Title of Invention	METHOD AND APPARATUS FOR POWER LINE COMMUNICATION
Abstract	The variation cycle L of the characteristies of a transmission line is divided into a plurality of sections (n sections), a procedure is repeated in which transmission line estimation is performed for only one section among n sections in one beacon period and thus transmission line estimation is performed for all of the n section. The beacon period T is set based on (T=L,Lm/m),where n is an interger that is 2 or larger, and in is an interger that is n or larger and whose greatest common measure with n is 1.

Title of Invention

METHOD AND APPARATUS FOR POWER LINE COMMUNICATION

Abstract

The variation cycle L of the characteristies of a transmission line is divided into a plurality of sections (n sections), a procedure is repeated in which transmission line estimation is performed for only one section among n sections in one beacon period and thus transmission line estimation is performed for all of the n section. The beacon period T is set based on (T=L,Lm/m),where n is an interger that is 2 or larger, and in is an interger that is n or larger and whose greatest common measure with n is 1.

Full Text	DESCRIPTION COMMUNICATION APPARATUS AND TRANSMISSION LINE ESTIMATION METHOD 5 TECHNICAL FIELD The present invention relates to a communication apparatus and a transmission line estimation method. More specifically, the present invention relates to a communication apparatus sending and receiving data based on the characteristics of a transmission 10 line between apparatuses without lowering the throughput, and a transmission line estimation method (channel estimation) performed by the communication apparatus, by which the characteristics of the transmission line are estimated and evaluated with a high precision. 15 BACKGROUND ART In a communication method by which communication parameters such as a subscriber and a modulation method used for transmission and reception are determined based on estimation on the 20 characteristics of a transmission line, it is important to precisely determines the communication parameters that are suitable for the characteristics of the transmission line in transmission. In particular, in a communication system having attenuation characteristics that deeply depend on the frequency (power line. 25 carrier communications having a power line as a communication 1 medium for example) , it is effective to use a multi-carrier transmission line method using a subcarrier and a modulation method the characteristics of the transmission line are deteriorated) . Then, based on the result of this estimation on the transmission 10 line, new parameters are selected, and data is sent or received. This technique has been disclosed in, for example, JF2002-158675A. However, in an environment in which the characteristics of the transmission line vary periodically, the communication parameters selected when estimating the transmission line often 15 do not suit for the characteristics of the transmission line when sending data if a timing of sending data is not synchronized with the periodical variation of the characteristics of the transmission line. Thus, in the above-described conventional method, the maximum communication efficiency is not always obtained even when 20 the transmission line is estimated. Thus, as a countermeasure for this problem., a following method has been conventionally proposed. First, the variation cycle of the characteristics of a transmission line is synchronized with the frame period of a 25 communication system, and this variation cycle is divided into 2 a plurality of sections. Next, within one frame period, the plurality of divided sections of the transmission line are continuously estimated section by section. Then, as a result of the transmission line estimation, communication parameters, 5 obtained in a section with the highest communication efficiency are selected and then communications are performed. FIG- 12 is- a process sequence of this conventional method for estimating a transmission line. However, in the conventional method shown in FIG- 12, there 10 is the problem that the transmission line is estimated continuously, and thus requests to estimate the transmission line and their response messages occupy the transmission line and disturb communications of stream data, audio data, or other data that is supposed to be sent. Furthermore, in this conventional method, 15 a time from the starting point of the frame period of the communication system to the starting time of a transmission line:. estimation section is different for each frame period. As a result, when the band is guaranteed, for example, with time sharing, not only is scheduling for transmission line estimation complicated, 20 but also arises a case in which a scheduling condition cannot be- satisfied. DISCLOSURE OF THE INVENTION Therefore, an object of the present invention is to provide 25 a communication apparatus in which a transmission line is estimated 3 apparatus performing periodical communications with another communication apparatus via a transmission line. In order to 10 achieve the above-described object, the communication apparatus of the present invention is provided with a. communication control portion, a transmission line estimation portion, and a communication parameter determination portion. The communication control portion sets the communication 15 period to (Lxm/n) (L is the variation cycle of the characteristics of a transmission line, n is an integer that is 2 or larger, and m is an integer that is n or larger and whose greatest common measure with n is 1} to perform communications. The transmission line estimation portion estimates the characteristics of the 20 transmission line within a time (L/n) after a certain offset time (Lxk/h) {k is a real number that is 0 or larger) has passed since the communication period started. The communication parameter determination portion determines a communication parameter to be used by the communication control portion, based on a result of 25 estimation by the transmission line estimation portion . 4 It is preferable' that the transmission line estimation portion estimates the characteristics of the transmission line at least n times. Furthermore, the communication apparatus may estimate the characteristics of the transmission line at the 5 initial starting up or upon detecting a change in a state of the transmission line. A typical communication period is the period of beacons sent from a communication apparatus serving as a base unit. When there is a request to estimate the characteristics of the transmission line, the communication apparatus sends a. 10 request to allocate a Lime for estimating the characteristics of the transmission line to the communication apparatus serving as. the base unit, -and the characteristics of the transmission line are estimated only when permission is given. This request may be notified using the beacon frame or the polling frame to another 15 communication apparatus. A typical variation cycle L of the characteristics of the transmission line is the half cycle of the commercial power supply cycle. Each of the processes performed by each of the components of the communication apparatus described above can be regarded 20 as a transmission line estimation method that gives a series of procedures. This method is provided in the form of a program for letting a computer execute the series of procedures. This program may be introduced in a computer in the form stored in a computer-readable storage medium. Furthermore, a part of the 25 functional blocks described above that constitute the 5 communication apparatus may be realized as an LSI, which is an integrated circuit. As described above, according to the present invention, a transmission line is estimated in a distributed manner by a simples 5 scheduling, so that the characteristics of the transmission line are estimated and evaluated with a high precision and thus data can be sent and received at a high throughput without affecting other, streams. 10 BRIEF DESCRIPTION OF THE DRAWINGS FIG- 1 is a diagram showing a configuration example of a Communication network, system using communication apparatuses according to a first embodiment of the present invention. FIG. 2 is a diagram showing an example of timings at which 15 a transmission line is estimated by the communication apparatuses according to. the first embodiment of the present invention. FIG. 3 is a diagram showing another example of timings at which a transmission line is estimated: by the communication apparatuses according to the first embodiment of the present 20 invention. FIG.. 4 is a diagram showing another example of timings at which a transmission line is estimated by the communication apparatuses according to the first embodiment of the present invention. 