Esempio n. 1
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    def PointCloudCall(self,data): # 20 Hz As this function has highest frequency, good for update
        pointCloud_ = PointCloud2()
        pointCloud_ = data

        self.graphslam_PointCloud_pub.publish(pointCloud_) # for Graph slam

        self.nlosExclusionF_ = puNlosExclusion.nlosExclusion(self.calAngNNLOS)
        self.nlosExclusionF_.nlosExclusion_(self.posArr, self.GNSS_, 'statManu', self.excluSatLis) # statManu
        self.puGNSSPosCalF_prop = puGNSSPosCal.GNSSPosCal()
        if((len(self.GNSSNRAWlosDel.GNSS_Raws) > 1) and (self.GNSSNRAWlosDel.GNSS_Raws[-1].GNSS_time != self.GNSSNRAWlosDelTimeFlag)): # only if there is a change, there will conduct the calculation
            # print 'self.GNSSNRAWlosDel',len(self.GNSSNRAWlosDel.GNSS_Raws)
            self.puGNSSPosCalF_prop.iterPosCal(self.GNSSNRAWlosDel, 'WLSGNSS')
            self.GNSSNRAWlosDelTimeFlag = self.GNSSNRAWlosDel.GNSS_Raws[-1].GNSS_time
            navfix_ = NavSatFix()
            llh_ = []
            llh_ = ecef2llh.xyz2llh(self.puGNSSPosCalF_prop.ecef_)
            navfix_.header.stamp.secs = self.GNSSNRAWlosDel.GNSS_Raws[-1].GNSS_time
            navfix_.latitude = float(llh_[0])
            navfix_.longitude = float(llh_[1])
            navfix_.altitude = float(llh_[2])
            self.propGNSS_Navfix_pub.publish(navfix_)

            # for Graph slam
            graphNavfix_ = NavSatFix()
            graphNavfix_ = navfix_
            graphNavfix_.header = pointCloud_.header
            self.graphslam_Navfix_pub.publish(graphNavfix_)
            # for Graph slam
            geopoint = GeoPointStamped()
            geopoint.header = graphNavfix_.header
            geopoint.position.latitude = float(llh_[0])
            geopoint.position.longitude = float(llh_[1])
            geopoint.position.altitude = float(llh_[2])
            self.graphslam_GeoPoint_pub.publish(geopoint)
Esempio n. 2
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    def iterPosCal(self, GNSS_one_epoch_, calMode):
        iterations = 0
        itera_x = 0
        itera_y = 0
        itera_z = 0
        self.calMode = calMode
        self.getSatNum(GNSS_one_epoch_)  # get satellites numbers
        if (self.calMode
                == 'LSGNSS') and (self.GPSNum >= 4) and (self.BeiNum > 1):
            itera_x, itera_y, itera_z, itera_b_GPS, itera_b_Beidou, itera_bias_ = self.LSGNSSPosCalStep(
                GNSS_one_epoch_, 0.1, 0.1, 0.1, 1.0,
                1.0)  # first iteration from (0.1, 0.1, 0.1, 1.0)
            self.iterations_ = self.iterations_ + 1
            while (
                    itera_bias_ > 1e-4
            ) and iterations < 10:  # threshold for iterations:value and times
                itera_x, itera_y, itera_z, itera_b_GPS, itera_b_Beidou, itera_bias_ = self.LSGNSSPosCalStep(
                    GNSS_one_epoch_, itera_x, itera_y, itera_z, itera_b_GPS,
                    itera_b_Beidou)  # iteration
                self.iterations_ = self.iterations_ + 1
                iterations = iterations + 1  # add one iteration
        elif (self.calMode == 'LSGPS') and (self.GPSNum >= 4):
            itera_x, itera_y, itera_z, itera_b, itera_bias_ = self.LSGPSPosCalStep(
                GNSS_one_epoch_, 0.1, 0.1, 0.1,
                1.0)  # first iteration from (0.1, 0.1, 0.1, 1.0)
            self.iterations_ = self.iterations_ + 1
            while (
                    itera_bias_ > 1e-4
            ) and iterations < 10:  # threshold for iterations:value and times
                itera_x, itera_y, itera_z, itera_b, itera_bias_ = self.LSGPSPosCalStep(
                    GNSS_one_epoch_, itera_x, itera_y, itera_z, itera_b)
