changing means changes the data processing speed by thinning out a clock signal generated by the clock generating means.   The wireless LAN device according to claim 2, wherein the data processing speed changing means changes the data processing speed by changing an output frequency of a clock generator of the clock generating means.   2. The wireless LAN device according to claim 1, wherein the data processing speed changing means changes the data processing speed by changing the number of circuits operating in parallel.   The wireless LAN device according to claim 1, wherein the control unit performs control so as not to change the data processing speed in accordance with a power supply state.   The wireless LAN according to claim 1, wherein the control unit performs control so as not to change the data processing speed according to a CPU usage rate of the other device. apparatus.   A wireless LAN device having a baseband unit and an RF unit, and having a setting unit that sets a data transmission rate according to a communication state when transmitting and receiving data, and a control unit that controls transmission and reception operations; And a switching means for changing the set transmission rate of the data.   10. The wireless LAN device according to claim 9, further comprising display means for displaying an effective transmission rate when there are a plurality of transmission rate candidates and whether or not the transmission rate is changed by the switching unit.   The wireless LAN device according to claim 10, wherein the display unit displays valid / invalid of the transmission rate and an effective transmission rate by lighting the light emitter.   A wireless LAN device that is used in connection with another device, has a baseband unit and an RF unit, and has setting means for setting a data transmission rate according to a communication state when data is transmitted and received. Switching means for changing the transmission rate of the set data and control means for controlling transmission / reception operation, wherein the control means enables / disables the transmission rate to be changed by the switching means for the connected device. And a wireless LAN device that notifies an effective transmission rate when there are a plurality of transmission rate candidates.

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