25 FIG. 5 is a communication sequence showing the procedure 6 following which a transmission line is estimated by the communication apparatuses according to the first embodiment of the present invention. FIG. 6 is a diagram showing an example of a tonemap- 5 FIG. 7 is a diagram explaining the relationship between a noise and transmission line estimation sections. FIG. 8 is another communication sequence showing the procedure following which a transmission Line is estimated by the communication apparatuses according to the first embodiment of 10 the present invention. FIG. 9 is a diagram explaining a, method by which a beacon period is determined by the communication apparatuses according to the first embodiment of the present invention. FIG. 10 is a diagram-explaining a method by which a beacon 15 period is determined by the communication apparatuses according to the first embodiment of the present invention. FIG. 11 is a diagram showing an example of a communication network system, in which the communication apparatuses of the present invention are applied to high-speed power line 20 transmission. FIG. 12' is a communication sequence showing the procedure following which a transmission line is estimated by a conventional communication apparatus. 25 BEST MODE FOR CARRYING OUT THE INVENTION 7 Hereinafter, embodiments of the present invention will be described with reference, to the drawings- First Embodiment FIG. 1 is a diagram showing a configuration example of a 5 communication network system using a communication apparatus l according to a first embodiment of the present invention. In FIG. \, in the communication network system of the present invention, a plurality of communication apparatuses 1 are connected to each other via a transmission line 2. The transmission line 2 way be 10 either wired or wireless. This embodiment will be described using, as. an example, the communication network system in which one of the plurality of communication apparatuses 1 is a master unit, and this master unit periodically transmits a beacon so as to control the communications of the other communication apparatuses 1 (slave 15 units). The communication apparatus 1 is provided with a communication control portion II, a transmission line estimation portion 12, and a communication parameter determination portion 13. The communication control portion 11 deals with most 20 of the communication processes performed by the communication apparatus 1. Basically, this communication control portion 11 performs communications with another communication apparatus 1 using communication parameters determined, by the communication parameter determination portion 13. The transmission line 25 estimation portion 12 measures the characteristics of the 8 transmission line 2 at predetermined periodical timings and estimates a state of the transmission line 2- The communication parameter determination portion 13 sets or updates communication parameters based on the result obtained when transmission line 5 estimation portion 12 estimates the transmission line 2. Hereinafter, a method by which the thus configured communication apparatus 1 estimates the characteristics of a transmission line will be described. FIGS. 2 to 4 are diagrams each showing an example of timings at which a transmission line 10 is: estimated by the communication apparatus 1 according to the first embodiment of the present invention- FIG. 5 is a communication sequence showing the procedure following which a transmission line is estimated, by the communication apparatus 1 according to the first embodiment of the present invention. 15 In this embodiment, a case will be described in which in the. transmission line 2 in the communication network system, a noise with a certain pattern (the mark X in FIG. 2) is generated with certain intervals as shown in FIG, 2, that is, the variation cycle of the characteristics of the transmission line corresponds 20 to these certain intervals. In this case, the communication control portion 11 in each of the communication apparatuses 1 that constitute the communication network systemsets the beacon period, which will be the communication period, in the following manner- Herein, the beacon period refers to a time interval between when 25 a beacon is transmitted by the master unit and when its next beacon 9 is transmitted. There is a case in which due to an influence of a power circuit of, for example, a household electrical appliance that is connected to a power line, the cycle of a noise pattern on the power line 5 is the same as the half cycle of a commercial power supply [50 Hz or 60 Hz) . Accordingly, when assuming a communication network system using a power line, it is necessary to consider the characteristics of a transmission line-that has been synchronized with the half cycle of the commercial power supply described above 10 (see sine waves in FIG. 2). A point of the setting is that a "variation cycle L of the characteristics of the transmission line is divided into n sets of sections (n sections), a procedure is repeated in which transmission line estimation is performed for only one section 15 among sections in one beacon period, and thus transmission Line estimation is performed for all of the n sections. A beacon period T for realizing this point is set based on "T=Lxm/n", where n is an integer that is 2 or larger, and in is in integer that is n or larger and whose greatest common measure with n is 1. 20 Furthermore an offset time is .set based on "Lxk/n", where k is a real number that satisfies 0 like is set to enable a transmission line to be estimated within one beacon period and section by section, it is possible to deal with a variation of the transmission line quickly. It should be 25 noted that the offset time can be set freely if dealing with a 10 variation of the transmission line rapidly is not considered. FIGS. 2 and 3 are examples in which n=3 and m=17. FIG. 4 is an example in which n=4 and xu=19. When assuming a communication network system using a power line as described above, the beacon 5 period T is calculated using L=8.333 msec when the commercial power supply frequency is 60 Hz and using L=10 msec when the commercial power supply frequency is 50 Hz. In FIGS. 2 to 1, a description of the beacon itself has been omitted. Furthermore, regarding the Offset time, k=l6 in FIG. 2, k=15 in FIG. 3, and k=17 in FIG- 4. 10 AS seen in FIGS. 2 to 4, when the beacon period and the offset time are set based on the above-described points, after the offset time has passed, each of the transmission line estimation sections does not have the same timing as that of the commercial power supply cycle and slides therefrom. Therefore, it is possible to easily 15 realize the transmission line estimation that cities not overlap the commercial power supply cycle and that is- continuous in time. Referring to FIG. 5, the procedure following which a transmission line is estimated by the communication apparatus 1 will be described in detail. 20 At the initial starting up such as when the power is turned on, or upon detecting a change in the characteristics of a transmission line, a communication apparatus 1 serving as a slave unit (hereinafter, referred to as apparatus A) requests a communication apparatus 1 serving as a master unit (hereinafter, 25 referred to as apparatus C) to allocate a time for estimating the 11 transmission line (step 1). When receiving the request to. allocate a time for estimating the transmission Line from the apparatus A, the apparatus C sends a beacon, to which information on time allocation for estimating the transmission line is added, 5 during the next time of sending the beacon (step 2). This Information on the time allocation for estimating the transmission line refers to information showing sections that can be used for estimating the transmission line, and is typically given as the offset time from the starting time of the beacon period. 10 when receiving the beacon, to which the information on time allocation for estimating the transmission line is added,, from the apparatus C, the apparatus A measures the characteristics of the transmission line based on this information, after the offset time has passed since the beacon period started. In the example 15 in: FIG. 2, the characteristics of the transmission line are measured in a transmission line estimation, section 2/3 (the half-tone portion 2 in the drawing). A specific method for measuring the characteristics of the transmission line is that the apparatus A sends a communication apparatus 1 serving as a 20 slave unit of interest in the communication (hereinafter, referred to as apparatus B) a request to estimate the transmission line (step 3) , and receives a response, from the apparatus B, for the request to estimate the transmission line (step 4). This estimation on the transmission line is, for example, performed 25 in the following manner. 