                self.iterations_ = self.iterations_ + 1
                iterations = iterations + 1  # add one iteration
        elif (self.calMode
              == 'WLSGNSS') and (self.GPSNum >= 4) and (self.BeiNum > 1):
            itera_x, itera_y, itera_z, itera_b_GPS, itera_b_Beidou, itera_bias_ = self.WLSGNSSPosCalStep(
                GNSS_one_epoch_, 0.1, 0.1, 0.1, 1.0,
                1.0)  # first iteration from (0.1, 0.1, 0.1, 1.0)
            self.iterations_ = self.iterations_ + 1
            while (
                    itera_bias_ > 1e-4
            ) and iterations < 10:  # threshold for iterations:value and times
                itera_x, itera_y, itera_z, itera_b_GPS, itera_b_Beidou, itera_bias_ = self.WLSGNSSPosCalStep(
                    GNSS_one_epoch_, itera_x, itera_y, itera_z, itera_b_GPS,
                    itera_b_Beidou)  # iteration
                self.iterations_ = self.iterations_ + 1
                iterations = iterations + 1  # add one iteration
                print 'itera_b_GPS', itera_b_GPS, 'itera_b_Beidou-----------------------------------------', itera_b_Beidou

        self.ecef_.append(float(itera_x))
        self.ecef_.append(float(itera_y))
        self.ecef_.append(float(itera_z))
        self.pseudoResCal(GNSS_one_epoch_)
        self.PosError()
        self.llh_ = ecef2llh.xyz2llh(self.ecef_)  # ecef to llh coordinates
        iterations = 0.0  # initialize iterations variable
Esempio n. 3
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 def CallGNSS_(self, data):  # GNSS data # 1Hz
     self.GNSS_ = data
     self.puGNSSPosCalF_ = puGNSSPosCal.GNSSPosCal()
     self.puGNSSPosCalF_.iterPosCal(self.GNSS_, 'WLSGNSS')
     navfix_ = NavSatFix()
     llh_ = []
     llh_ = ecef2llh.xyz2llh(self.puGNSSPosCalF_.ecef_)
     navfix_.header.stamp.secs = self.GNSS_.GNSS_Raws[-1].GNSS_time
     navfix_.latitude  = float(llh_[0])
     navfix_.longitude = float(llh_[1])
     navfix_.altitude  = float(llh_[2])
     self.GNSS_Navfix_pub.publish(navfix_) # print 'ecef',self.puGNSSPosCalF_.ecef_,'llh',llh_
Esempio n. 4
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    def PointCloudCall(
            self, data
    ):  # 20 Hz As this function has highest frequency, good for update
        self.pointCloud_ = PointCloud2()
        self.pointCloud_ = data
        # self.graphslam_PointCloud_pub.publish(self.pointCloud_) # for Graph slam

        self.nlosExclusionF_ = puNlosExclusion.nlosExclusion(self.calAngNNLOS)
        self.nlosExclusionF_.nlosExclusion_(self.posArr, self.GNSS_,
                                            'statManu_ExclusionOpenLoop',
                                            self.excluSatLis)  # statManu
        self.puGNSSPosCalF_prop = puGNSSPosCal.GNSSPosCal()
        if ((len(self.GNSSNRAWlosDel.GNSS_Raws) > 1)
                and (self.GNSSNRAWlosDel.GNSS_Raws[-1].GNSS_time !=
                     self.GNSSNRAWlosDelTimeFlag)
            ):  # only if there is a change, there will conduct the calculation
            # print 'self.GNSSNRAWlosDel',len(self.GNSSNRAWlosDel.GNSS_Raws)
            self.puGNSSPosCalF_prop.iterPosCal(self.GNSSNRAWlosDel, 'WLSGNSS')
            self.GNSSNRAWlosDelTimeFlag = self.GNSSNRAWlosDel.GNSS_Raws[
                -1].GNSS_time
            navfix_ = NavSatFix()
            llh_ = []
            llh_ = ecef2llh.xyz2llh(self.puGNSSPosCalF_prop.ecef_)
            navfix_.header.stamp.secs = self.GNSSNRAWlosDel.GNSS_Raws[
                -1].GNSS_time
            navfix_.latitude = float(llh_[0])
            navfix_.longitude = float(llh_[1])
            navfix_.altitude = float(llh_[2])
            self.propGNSS_Navfix_pub.publish(navfix_)