12 First, a predetermined estimation series as well as the transmission line estimation request are sent from the apparatus A to the apparatus B. Based on this estimation series, the apparatus B calculates the receiving CNR (carrier to noise power 5 ratio). Next, according to the calculated receiving CNR, the apparatus B creates a tonemap that specifies communication parameters such as a subcarrier to be used and a modulation method. for each subcarrier. An example of the tonemap is shown in FIG. 6, Herein, the tonemap is constituted by the tone-map number for 10 discriminating this tonemap from other tonemaps, the subcarrier number for identifying the subearrier of interest in this tonemap, and information of use/non-useof the subcarrier and the modulation factor. The information on the modulation factor of the subcarrier may be information an the modulation type (16 QAM or 32 QAM, for 15 example) or. may be the number of bit allocation of the subcarrier ("4" in the case of 16 QAM, for example) shown in FIG, 6- Then, the apparatus B responds to the apparatus A by sending the transmission line estimation including the tonemap. It should be noted that the above-described multi-carrier transmission 20 method is en example-, and other methods such as a spread spectrum method also can be used. Furthermore, the information on the receiving CNR is used for determining the communication parameters but information other than this also can be used with a similar process, the apparatus. A measure the 25 characteristics of the transmission line in the other transmission 13 line estimation sections (steps 5 to 10). In the example in FIG, 2, the characteristics of the transmission line are measured in a transmission line estimation section 1/3 (the half-tone portion 1 in the drawing) and a transmission line estimation section 3/3 5 (the half-tone portion 3 in the drawing), With this process, the apparatus A completes the transmission line estimation in all of these three divided transmission line estimation sections, that is, acquisition of the tonemaps I step 11) . Then, among the plurality of acquired tonemaps, the apparatus a selects one tonemap 10 that is optical for use in the communications-, and notifies the apparatus B of it (step 12). With this process, the apparatuses A and B can share the optimal tonemap. Hereinafter, the communications are performed using this optimal tonemap. An optimal tonemap is selected, for example, in the following 15 manner- in the example in FIG. 2, a noise is generated in the transmission- line estimation sections 1/3 and 2/3, and. a noise is not generated in the transmission line estimation section 3/3 (see FIG, 7 partially extracting and magnifying FIG- 2). Therefore, the tonemap of the transmission line estimation 20 section 3/3.has the highest PHY rate. Accordingly, this tonemap with the highest PHY rate is selected as the tonemap used for the communication. Even without acquiring all of the tonemaps of the transmission line estimation sections, it is possible to select 25 an optimal tonentap among tonernaps that have been acquired when 14 a predetermined time-out period has passed. As described above, according to the communication apparatus 1 of the first embodiment of the present invention, it is possible to easily realize transmission line estimation in a 5 distributed manner. Thus, the characteristics of the transmission line are estimated and evaluated with a high precision, and thus data can be sent and received at a high throughout. In the first embodiment, the integers n and in are described as fixed values, but they can be changed dynamically in accordance 10 with, for example, a change in the transmission line based on the- estimation result of the transmission line, the value of the PHY rate., or the' degree of a variation of the PHY rate. Furthermore, in the communication sequence shown in FIG. 5, a relevant apparatus other than the apparatuses A, B, and C is; 15 not described, but the process is performed typically as shown in. FIG. 8. Referring, to FIG. 8r information on time allocation for estimating; the transmission line is added to a beacon sent from the apparatus C. The information on the time allocation for 20 estimating the transmission line- not only specifies, for the apparatus. A, a time during which a request to estimate the transmission line can be sent to the apparatus B, but also prohibits the apparatuses B, c, and others from transferring data. By prohibiting apparatuses other than that sends the request from 25 transmitting in a time during which the request to estimate the 15 transmission line is sent (the half-tone period in FIG. 8), it is possible to avoid a collision, for example, between the request to estimate the transmission line and data. In a time during which a response to the request to estimate 5 the transmission line is sent from the apparatus B to the apparatus A, data transfer by the apparatuses A, B, and others may be or may not be prohibited for the purpose of improving the throughput in the data transfer. FIG. 8 is the communication sequence in which data transfer is not prohibited. Herein, when 10 data transfer is not prohibited, it is preferable that the response from the apparatus B is given the highest priority. Furthermore, instead of a manner in which the receiver apparatus B responds to the transmitter apparatus A by sending the transmission line estimation at each time as described above, 15 the plurality of transmission line estimations may be sent at one time, or the receiver apparatus B may select a tone-map based on the plurality of transmission line estimations and notify the transmitter apparatus A of the selected tonemap. In either case, the effect of the present invention is not lost. 20 Second Embodiment The first embodiment described above is a technique assuming that the variation cycle of the characteristics, of the transmission line is known in advance. Then, in a second embodiment below, a technique -will be described in which an optimal beacon period 25 can be set automatically even when the variation cycle of the 16 characteristics .of the transmission line is not known in advance. FOR example, a case will be described in which the communication apparatus 1 can set both of a beacon period T1l (FIG. 9) when the variation cycle L of the characteristics of the 5 transmission line , which is synchronized with a commercial power supply frequency of 60 Hz, is 8.333 msec and when the integers n=3 and m=17, and a beacon period T2 (FIG. 10) when the variation cycle L of the characteristics of the transmission line, which is; synchronized with a commercial power supply frequency of 50 Hz, 10 is 10 msec and when the variables n=3 and m=l7. In this case, the communication apparatus 1 estimates the transmission line in all of the identical sections within a beacon period and acquires a plurality of tonemaps. FIGS- 9 and 10 show a case of the transmission line estimation section 2 (the half -tone portions 15 in the drawings). The offset time is given based on ""Lxk/n" (k is a real number-that satisfies 0 10. Herein, it is assumed that the actual commercial power supply frequency is 60 Hz. 20 As a result, the variation cycle L of the characteristics of the transmission line in the beacon period T1 is synchronized more with a noise that is synchronized with the actual commercial power supply frequency (6.0 Hz) in. the drawing (FIG. 9). Thus, the characteristics of the transmission line at the transmission 25 line estimation sections 2 are substantially the same, and a 17 similar value for the communication parameter (PHY rate} of each tonemap can be obtained in the plurality of acquired tonemaps, so that it is determined that the correlation, regarding a noise, between the beacon period T1 and the variation cycle L is high. 5 On the other hand, the variation cycle L of the characteristics of the transmission line in the beacon period T2 is not synchronized with a noise that is synchronized with the actual commercial power supply frequency (60 Hz) in the drawing (FIG. 10). Thus, the characteristics of the transmission line 10 at the transmission line estimation sections 2 are different from each other, and the communication parameter (PHY rate) of each tonemap is different for each of the plurality of acquired tonemaps, Therefore, it is determined that the correlation, regarding a noise, between the beacon period T2 and the variation cycle L is low. 15 Based on the above-described points, it is determined that the settings of a beacon period determined to have the highest correlation is synchronized most with a noise that is actually being generated- Accordingly, only by selecting the settings of the beacon period with which the correlation is high, it is possible 20 to automatically set a beacon period that corresponds to the variation cycle of the characteristics of the transmission line. An optimal communication parameter that is noise-resistant is selected by setting the beacon period according to the second embodiment and then by performing the process according to the 25 first -embodiment. 18 The above-described embodiments can be realized also when a CPU executes a program that can let the CPU execute the above described procedure stored in e storage device (ROM., BAM, or hard disk, for example). In this case, the program may be 5 executed after being stored in the storage device via a storage medium, or may be executed directly on the storage medium. The storage medium here includes a semiconductor memory such as a ROM a RAM, and a f lash memory, a magnetic disk memory such as a flexible disk and 5 hard, disk, an optical disk such as a CD-ROM, a DVD, 10 and a BD, and a memory card. Furthermore, the concept of the storage medium also includes a communication medium such as a telephone line and a carrier line. Each of the functional blocks indicated by the broken line in FIG. 1 may be realized by an LSI, which is an integrated circuit. 15 Each of the' functional blocks may be formed on a single chip one by one, or a part or all of them may be formed on one chip. Although an LSI is used in these embodiments, this circuit may be called IC; system LSI, super LSI, or ultra LSI, depending on the difference of the degree of integration. 20 It should be noted that the method for forming an integrated circuit is not limited to using an LSI, and circuit integration may be realized by a dedicated circuit: or a general purpose processor. Furthermore, it is. possible to use an FPGA (field programmable gate array) that can be programmed after an LSI is produced, and 25 a reconfigurable processor being capable of reconfiguring 19 connections and settings of circuit cells inside of the LSI. possibility of, for example, application of biotechnology. Hereinafter, an example will be described in which the present invention that has been described in the embodiments is applied to an actual network system, FIG. 11 is a diagram. showing 10 an example of a network system in which the present invention is applied to high-speed power line transmission. In FIG. 11, an IEEE/E1394 interface, a USB interface, or so forth provided in multimedia equipment such as a personal computer, a DVD recorder, a (digital TV, and a home server system is- connected to a power 15 line via an adaptor provided with the function of the present invention. With this configuration, it is possible to construct a network system in which digital data such as multimedia data can be transmitted at a high speed via a power line serving as a medium. In contrast to a conventional wired LAN, this system 20 does not require a network cable to be newly installed and can use a power line having been installed already at home, office, or so forth without any process as a network- line, so that a significant convenience in terms of cost and simplicity of installation is provided- 25 The above-described embodiment is an example in which 20 existing multimedia equipment is applied to power line communications via an adaptor converting a. signal interface of the existing equipment to an interface of the power line communications. In future, however, the function of the present 5 invention is included in multimedia equipment, so that it becomes possible to transmit data between the equipment via power codes of the multimedia equipment. In this case there is no need for the adaptor, the IEEE1394 cable, or the USB cable shown in FIG, 11, and thus wiring is simplified. Furthermore, since connection to 10 the Internet via a router or connection to a wireless/wired LAN using, for example, a hub is possible, so that it is possible to expand a LAN system using the high-speed power line transmission system of the present invention. Furthermore, in the provider line transmission method, communication data runs via a power line. 15 Therefore, in contrast to a wireless LAN, there is no problem that radio waves are intercepted, resulting in data leakage „ The power line transmission method also has a security effect to protect data. Data running on the power line can be protected by IPsec in IP protocol, encoding the contents themselves, or other DRM 20 methods, for example. As described above, by installing a QoS function including a copyright protection function by encoding the contents and the effect of the present invention (band allocation flexibly addressing improvement in throughput increased retransmission, 25 and variation in traffic), AV contents with a high quality can 21 CLAIMS 1. A communication apparatus performing periodical communications with another communication apparatus via a 5 transmission line, comprising: a- communication control portion operable to set a communication period to (Lxm/n) (L is a variation cycle of characteristics of a transmission line, n is an integer that is 2 or larger, and in is an integer that is n or larger and whose 10 greatest common measure with n is 1) to perform communications, a transmission line estimation portion operable to estimate the characteristics of the transmission line within a time (L/n) after a certain offset time has passed since the communication period started, and 15 a communication parameter determination portion operable to determine a communication parameter to be used by the communication control portion,, based on a result of estimation by the transmission line estimation portion, 20 2. The communication apparatus according to claim 1, wherein the offset time is (Lxk/n) (k is a real number that satisfies. 0 3. The communication apparatus according to claim 1, 25 wherein the transmission line estimation portion estimates 23 the characteristics of the transmission line at least n times. 4. The communication apparatus according to claim 1, wherein the characteristics of the transmission line are 5 estimated at an initial starting up or upon detecting a change in a state of the transmission line. 5. The communication apparatus according to claim 1, wherein the communication period is a period of beacons sent 10 from a communication apparatus serving as a master unit. 6. The communication apparatus according to clam 5, wherein a request to allocate a time for estimating the Characteristics of the transmission line is sent to the 15 communication apparatus serving as the master unit. 7. The communication apparatus according to claim 6, wherein allocation of a time for estimating the characteristics of the transmission line is notified using a beacon 20 frame or a polling f frame to another communication apparatus, and the characteristics of the- transmission line are estimated only when permission is given. 8. The communication apparatus according to claim 1, 25 wherein the variation cycle I of the characteristics of the 24 transmission line is a half cycle of a commercial power supply, cycle. 9 A transmission line estimation method executed by a 5 communication apparatus performing periodical communications with another communication apparatus via a transmission line, comprising: setting a communication period to (Lxm/n) (L is a variation. cycle of characteristics of a transmission line, n is an integer 10 that is 2 or larger, and in is an integer that is n or larger and whose greatest common measure with n is 1) to perform communications, estimating the characteristics of the transmission line within a time (L/n) after a certain offset time has passed since 15 the communication period started, and determining a communication parameter to be used in the communicating step, based on a result of estimation in the estimating step. 20 10. An integrated circuit used for a communication apparatus per forming periodical communications with another communication apparatus via a transmission line wherein circuits are integrated that function as: a communication control portion operable to set a 25 communication period to (Lxm/n) [L is a variation cycle of 25 characteristics of a transmission line, n is an integer that is 2 or larger, and in is an integer that is n or larger and whose greatest common measure with n is 1) to perform communication, a transmission line estimation portion operable to 5 estimate the characteristics of the transmission line within a time (L/n) after a certain offset time has passed since the communication period started, and a communication parameter determination portion operable to determine a communication parameter to be used by the 10 communication control portion, based on a result of estimation by; the transmission line estimation portion. The variation cycle L of the characteristies of a transmission line is divided into a plurality of sections (n sections), a procedure is repeated in which transmission line estimation is performed for only one section among n sections in one beacon period and thus transmission line estimation is performed for all of the n section. The beacon period T is set based on (T=L,Lm/m),where n is an interger that is 2 or larger, and in is an interger that is n or larger and whose greatest common measure with n is 1.