            # for Graph slam
            graphNavfix_ = NavSatFix()
            graphNavfix_ = navfix_
            graphNavfix_.header = self.pointCloud_.header
            self.graphslam_Navfix_pub.publish(graphNavfix_)
            # for Graph slam
            geopoint = GeoPointStamped()
            geopoint.header = graphNavfix_.header

            # calculate the ENU coordiantes  initialLLH
            enu_ = pugeomath.transformEcefToEnu(self.initialLLH,
                                                self.puGNSSPosCalF_prop.ecef_)
            print 'enu_ ->: ', enu_

            geopoint.position.latitude = float(enu_[0])
            geopoint.position.longitude = float(enu_[1])
            # geopoint.position.altitude = float(llh_[2]) # use this to save the covariance in altitude component
            geopoint.position.altitude = self.GNSSNRAWlosDel.GNSS_Raws[
                -1].snr * self.HDOPProp  # save the covariance
            self.graphslam_GeoPoint_pub.publish(geopoint)
 def PointCloudCall(self,data): # 20 Hz As this function has highest frequency, good for update
     pointCloud_ = PointCloud2()
     pointCloud_ = data
     self.nlosExclusionF_ = puNlosExclusion.nlosExclusion(self.calAngNNLOS)
     self.nlosExclusionF_.nlosExclusion_(self.posArr, self.GNSS_, 'statAuto', self.excluSatLis)
     self.puGNSSPosCalF_prop = puGNSSPosCal.GNSSPosCal()
     if(len(self.GNSSNRAWlosDel.GNSS_Raws) > 1):
         # print 'self.GNSSNRAWlosDel',len(self.GNSSNRAWlosDel.GNSS_Raws)
         self.puGNSSPosCalF_prop.iterPosCal(self.GNSSNRAWlosDel, 'WLSGNSS')
         navfix_ = NavSatFix()
         llh_ = []
         llh_ = ecef2llh.xyz2llh(self.puGNSSPosCalF_prop.ecef_)
         navfix_.header.stamp.secs = self.GNSSNRAWlosDel.GNSS_Raws[-1].GNSS_time
         navfix_.latitude = float(llh_[0])
         navfix_.longitude = float(llh_[1])
         navfix_.altitude = float(llh_[2])
         self.propGNSS_Navfix_pub.publish(navfix_)
Esempio n. 6
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    def standardGT2kml(self):
        print 'begin read standard data'
        self.Fcsv_GNSS = csv.reader(
            open('/home/wws/map_trajectory.csv',
                 'r'))  # read csv context to csv_reader variable
        for rowCsv in self.Fcsv_GNSS:
            # self.lat_.append(float(rowCsv[1]))
            # self.lon_.append(float(rowCsv[2]))
            east = rowCsv[1]
            north = rowCsv[2]
            up = rowCsv[3]
            prex_ = float(east)
            prey_ = float(north)

            origin_azimuth = 348.747632943 + 180 - 1.35  # 1.5
            theta = -1 * (origin_azimuth - 90) * (3.141592 / 180.0)
            # east = (prex_ * cos(theta) - prey_ * sin(theta)) - 1.3
            # north = (prex_ * sin(theta) + prey_ * cos(theta)) + 1.3
            east = (prex_ * cos(theta) - prey_ *
                    sin(theta)) + 1.6  # best suit for data in moko east
            north = (prex_ * sin(theta) +
                     prey_ * cos(theta)) + 1.3  # best suit moko east

            self.ENU = []
            self.ENU.append(east)
            self.ENU.append(north)
            self.ENU.append(up)
            self.ecef = enu2ecef.enu2ecef(self.oriLLH, self.ENU)
            print 'self.ENU-> ', self.ENU, '\n'
            print 'self.ecef-> ', self.ecef, '\n'
            self.llh_cal = []
            self.llh_cal = ecef2llh.xyz2llh(self.ecef)
            self.lat_.append(float(self.llh_cal[0]))
            self.lon_.append(float(self.llh_cal[1]))
            print 'self.llh_cal-> ', self.llh_cal, '\n'
        print 'finish tranversal standard data', len(self.lat_)
Esempio n. 7
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def csv2topic():