Full Text

DESCRIPTION
COMMUNICATION APPARATUS AND TRANSMISSION LINE ESTIMATION METHOD
5 TECHNICAL FIELD
The present invention relates to a communication apparatus
and a transmission line estimation method. More specifically,
the present invention relates to a communication apparatus sending
and receiving data based on the characteristics of a transmission
10 line between apparatuses without lowering the throughput, and a
transmission line estimation method (channel estimation)
performed by the communication apparatus, by which the
characteristics of the transmission line are estimated and
evaluated with a high precision.
15
BACKGROUND ART
In a communication method by which communication parameters
such as a subscriber and a modulation method used for transmission
and reception are determined based on estimation on the
20 characteristics of a transmission line, it is important to
precisely determines the communication parameters that are suitable
for the characteristics of the transmission line in transmission.
In particular, in a communication system having attenuation
characteristics that deeply depend on the frequency (power line.
25 carrier communications having a power line as a communication

1

medium for example) , it is effective to use a multi-carrier
transmission line method using a subcarrier and a modulation method

the characteristics of the transmission line are deteriorated) .
Then, based on the result of this estimation on the transmission
10 line, new parameters are selected, and data is sent or received.
This technique has been disclosed in, for example, JF2002-158675A.
However, in an environment in which the characteristics of
the transmission line vary periodically, the communication
parameters selected when estimating the transmission line often
15 do not suit for the characteristics of the transmission line when
sending data if a timing of sending data is not synchronized with
the periodical variation of the characteristics of the transmission
line. Thus, in the above-described conventional method, the
maximum communication efficiency is not always obtained even when
20 the transmission line is estimated.
Thus, as a countermeasure for this problem., a following
method has been conventionally proposed.
First, the variation cycle of the characteristics of a
transmission line is synchronized with the frame period of a
25 communication system, and this variation cycle is divided into

2

a plurality of sections. Next, within one frame period, the
plurality of divided sections of the transmission line are
continuously estimated section by section. Then, as a result of
the transmission line estimation, communication parameters,
5 obtained in a section with the highest communication efficiency
are selected and then communications are performed. FIG- 12 is-
a process sequence of this conventional method for estimating a
transmission line.
However, in the conventional method shown in FIG- 12, there
10 is the problem that the transmission line is estimated continuously,
and thus requests to estimate the transmission line and their
response messages occupy the transmission line and disturb
communications of stream data, audio data, or other data that is
supposed to be sent. Furthermore, in this conventional method,
15 a time from the starting point of the frame period of the
communication system to the starting time of a transmission line:.
estimation section is different for each frame period. As a result,
when the band is guaranteed, for example, with time sharing, not
only is scheduling for transmission line estimation complicated,
20 but also arises a case in which a scheduling condition cannot be-
satisfied.
DISCLOSURE OF THE INVENTION
Therefore, an object of the present invention is to provide
25 a communication apparatus in which a transmission line is estimated

3

apparatus performing periodical communications with another
communication apparatus via a transmission line. In order to
10 achieve the above-described object, the communication apparatus
of the present invention is provided with a. communication control
portion, a transmission line estimation portion, and a
communication parameter determination portion.
The communication control portion sets the communication
15 period to (Lxm/n) (L is the variation cycle of the characteristics
of a transmission line, n is an integer that is 2 or larger, and
m is an integer that is n or larger and whose greatest common measure
with n is 1} to perform communications. The transmission line
estimation portion estimates the characteristics of the
20 transmission line within a time (L/n) after a certain offset time
(Lxk/h) {k is a real number that is 0 or larger) has passed since
the communication period started. The communication parameter
determination portion determines a communication parameter to be
used by the communication control portion, based on a result of
25 estimation by the transmission line estimation portion .
4

It is preferable' that the transmission line estimation
portion estimates the characteristics of the transmission line
at least n times. Furthermore, the communication apparatus may
estimate the characteristics of the transmission line at the
5 initial starting up or upon detecting a change in a state of the
transmission line. A typical communication period is the period
of beacons sent from a communication apparatus serving as a base
unit. When there is a request to estimate the characteristics
of the transmission line, the communication apparatus sends a.
10 request to allocate a Lime for estimating the characteristics of
the transmission line to the communication apparatus serving as.
the base unit, -and the characteristics of the transmission line
are estimated only when permission is given. This request may
be notified using the beacon frame or the polling frame to another
15 communication apparatus. A typical variation cycle L of the
characteristics of the transmission line is the half cycle of the
commercial power supply cycle.
Each of the processes performed by each of the components
of the communication apparatus described above can be regarded
20 as a transmission line estimation method that gives a series of
procedures. This method is provided in the form of a program for
letting a computer execute the series of procedures. This program
may be introduced in a computer in the form stored in a
computer-readable storage medium. Furthermore, a part of the
25 functional blocks described above that constitute the

5

communication apparatus may be realized as an LSI, which is an
integrated circuit.
As described above, according to the present invention, a
transmission line is estimated in a distributed manner by a simples
5 scheduling, so that the characteristics of the transmission line
are estimated and evaluated with a high precision and thus data
can be sent and received at a high throughput without affecting
other, streams.
10 BRIEF DESCRIPTION OF THE DRAWINGS
FIG- 1 is a diagram showing a configuration example of a
Communication network, system using communication apparatuses
according to a first embodiment of the present invention.
FIG. 2 is a diagram showing an example of timings at which
15 a transmission line is estimated by the communication apparatuses
according to. the first embodiment of the present invention.
FIG. 3 is a diagram showing another example of timings at
which a transmission line is estimated: by the communication
apparatuses according to the first embodiment of the present
20 invention.
FIG.. 4 is a diagram showing another example of timings at
which a transmission line is estimated by the communication
apparatuses according to the first embodiment of the present
invention.
25 FIG. 5 is a communication sequence showing the procedure

6

following which a transmission line is estimated by the
communication apparatuses according to the first embodiment of
the present invention.
FIG. 6 is a diagram showing an example of a tonemap-
5 FIG. 7 is a diagram explaining the relationship between a
noise and transmission line estimation sections.
FIG. 8 is another communication sequence showing the
procedure following which a transmission Line is estimated by the
communication apparatuses according to the first embodiment of
10 the present invention.
FIG. 9 is a diagram explaining a, method by which a beacon
period is determined by the communication apparatuses according
to the first embodiment of the present invention.
FIG. 10 is a diagram-explaining a method by which a beacon
15 period is determined by the communication apparatuses according
to the first embodiment of the present invention.
FIG. 11 is a diagram showing an example of a communication
network system, in which the communication apparatuses of the
present invention are applied to high-speed power line
20 transmission.
FIG. 12' is a communication sequence showing the procedure
following which a transmission line is estimated by a conventional
communication apparatus.
25 BEST MODE FOR CARRYING OUT THE INVENTION
7

Hereinafter, embodiments of the present invention will be
described with reference, to the drawings-
First Embodiment
FIG. 1 is a diagram showing a configuration example of a
5 communication network system using a communication apparatus l
according to a first embodiment of the present invention. In FIG. \,
in the communication network system of the present invention, a
plurality of communication apparatuses 1 are connected to each
other via a transmission line 2. The transmission line 2 way be
10 either wired or wireless. This embodiment will be described using,
as. an example, the communication network system in which one of
the plurality of communication apparatuses 1 is a master unit,
and this master unit periodically transmits a beacon so as to control
the communications of the other communication apparatuses 1 (slave
15 units).
The communication apparatus 1 is provided with a
communication control portion II, a transmission line estimation
portion 12, and a communication parameter determination
portion 13. The communication control portion 11 deals with most
20 of the communication processes performed by the communication
apparatus 1. Basically, this communication control portion 11
performs communications with another communication apparatus 1
using communication parameters determined, by the communication
parameter determination portion 13. The transmission line
25 estimation portion 12 measures the characteristics of the

8

transmission line 2 at predetermined periodical timings and
estimates a state of the transmission line 2- The communication
parameter determination portion 13 sets or updates communication
parameters based on the result obtained when transmission line
5 estimation portion 12 estimates the transmission line 2.
Hereinafter, a method by which the thus configured
communication apparatus 1 estimates the characteristics of a
transmission line will be described. FIGS. 2 to 4 are diagrams
each showing an example of timings at which a transmission line
10 is: estimated by the communication apparatus 1 according to the
first embodiment of the present invention- FIG. 5 is a
communication sequence showing the procedure following which a
transmission line is estimated, by the communication apparatus 1
according to the first embodiment of the present invention.
15 In this embodiment, a case will be described in which in
the. transmission line 2 in the communication network system, a
noise with a certain pattern (the mark X in FIG. 2) is generated
with certain intervals as shown in FIG, 2, that is, the variation
cycle of the characteristics of the transmission line corresponds
20 to these certain intervals. In this case, the communication
control portion 11 in each of the communication apparatuses 1 that
constitute the communication network systemsets the beacon period,
which will be the communication period, in the following manner-
Herein, the beacon period refers to a time interval between when
25 a beacon is transmitted by the master unit and when its next beacon

9

is transmitted.
There is a case in which due to an influence of a power circuit
of, for example, a household electrical appliance that is connected
to a power line, the cycle of a noise pattern on the power line
5 is the same as the half cycle of a commercial power supply [50 Hz
or 60 Hz) . Accordingly, when assuming a communication network
system using a power line, it is necessary to consider the
characteristics of a transmission line-that has been synchronized
with the half cycle of the commercial power supply described above
10 (see sine waves in FIG. 2).
A point of the setting is that a "variation cycle L of the
characteristics of the transmission line is divided into n sets
of sections (n sections), a procedure is repeated in which
transmission line estimation is performed for only one section
15 among sections in one beacon period, and thus transmission Line
estimation is performed for all of the n sections. A beacon
period T for realizing this point is set based on "T=Lxm/n", where
n is an integer that is 2 or larger, and in is in integer that is
n or larger and whose greatest common measure with n is 1.
20 Furthermore an offset time is .set based on "Lxk/n", where k is
a real number that satisfies 0 like is set to enable a transmission line to be estimated within
one beacon period and section by section, it is possible to deal
with a variation of the transmission line quickly. It should be
25 noted that the offset time can be set freely if dealing with a

10

variation of the transmission line rapidly is not considered.
FIGS. 2 and 3 are examples in which n=3 and m=17. FIG. 4
is an example in which n=4 and xu=19. When assuming a communication
network system using a power line as described above, the beacon
5 period T is calculated using L=8.333 msec when the commercial power
supply frequency is 60 Hz and using L=10 msec when the commercial
power supply frequency is 50 Hz. In FIGS. 2 to 1, a description
of the beacon itself has been omitted. Furthermore, regarding
the Offset time, k=l6 in FIG. 2, k=15 in FIG. 3, and k=17 in FIG- 4.
10 AS seen in FIGS. 2 to 4, when the beacon period and the offset
time are set based on the above-described points, after the offset
time has passed, each of the transmission line estimation sections
does not have the same timing as that of the commercial power supply
cycle and slides therefrom. Therefore, it is possible to easily
15 realize the transmission line estimation that cities not overlap
the commercial power supply cycle and that is- continuous in time.
Referring to FIG. 5, the procedure following which a
transmission line is estimated by the communication apparatus 1
will be described in detail.
20 At the initial starting up such as when the power is turned
on, or upon detecting a change in the characteristics of a
transmission line, a communication apparatus 1 serving as a slave
unit (hereinafter, referred to as apparatus A) requests a
communication apparatus 1 serving as a master unit (hereinafter,
25 referred to as apparatus C) to allocate a time for estimating the

11

transmission line (step 1). When receiving the request to.
allocate a time for estimating the transmission Line from the
apparatus A, the apparatus C sends a beacon, to which information
on time allocation for estimating the transmission line is added,
5 during the next time of sending the beacon (step 2). This
Information on the time allocation for estimating the transmission
line refers to information showing sections that can be used for
estimating the transmission line, and is typically given as the
offset time from the starting time of the beacon period.
10 when receiving the beacon, to which the information on time
allocation for estimating the transmission line is added,, from
the apparatus C, the apparatus A measures the characteristics of
the transmission line based on this information, after the offset
time has passed since the beacon period started. In the example
15 in: FIG. 2, the characteristics of the transmission line are
measured in a transmission line estimation, section 2/3 (the
half-tone portion 2 in the drawing). A specific method for
measuring the characteristics of the transmission line is that
the apparatus A sends a communication apparatus 1 serving as a
20 slave unit of interest in the communication (hereinafter, referred
to as apparatus B) a request to estimate the transmission line
(step 3) , and receives a response, from the apparatus B, for the
request to estimate the transmission line (step 4). This
estimation on the transmission line is, for example, performed
25 in the following manner.
12

First, a predetermined estimation series as well as the
transmission line estimation request are sent from the apparatus A
to the apparatus B. Based on this estimation series, the
apparatus B calculates the receiving CNR (carrier to noise power
5 ratio). Next, according to the calculated receiving CNR, the
apparatus B creates a tonemap that specifies communication
parameters such as a subcarrier to be used and a modulation method.
for each subcarrier. An example of the tonemap is shown in FIG. 6,
Herein, the tonemap is constituted by the tone-map number for
10 discriminating this tonemap from other tonemaps, the subcarrier
number for identifying the subearrier of interest in this tonemap,
and information of use/non-useof the subcarrier and the modulation
factor. The information on the modulation factor of the subcarrier
may be information an the modulation type (16 QAM or 32 QAM, for
15 example) or. may be the number of bit allocation of the subcarrier
("4" in the case of 16 QAM, for example) shown in FIG, 6- Then,
the apparatus B responds to the apparatus A by sending the
transmission line estimation including the tonemap. It should
be noted that the above-described multi-carrier transmission
20 method is en example-, and other methods such as a spread spectrum
method also can be used. Furthermore, the information on the
receiving CNR is used for determining the communication parameters
but information other than this also can be used
with a similar process, the apparatus. A measure the
25 characteristics of the transmission line in the other transmission

13

line estimation sections (steps 5 to 10). In the example in FIG, 2,
the characteristics of the transmission line are measured in a
transmission line estimation section 1/3 (the half-tone portion 1
in the drawing) and a transmission line estimation section 3/3
5 (the half-tone portion 3 in the drawing), With this process, the
apparatus A completes the transmission line estimation in all of
these three divided transmission line estimation sections, that
is, acquisition of the tonemaps I step 11) . Then, among the
plurality of acquired tonemaps, the apparatus a selects one tonemap
10 that is optical for use in the communications-, and notifies the
apparatus B of it (step 12). With this process, the apparatuses A
and B can share the optimal tonemap. Hereinafter, the
communications are performed using this optimal tonemap.
An optimal tonemap is selected, for example, in the following
15 manner- in the example in FIG. 2, a noise is generated in the
transmission- line estimation sections 1/3 and 2/3, and. a noise
is not generated in the transmission line estimation section 3/3
(see FIG, 7 partially extracting and magnifying FIG- 2).
Therefore, the tonemap of the transmission line estimation
20 section 3/3.has the highest PHY rate. Accordingly, this tonemap
with the highest PHY rate is selected as the tonemap used for the
communication.
Even without acquiring all of the tonemaps of the
transmission line estimation sections, it is possible to select
25 an optimal tonentap among tonernaps that have been acquired when