    # In ROS, nodes are uniquely named. If two nodes with the same
    # node are launched, the previous one is kicked off. The
    # anonymous=True flag means that rospy will choose a unique
    # name for our 'listener' node so that multiple listeners can
    # run simultaneously.
    rospy.init_node('csv2topic',
                    anonymous=True)  #initialize node with specific node name
    GNSS_Raw_pub = rospy.Publisher(
        'GNSS_RAW', GNSS_Raw_Array,
        queue_size=10)  #customerized GNSS raw data ros message
    Navsatfix_pub = rospy.Publisher(
        'navsatfix_llh', NavSatFix,
        queue_size=10)  #standard GNSSs meaasge with lat and longt
    rospy.Subscriber('GNSS_exclued_data', GNSS_Raw_Array,
                     callback_GNSS_data_after_NLOS_exclusion)
    rospy.Subscriber('Satellite_Info', Satellite_Info,
                     callback_Satellite_NLOS_exclusion)

    GNSS_Raw_Array_1 = GNSS_Raw_Array(
    )  #create an variable in GNSS_Raw_Array format
    GNSS_options = 1  # 0-GPS only  1-hybrid GNSS (GPS+Beidou)
    sate_index_range = 330  # GPS only (sate_index_range=33)  Hybrid GNSS positioning (sate_index_range=330)
    line_index = 0  # variable represents line index in csv file
    gnss_time = 0  # GNSS time contained in csv file for each epoch (epoch: each time point)
    previous_gnss_time = 0.0  # previous GNSS time contained in csv file for each epoch (epoch: each time point)
    previoustime = time.time()  #initialize variable
    currenttime = time.time()  #initialize variable
    plot_time = 0.0
    #get data from .csv file--------------------begin----------------------------
    for row_csv in csv_reader:  #index all rows in csv file
        plt.figure(1)  # create figure 1
        ax1 = plt.subplot(3, 1, 1)
        ax2 = plt.subplot(3, 1, 2)
        ax3 = plt.subplot(3, 1, 3)
        gnss_time = row_csv[0]  #get first data in each row (GNSS time exactly)
        GNSS_Raw_1 = GNSS_Raw(
        )  # create customerized variable in GNSS_Raw format (element for GNSS_Raw_Array)
        NavSatFix_llh = NavSatFix(
        )  # creat standard variable in NavSatFix format
        # print '--------------begin one row----------'
        # print row_csv[12],len(row_csv),type(row_csv)
        # data_test=float(row_csv[3])
        GNSS_Raw_1.GNSS_time = float(
            row_csv[0])  # GNSS time contained in csv file
        GNSS_Raw_1.total_sv = float(
            row_csv[1]
        )  # total sitellites in one epoch (epoch: each time point)
        GNSS_Raw_1.prn_satellites_index = float(
            row_csv[2]
        )  # satellite index in this epoch (epoch: each time point)
        GNSS_Raw_1.pseudorange = float(row_csv[3]) - float(row_csv[7]) - float(
            row_csv[8]) + float(row_csv[9])  # pseudorange measurement
        GNSS_Raw_1.snr = float(
            row_csv[4])  # signal noise ratio for this satellite
        GNSS_Raw_1.elevation = float(
            row_csv[5])  # elevation for this satellite and receiver
        GNSS_Raw_1.azimuth = float(row_csv[6])  # azimuth for this satellite
        GNSS_Raw_1.err_tropo = float(row_csv[7])  # troposphere error in meters
        GNSS_Raw_1.err_iono = float(row_csv[8])  # ionophere error in meters
        GNSS_Raw_1.sat_clk_err = float(
            row_csv[9])  # satellite clock bias caused error
        GNSS_Raw_1.sat_pos_x = float(
            row_csv[10])  # satellite positioning in x direction
        GNSS_Raw_1.sat_pos_y = float(
            row_csv[11])  # satellite positioning in y direction
        GNSS_Raw_1.sat_pos_z = float(
            row_csv[12])  # satellite positioning in Z direction
        GNSS_Raw_1.visable = 0  # satellite visability juded by NLOS exclusion
        if ((previous_gnss_time == gnss_time)
                or (line_index == 0)):  # differentiate each epoch
            if (
                    GNSS_Raw_1.prn_satellites_index < sate_index_range
            ):  ## GPS only (sate_index_range=33)  Hybrid GNSS positioning (sate_index_range=330)
                GNSS_Raw_Array_1.GNSS_Raws.append(
                    GNSS_Raw_1)  #save data for each epoch
        else:
            GNSS_Raw_Array_1.header.frame_id = 'GNSS_Raw_'  # set frame_id
            # for del_index in range(len(GNSS_Raw_Array_1.GNSS_Raws)):  # index all the satellites' visability in one epoch
            #     if (del_index >= len(GNSS_Raw_Array_1.GNSS_Raws)):
            #         break
            #     if (GNSS_Raw_Array_1.GNSS_Raws[del_index].elevation <= 20):  # if satellite is low elevation satellite, delete this satellite
            #         del GNSS_Raw_Array_1.GNSS_Raws[del_index]  # delete the low elevation satellites
            GNSS_Raw_pub.publish(
                GNSS_Raw_Array_1
            )  # publish GNSS_Raw_Array topic after one epoch
            plot_time = plot_time + 1
            plot_RawHdop.append(float(
                DopCalculation(GNSS_Raw_Array_1)))  # calculate dop matrix
            plot_RawHdopTim.append(float(GNSS_Raw_1.GNSS_time))
            GPS_satellite_number = []
            Beidou_satellite_number = []
            GPS_satellite_number, Beidou_satellite_number = get_GPS_Beidou_satellite_numbers(
                GNSS_Raw_Array_1)
            plot_Total_sate.append(
                len(GPS_satellite_number) +
                len(Beidou_satellite_number))  # save the Total satellites
            plot_Beidou_sate.append(
                len(Beidou_satellite_number))  # save the Beidou satellites
            plot_GPS_sate.append(
                len(GPS_satellite_number))  # save the GPS satellites
            plot_Total_sate_Tim.append(float(
                GNSS_Raw_1.GNSS_time))  # save the tinme for total satellites
            print ' one epoch...... ', 'BeiN', len(
                GPS_satellite_number), 'GPSN', len(
                    Beidou_satellite_number
                )  # indicates one epoch (epoch: each time point)
            iterations = 0.0  # initialize iterations times
            itera_x = 0.0  # initialize receiver's position x
            itera_y = 0.0  # initialize receiver's position y
            itera_z = 0.0  # initialize receiver's position z
            itera_b = 0.0  # initialize receiver's clock bias error of GPS only positioning in meters
            itera_bias_ = 0.0  # initialize total bias of GPS only positioning in each iteration
            itera_b_GPS = 0.0  # initialize receiver's clock bias error of GPS in Hybrid GNSS positioning in meters
            itera_b_Beidou = 0.0  # initialize receiver's clock bias error of Beidou in Hybrid GNSS positioning in meters
            if (len(GNSS_Raw_Array_1.GNSS_Raws) > 3) and (
                    GNSS_options == 0
            ):  #at least four satellites for least square calculation with GPS only
                itera_x, itera_y, itera_z, itera_b, itera_bias_ = weighted_lesat_square_GNSS_positioning(
                    GNSS_Raw_Array_1, 0.1, 0.1, 0.1,
                    1.0)  # first iteration from (0.1, 0.1, 0.1, 1.0)
                while (
                        itera_bias_ > 1e-4
                ) and iterations < 10:  #threshold for iterations:value and times
                    itera_x, itera_y, itera_z, itera_b, itera_bias_ = weighted_lesat_square_GNSS_positioning(
                        GNSS_Raw_Array_1, itera_x, itera_y, itera_z,
                        itera_b)  # iteration
                    iterations = iterations + 1  # add one iteration
            if (len(GNSS_Raw_Array_1.GNSS_Raws) > 4) and (
                    len(Beidou_satellite_number) >= 1
            ) and (
                    GNSS_options == 1
            ):  # at least five satellites (at least one Beidou) for least square calculation with Hybrid GNSS
                itera_x, itera_y, itera_z, itera_b_GPS, itera_b_Beidou, itera_bias_ = weighted_lesat_square_GNSS_positioning_hybrid_GNSS(
                    GNSS_Raw_Array_1, 0.1, 0.1, 0.1, 1.0,
                    1.0)  # first iteration from (0.1, 0.1, 0.1, 1.0)
                while (
                        itera_bias_ > 1e-4
                ) and iterations < 10:  # threshold for iterations:value and times
                    itera_x, itera_y, itera_z, itera_b_GPS, itera_b_Beidou, itera_bias_ = weighted_lesat_square_GNSS_positioning_hybrid_GNSS(
                        GNSS_Raw_Array_1, itera_x, itera_y, itera_z,
                        itera_b_GPS, itera_b_Beidou)  # iteration
                    iterations = iterations + 1  # add one iteration
            print 'iterations=', iterations, 'itera_bias_=', itera_bias_  # how many iterations after sucessfully least square calculation, total bioas
            print 'skyplot_python_subscribe.plot_total_sate', skyplot_python_subscribe.plot_total_sate