14

a predetermined time-out period has passed.
As described above, according to the communication
apparatus 1 of the first embodiment of the present invention, it
is possible to easily realize transmission line estimation in a
5 distributed manner. Thus, the characteristics of the
transmission line are estimated and evaluated with a high precision,
and thus data can be sent and received at a high throughout.
In the first embodiment, the integers n and in are described
as fixed values, but they can be changed dynamically in accordance
10 with, for example, a change in the transmission line based on the-
estimation result of the transmission line, the value of the PHY
rate., or the' degree of a variation of the PHY rate.
Furthermore, in the communication sequence shown in FIG. 5,
a relevant apparatus other than the apparatuses A, B, and C is;
15 not described, but the process is performed typically as shown
in. FIG. 8.
Referring, to FIG. 8r information on time allocation for
estimating; the transmission line is added to a beacon sent from
the apparatus C. The information on the time allocation for
20 estimating the transmission line- not only specifies, for the
apparatus. A, a time during which a request to estimate the
transmission line can be sent to the apparatus B, but also prohibits
the apparatuses B, c, and others from transferring data. By
prohibiting apparatuses other than that sends the request from
25 transmitting in a time during which the request to estimate the

15

transmission line is sent (the half-tone period in FIG. 8), it
is possible to avoid a collision, for example, between the request
to estimate the transmission line and data.
In a time during which a response to the request to estimate
5 the transmission line is sent from the apparatus B to the
apparatus A, data transfer by the apparatuses A, B, and others
may be or may not be prohibited for the purpose of improving the
throughput in the data transfer. FIG. 8 is the communication
sequence in which data transfer is not prohibited. Herein, when
10 data transfer is not prohibited, it is preferable that the response
from the apparatus B is given the highest priority.
Furthermore, instead of a manner in which the receiver
apparatus B responds to the transmitter apparatus A by sending
the transmission line estimation at each time as described above,
15 the plurality of transmission line estimations may be sent at one
time, or the receiver apparatus B may select a tone-map based on
the plurality of transmission line estimations and notify the
transmitter apparatus A of the selected tonemap. In either case,
the effect of the present invention is not lost.
20 Second Embodiment
The first embodiment described above is a technique assuming
that the variation cycle of the characteristics, of the transmission
line is known in advance. Then, in a second embodiment below,
a technique -will be described in which an optimal beacon period
25 can be set automatically even when the variation cycle of the

16

characteristics .of the transmission line is not known in advance.
FOR example, a case will be described in which the
communication apparatus 1 can set both of a beacon period T1l
(FIG. 9) when the variation cycle L of the characteristics of the
5 transmission line , which is synchronized with a commercial power
supply frequency of 60 Hz, is 8.333 msec and when the integers n=3
and m=17, and a beacon period T2 (FIG. 10) when the variation
cycle L of the characteristics of the transmission line, which
is; synchronized with a commercial power supply frequency of 50 Hz,
10 is 10 msec and when the variables n=3 and m=l7. In this case,
the communication apparatus 1 estimates the transmission line in
all of the identical sections within a beacon period and acquires
a plurality of tonemaps. FIGS- 9 and 10 show a case of the
transmission line estimation section 2 (the half -tone portions
15 in the drawings). The offset time is given based on ""Lxk/n" (k
is a real number-that satisfies 0 10.
Herein, it is assumed that the actual commercial power supply
frequency is 60 Hz.
20 As a result, the variation cycle L of the characteristics
of the transmission line in the beacon period T1 is synchronized
more with a noise that is synchronized with the actual commercial
power supply frequency (6.0 Hz) in. the drawing (FIG. 9). Thus,
the characteristics of the transmission line at the transmission
25 line estimation sections 2 are substantially the same, and a

17

similar value for the communication parameter (PHY rate} of each
tonemap can be obtained in the plurality of acquired tonemaps,
so that it is determined that the correlation, regarding a noise,
between the beacon period T1 and the variation cycle L is high.
5 On the other hand, the variation cycle L of the
characteristics of the transmission line in the beacon period T2
is not synchronized with a noise that is synchronized with the
actual commercial power supply frequency (60 Hz) in the drawing
(FIG. 10). Thus, the characteristics of the transmission line
10 at the transmission line estimation sections 2 are different from
each other, and the communication parameter (PHY rate) of each
tonemap is different for each of the plurality of acquired tonemaps,
Therefore, it is determined that the correlation, regarding a noise,
between the beacon period T2 and the variation cycle L is low.
15 Based on the above-described points, it is determined that
the settings of a beacon period determined to have the highest
correlation is synchronized most with a noise that is actually
being generated- Accordingly, only by selecting the settings of
the beacon period with which the correlation is high, it is possible
20 to automatically set a beacon period that corresponds to the
variation cycle of the characteristics of the transmission line.
An optimal communication parameter that is noise-resistant
is selected by setting the beacon period according to the second
embodiment and then by performing the process according to the
25 first -embodiment.
18

The above-described embodiments can be realized also when
a CPU executes a program that can let the CPU execute the
above described procedure stored in e storage device (ROM., BAM,
or hard disk, for example). In this case, the program may be
5 executed after being stored in the storage device via a storage
medium, or may be executed directly on the storage medium. The
storage medium here includes a semiconductor memory such as a ROM
a RAM, and a f lash memory, a magnetic disk memory such as a flexible
disk and 5 hard, disk, an optical disk such as a CD-ROM, a DVD,
10 and a BD, and a memory card. Furthermore, the concept of the storage
medium also includes a communication medium such as a telephone
line and a carrier line.
Each of the functional blocks indicated by the broken line
in FIG. 1 may be realized by an LSI, which is an integrated circuit.
15 Each of the' functional blocks may be formed on a single chip one
by one, or a part or all of them may be formed on one chip. Although
an LSI is used in these embodiments, this circuit may be called
IC; system LSI, super LSI, or ultra LSI, depending on the difference
of the degree of integration.
20 It should be noted that the method for forming an integrated
circuit is not limited to using an LSI, and circuit integration
may be realized by a dedicated circuit: or a general purpose processor.
Furthermore, it is. possible to use an FPGA (field programmable
gate array) that can be programmed after an LSI is produced, and
25 a reconfigurable processor being capable of reconfiguring

19

connections and settings of circuit cells inside of the LSI.