            iterations = 0.0  #initialize iterations variable
            #get llh information
            if (
                    itera_x != 0
            ):  # make sure that itera_x is not zero value, otherwise arctan(itera_y/itera_x) in xyz2llh function
                itera_xyz = []  # create a list to save ecef coordiante
                itera_xyz.append(float(itera_x))  # save x value
                itera_xyz.append(float(itera_y))  # save y value
                itera_xyz.append(float(itera_z))  # save z value
                llh_output = ecef2llh.xyz2llh(
                    itera_xyz)  # ecef to llh coordinates
                if (latDic.has_key(str(int(gnss_time)))):
                    truthList = []  # create a list to save ground truth
                    truthList.append(float(latDic[str(
                        int(gnss_time))]))  # get truth lat
                    truthList.append(float(lonDic[str(
                        int(gnss_time))]))  # get truth lon
                    xyzTruth = llh2ecef.llh2xyz(truthList)  # get xyz from ecef
                    delt_x = (xyzTruth[0] - itera_xyz[0]) * (
                        xyzTruth[0] - itera_xyz[0])  # get delta x (Error in x)
                    delt_y = (xyzTruth[1] - itera_xyz[1]) * (
                        xyzTruth[1] - itera_xyz[1])  # get delta y (Error in y)
                    delt_z = (xyzTruth[2] - itera_xyz[2]) * (
                        xyzTruth[2] - itera_xyz[2])  # get delta z (Error in z)
                    delErrTem = sqrt(delt_x + delt_y + delt_z)
                    if (delErrTem > 100):
                        delErrTem = 100
                    plot_RGNSSyGtBias.append(delErrTem)  # save error
                    GNSSTimeList.append(float(GNSS_Raw_1.GNSS_time))
                    # print 'xyzTruth=',xyzTruth
                # print 'llh output=',llh_output,'line_index=',line_index,'itera_xyz=',itera_xyz # llh coordinates and line index
                NavSatFix_llh.latitude = float(
                    llh_output[0])  # save latitude to NavSatFix_llh message
                NavSatFix_llh.longitude = float(
                    llh_output[1])  # save longitude to NavSatFix_llh message
                plot_RawGNSSlat.append(float(
                    llh_output[0]))  # save raw GNSS latitude for plotting
                plot_RawGNSSlon.append(float(
                    llh_output[1]))  # save raw GNSS longitude for plotting
                Navsatfix_pub.publish(
                    NavSatFix_llh)  #publish NavSatFix_llh message
                #route of vehicles in matplotlib
                plt.sca(ax1)
                # plt.plot(lonTruth,latTruth, 'o', color='r',label="ground truth")  # plot discrete position of receiver (Ground Truth)
                # plt.plot(plot_RawGNSSlon , plot_RawGNSSlat,'*', color='g',label="GNSS positioning") # plot discrete position of receiver
                listLatRaw.append(float(llh_output[0]))  # save Raw Lat
                listLonRaw.append(float(llh_output[1]))  # save Raw lon
            if (len(list_lat) > 0):
                plot_ExclLat.append(float(list_lon[0]))
                plot_ExclLon.append(float(list_lat[0]))
                # plt.plot(list_lon,list_lat, '*', color='g')
                del list_lat[:]
                del list_lon[:]
            plt.plot(plot_Beidou_sate_excluded_Tim,
                     plot_Beidou_sate_excluded_,
                     '*-',
                     color='r',
                     label="Excluded Beidou numbers"
                     )  # plot discrete position of receiver
            plt.plot(plot_Beidou_sate_excluded_Tim,
                     plot_GPS_sate_excluded_,
                     '*-',
                     color='g',
                     label="Excluded GPS Numbers"
                     )  # plot discrete position of receiver
            plt.plot(plot_Total_sate_Tim,
                     plot_Beidou_sate,
                     '*-',
                     linewidth='2',
                     color='b',
                     label="total Beid Numbers"
                     )  # plot discrete position of receiver
            plt.plot(plot_Total_sate_Tim,
                     plot_GPS_sate,
                     '*-',
                     linewidth='2',
                     color='fuchsia',
                     label="total GPS Numbers"
                     )  # plot discrete position of receiver