possibility of, for example, application of biotechnology.
Hereinafter, an example will be described in which the
present invention that has been described in the embodiments is
applied to an actual network system, FIG. 11 is a diagram. showing
10 an example of a network system in which the present invention is
applied to high-speed power line transmission. In FIG. 11, an
IEEE/E1394 interface, a USB interface, or so forth provided in
multimedia equipment such as a personal computer, a DVD recorder,
a (digital TV, and a home server system is- connected to a power
15 line via an adaptor provided with the function of the present
invention. With this configuration, it is possible to construct
a network system in which digital data such as multimedia data
can be transmitted at a high speed via a power line serving as
a medium. In contrast to a conventional wired LAN, this system
20 does not require a network cable to be newly installed and can
use a power line having been installed already at home, office,
or so forth without any process as a network- line, so that a
significant convenience in terms of cost and simplicity of
installation is provided-
25 The above-described embodiment is an example in which

20

existing multimedia equipment is applied to power line
communications via an adaptor converting a. signal interface of
the existing equipment to an interface of the power line
communications. In future, however, the function of the present
5 invention is included in multimedia equipment, so that it becomes
possible to transmit data between the equipment via power codes
of the multimedia equipment. In this case there is no need for
the adaptor, the IEEE1394 cable, or the USB cable shown in FIG, 11,
and thus wiring is simplified. Furthermore, since connection to
10 the Internet via a router or connection to a wireless/wired LAN
using, for example, a hub is possible, so that it is possible to
expand a LAN system using the high-speed power line transmission
system of the present invention. Furthermore, in the provider line
transmission method, communication data runs via a power line.
15 Therefore, in contrast to a wireless LAN, there is no problem that
radio waves are intercepted, resulting in data leakage „ The power
line transmission method also has a security effect to protect
data. Data running on the power line can be protected by IPsec
in IP protocol, encoding the contents themselves, or other DRM
20 methods, for example.
As described above, by installing a QoS function including
a copyright protection function by encoding the contents and the
effect of the present invention (band allocation flexibly
addressing improvement in throughput increased retransmission,
25 and variation in traffic), AV contents with a high quality can
21

CLAIMS
1. A communication apparatus performing periodical
communications with another communication apparatus via a
5 transmission line, comprising:
a- communication control portion operable to set a
communication period to (Lxm/n) (L is a variation cycle of
characteristics of a transmission line, n is an integer that is
2 or larger, and in is an integer that is n or larger and whose
10 greatest common measure with n is 1) to perform communications,
a transmission line estimation portion operable to estimate
the characteristics of the transmission line within a time (L/n)
after a certain offset time has passed since the communication
period started, and
15 a communication parameter determination portion operable
to determine a communication parameter to be used by the
communication control portion,, based on a result of estimation
by the transmission line estimation portion,
20 2. The communication apparatus according to claim 1,
wherein the offset time is (Lxk/n) (k is a real number that
satisfies. 0 3. The communication apparatus according to claim 1,
25 wherein the transmission line estimation portion estimates

23

the characteristics of the transmission line at least n times.
4. The communication apparatus according to claim 1,
wherein the characteristics of the transmission line are
5 estimated at an initial starting up or upon detecting a change
in a state of the transmission line.
5. The communication apparatus according to claim 1,
wherein the communication period is a period of beacons sent
10 from a communication apparatus serving as a master unit.
6. The communication apparatus according to clam 5,
wherein a request to allocate a time for estimating the
Characteristics of the transmission line is sent to the
15 communication apparatus serving as the master unit.
7. The communication apparatus according to claim 6,
wherein allocation of a time for estimating the
characteristics of the transmission line is notified using a beacon
20 frame or a polling f frame to another communication apparatus, and
the characteristics of the- transmission line are estimated only
when permission is given.
8. The communication apparatus according to claim 1,
25 wherein the variation cycle I of the characteristics of the

24

transmission line is a half cycle of a commercial power supply,
cycle.
9 A transmission line estimation method executed by a
5 communication apparatus performing periodical communications
with another communication apparatus via a transmission line,
comprising:
setting a communication period to (Lxm/n) (L is a variation.
cycle of characteristics of a transmission line, n is an integer
10 that is 2 or larger, and in is an integer that is n or larger and
whose greatest common measure with n is 1) to perform
communications,
estimating the characteristics of the transmission line
within a time (L/n) after a certain offset time has passed since
15 the communication period started, and
determining a communication parameter to be used in the
communicating step, based on a result of estimation in the
estimating step.
20 10. An integrated circuit used for a communication
apparatus per forming periodical communications with another
communication apparatus via a transmission line
wherein circuits are integrated that function as:
a communication control portion operable to set a
25 communication period to (Lxm/n) [L is a variation cycle of
25

characteristics of a transmission line, n is an integer that is
2 or larger, and in is an integer that is n or larger and whose
greatest common measure with n is 1) to perform communication,
a transmission line estimation portion operable to
5 estimate the characteristics of the transmission line within a
time (L/n) after a certain offset time has passed since the
communication period started, and
a communication parameter determination portion
operable to determine a communication parameter to be used by the
10 communication control portion, based on a result of estimation
by; the transmission line estimation portion.

The variation cycle L of the characteristies of a transmission line is divided into a plurality of sections (n sections), a procedure is repeated in which transmission line estimation is performed for only one section among n sections in one beacon period and thus transmission line estimation is performed for all of the n section. The beacon period T is set based on (T=L,Lm/m),where n is an interger that is 2 or larger, and in is an interger that is n or larger and whose greatest common measure with n is 1.

Documents:

http://ipindiaonline.gov.in/patentsearch/GrantedSearch/viewdoc.aspx?id=pQiOOr6k4DiSHpUTBVvkgg==&loc=wDBSZCsAt7zoiVrqcFJsRw==

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Patent Number

270804

Indian Patent Application Number

744/KOLNP/2006

PG Journal Number

04/2016

Publication Date

22-Jan-2016

Grant Date

21-Jan-2016

Date of Filing

28-Mar-2006

Name of Patentee

PANASONIC CORPORATION

Applicant Address

1006, OAZA KADOMA, KADOMA-SHI, OSAKA 571-8501 JAPAN

Inventors:

#	Inventor's Name	Inventor's Address
1	YOSHIDA, SHIGEO	C/O. MATSUSHITA ELECTRIC INDUSTRIAL CO. LTD., 1006, OAZA KADOKA-SHI, KADOMA-SHI, OSAKA 571-8501 JAPAN
2	YASUKAWA, TOHRU	C/O. MATSUSHITA ELECTRIC INDUSTRIAL CO. LTD., 1006, OAZA KADOKA-SHI, KADOMA-SHI, OSAKA 571-8501 JAPAN
3	YAMAGUCHI, TSUYOSHI	1-4-40-410, NONAKAMINAMI YODOGAWA-KU, OSAKA-SHI, OSAKA 5320022 JAPAN
4	OHMI, SHINICHIRO	C/O. MATSUSHITA ELECTRIC INDUSTRIAL CO. LTD., 1006, OAZA KADOKA-SHI, KADOMA-SHI, OSAKA 571-8501 JAPAN

PCT International Classification Number

H04B 3/54

PCT International Application Number

PCT/JP2005/015499

PCT International Filing date

2005-08-19

PCT Conventions:

#	PCT Application Number	Date of Convention	Priority Country
1	2004-243920	2004-08-24	Japan