            ax1.legend(loc=10, ncol=3, shadow=True)
            # plt.title('satellite exclusion numbers') # set title
            plt.sca(ax2)  # plot in another sca
            plt.plot(GNSSTimeList,
                     plot_RGNSSyGtBias,
                     '*-',
                     color='g',
                     label="RawGNSSerr")  # raw GNSS positioning error
            plt.plot(plot_ExclGNSSyGtBiasTim,
                     plot_ExclGNSSyGtBias,
                     '*-',
                     linewidth='4',
                     color='r',
                     label="ExclGNSSerr")  # excluded GNSS positioning error
            ax2.legend(loc=9, ncol=3, shadow=True)
            plt.sca(ax3)  # plot in another sca
            plt.xlabel('t/s---GPS time', fontdict={'size': 15, 'color': 'r'})
            plt.plot(plot_RawHdopTim,
                     plot_RawHdop,
                     '*-',
                     linewidth='2',
                     color='g',
                     label="HDOP error")  # Raw GNSS Hdop error
            plt.plot(plot_excludedHdopTim,
                     plot_excludedHdop,
                     '*-',
                     linewidth='4',
                     color='r',
                     label="Excluded HDOP error")  # excluded GNSS Hdop error
            ax3.legend(loc=9, ncol=3, shadow=True)
            plt.draw()  # draw figure
            plt.pause(
                0.00000000001)  # pause for a while to immitate multi-thread
            time.sleep(0.4)  # control frequency of topic publishment
            plt.clf()  # clean the plt

            del GNSS_Raw_Array_1.GNSS_Raws[:]  #relief the content
            if (
                    GNSS_Raw_1.prn_satellites_index < sate_index_range
            ):  # # GPS only (sate_index_range=33)  Hybrid GNSS positioning (sate_index_range=330)
                GNSS_Raw_Array_1.GNSS_Raws.append(
                    GNSS_Raw_1)  # save GNSS_Raws to GNSS_Raw_Array_1 variable
        previous_gnss_time = gnss_time  # save time to previous time
        line_index = line_index + 1  # add one line index
    with open(
            filename,
            'w') as file_object:  # save listLatRaw and listLonRaw to csv file
        for sav_idx in range(len(listLatWiNLOSExc)):
            str2 = str(listLatWiNLOSExc[sav_idx]) + ',' + str(
                listLonWiNLOSExc[sav_idx])
            file_object.write(str2)
            file_object.write('\n')
            # print 'str1 in one line....',str2
    # print 'finish saving llhWitNLOSExlu.csv ... with ',listLatWiNLOSExc,'items'
    with open(filename_2, 'w'
              ) as file_object_2:  # save listLatRaw and listLonRaw to csv file
        for sav_idx_2 in range(len(listLatRaw)):
            str1 = str(listLatRaw[sav_idx_2]) + ',' + str(
                listLonRaw[sav_idx_2])
            file_object_2.write(str1)
            file_object_2.write('\n')
    # plt.draw()
    rate = rospy.Rate(1)  # 1hz
    while not rospy.is_shutdown():
        hello_str = "current time is %s" % rospy.get_time()
        rate.sleep()
    """
Esempio n. 8
0
def callback_GNSS_data_after_NLOS_exclusion(
    data
):  # callback function: get GNSS data (after NLOS exclusion) and implement least square
    GNSS_exclusion_Array_1 = GNSS_Raw_Array(
    )  # create an variable in GNSS_Raw_Array format to save GNSS data after exclusion
    GNSS_exclusion_Array_1 = data  # get data from ros topic
    GNSS_options = 1  # 0-GPS only  1-hybrid GNSS (GPS+Beidou)
    sate_index_range = 330  # GPS only (sate_index_range=33)  Hybrid GNSS positioning (sate_index_range=330)
    GPS_satellite_number = []
    Beidou_satellite_number = []
    GPS_satellite_number, Beidou_satellite_number = get_GPS_Beidou_satellite_numbers(
        GNSS_exclusion_Array_1)  # get satellites numbers
    iterations = 0.0  # initialize iterations times
    itera_x = 0.0  # initialize receiver's position x
    itera_y = 0.0  # initialize receiver's position y
    itera_z = 0.0  # initialize receiver's position z
    itera_b = 0.0  # initialize receiver's clock bias error of GPS only positioning in meters
    itera_bias_ = 0.0  # initialize total bias of GPS only positioning in each iteration
    itera_b_GPS = 0.0  # initialize receiver's clock bias error of GPS in Hybrid GNSS positioning in meters
    itera_b_Beidou = 0.0  # initialize receiver's clock bias error of Beidou in Hybrid GNSS positioning in meters
    if (len(GNSS_exclusion_Array_1.GNSS_Raws) > 3) and (
            GNSS_options == 0
    ):  # at least four satellites for least square calculation with GPS only
        itera_x, itera_y, itera_z, itera_b, itera_bias_ = weighted_lesat_square_GNSS_positioning(
            GNSS_exclusion_Array_1, 0.1, 0.1, 0.1,
            1.0)  # first iteration from (0.1, 0.1, 0.1, 1.0)
        while (
                itera_bias_ > 1e-4
        ) and iterations < 10:  # threshold for iterations:value and times
            itera_x, itera_y, itera_z, itera_b, itera_bias_ = weighted_lesat_square_GNSS_positioning(
                GNSS_exclusion_Array_1, itera_x, itera_y, itera_z,
                itera_b)  # iteration
            iterations = iterations + 1  # add one iteration
    if (len(GNSS_exclusion_Array_1.GNSS_Raws) > 4) and (
            len(Beidou_satellite_number) >= 1
    ) and (
            GNSS_options == 1
    ):  # at least five satellites (at least one Beidou) for least square calculation with Hybrid GNSS
        itera_x, itera_y, itera_z, itera_b_GPS, itera_b_Beidou, itera_bias_ = weighted_lesat_square_GNSS_positioning_hybrid_GNSS(
            GNSS_exclusion_Array_1, 0.1, 0.1, 0.1, 1.0,
            1.0)  # first iteration from (0.1, 0.1, 0.1, 1.0)
        while (
                itera_bias_ > 1e-4
        ) and iterations < 10:  # threshold for iterations:value and times
            itera_x, itera_y, itera_z, itera_b_GPS, itera_b_Beidou, itera_bias_ = weighted_lesat_square_GNSS_positioning_hybrid_GNSS(
                GNSS_exclusion_Array_1, itera_x, itera_y, itera_z, itera_b_GPS,
                itera_b_Beidou)  # iteration
            iterations = iterations + 1  # add one iteration
    # print 'iterations after NLOS exclusion=', iterations, 'itera_bias_=', itera_bias_  # how many iterations after sucessfully least square calculation, total bioas
    iterations = 0.0  # initialize iterations variable
    # get llh information
    if (
            itera_x != 0
    ):  # make sure that itera_x is not zero value, otherwise arctan(itera_y/itera_x) in xyz2llh function
        itera_xyz = []  # create a list to save ecef coordiante
        itera_xyz.append(float(itera_x))  # save x value
        itera_xyz.append(float(itera_y))  # save y value
        itera_xyz.append(float(itera_z))  # save z value
        llh_output = ecef2llh.xyz2llh(itera_xyz)  # ecef to llh coordinates
        list_lat.append(float(llh_output[0]))  # save latitude
        list_lon.append(float(llh_output[1]))  # save longitude
        listLatWiNLOSExc.append(float(
            llh_output[0]))  # save latitude for csv saving
        listLonWiNLOSExc.append(float(
            llh_output[1]))  # save latitude for csv saving
        if (latDic.has_key(
                str(int(GNSS_exclusion_Array_1.GNSS_Raws[0].GNSS_time)))):
            truthList = []  # create a list to save ground truth
            truthList.append(
                float(latDic[str(
                    int(GNSS_exclusion_Array_1.GNSS_Raws[0].GNSS_time))])
            )  # get truth lat
            truthList.append(
                float(lonDic[str(
                    int(GNSS_exclusion_Array_1.GNSS_Raws[0].GNSS_time))])
            )  # get truth lon
            xyzTruth = llh2ecef.llh2xyz(truthList)  # get xyz from ecef
            delt_x = (xyzTruth[0] - itera_xyz[0]) * (
                xyzTruth[0] - itera_xyz[0])  # get delta x (Error in x)
            delt_y = (xyzTruth[1] - itera_xyz[1]) * (
                xyzTruth[1] - itera_xyz[1])  # get delta y (Error in y)
            delt_z = (xyzTruth[2] - itera_xyz[2]) * (
                xyzTruth[2] - itera_xyz[2])  # get delta z (Error in z)
            delErrTem = sqrt(delt_x + delt_y + delt_z)
            if (delErrTem > 100):
                delErrTem = 100
            plot_ExclGNSSyGtBias.append(float(delErrTem))  # save error
            plot_ExclGNSSyGtBiasTim.append(
                float(GNSS_exclusion_Array_1.GNSS_Raws[0].GNSS_time))
            # print 'xyzTruth afer exclusion=', xyzTruth
        # print 'llh output after NLOS exclusion==', llh_output
    plot_excludedHdop.append(float(DopCalculation(GNSS_exclusion_Array_1)))
    plot_excludedHdopTim.append(
        float(GNSS_exclusion_Array_1.GNSS_Raws[0].GNSS_time))
    del GNSS_exclusion_Array_1.GNSS_Raws[:]  # relief the content