Stand-level

Once all trees were detected from the normalized point cloud and the tree list was generated, metrics and variables at stand level can be estimated. These estimations can be based on different plot designs, that are circular fixed area, k-tree and angle-count plots. The sizes of the plots can be regulated by defining the radius, k and the basal area factor (BAF) respectively.

Computing stand-level metrics and variables

In order to calculate metrics and variables at stand level, the function metrics.variables is applied as follows:

metrics <- metrics.variables(tree.tls = tree.list, 
                  tree.ds = tree.ds, tree.field = tree.field,
                  plot.design = c("fixed.area", "k.tree", "angle.count"),
                  plot.parameters = data.frame(radius = 10, k = 10, BAF = 1),
                  scan.approach = "single", var.metr = NULL,
                  dbh.min = 4, h.min = 1.3, max.dist = Inf, 
                  dir.data = dir.data, save.result = FALSE, dir.result = NULL)

The input data frame is introduced in tree.tls and should contain information about the trees detected from TLS based data e.g., the output data frame of the functions tree.detection.single.scan or tree.detection.multi.scan. The path of the directory of the .txt files containing the reduced point cloud data generated by the function normalize can be specified in dir.data otherwise the current working directory will be assigned to this argument. If save.result is set to save.result = TRUE (default setting), the output files will be saved to the directory indicated in dir.result.

The scan approach, either TLS single-scan ("single") or TLS multi-scan and SLAM point clouds approaches ("multi") has to be specified in the argument scan.approach. By default, the argument is set to "multi".

If only a selection of metrics and variables should be calculated, the metrics and variables of interest can be specified as a vector in var.metr. If nothing is specified, the argument is set to NULL and all possible metrics and variables will be calculated.

Distance sampling (`distance.sampling` function)

The distance sampling method is used for the correction of occlusion effects. When the distance.sampling function was applied, the list with tree detection probabilities (i.e., the output file of the mentioned function) can be introduced in tree.ds. By default, this argument is set to NULL and metrics using distance sampling corrections will not be calculated. The distance.sampling is applied as follows:

tree.ds <- distance.sampling(tree.tls = tree.list,
                             id.plots = NULL,
                             strata.attributes = NULL)

The distance.sampling function computes the probability of detection of trees depending on their distance to the TLS device. Detection functions are fitted to the histogram representing the distribution of the trees relative to their horizontal distances. The computation of the detection functions is based on the data frame of the detected trees, i.e. the output file of the tree.detection.single.scan or tree.detection.multi.scan (here tree.list), which is introduced in the argument tree.tls. The plots to be analysed can be specified in id.plots by inserting a vector containing the plot identification numbers. If not specified, this argument is set to id.plots = NULL and all plots will be considered.

Two detection functions are fitted, that are the half normal and hazard rate functions, with and without \(dbh\) as covariate. These functions describe the decreasing detection probability with increasing distance. The probabilities are used for correcting estimation bias of the stand-level variables caused by the lack of detection of trees due to occlusion.

A list with three elements is generated by the distance.sampling function. The data frame tree represents the detection probabilities for each tree of all plots according to the four different detection functions. The columns P.hn and P.hn.cov show the detection probabilities calculated by the half normal function without and with \(dbh\) as covariate, while P.hr and P.hr.cov contain the probabilities according to the hazard rate function without and with covariate respectively.

head(tree.ds$tree)
#>   stratum id tree     P.hn  P.hn.cov      P.hr  P.hr.cov
#> 1       1  1    1 0.922808 0.9293580 0.9388107 0.9519734
#> 2       1  1    2 0.922808 0.8922843 0.9388107 0.9199997
#> 3       1  1    3 0.922808 0.9146826 0.9388107 0.9389643
#> 4       1  1    4 0.922808 0.9017652 0.9388107 0.9278849
#> 5       1  1    5 0.922808 0.9277925 0.9388107 0.9505678
#> 6       1  1    6 0.922808 0.9424095 0.9388107 0.9637861

The data frame par shows the parameters of the detection functions and AIC the Akaike information criterion (AIC) for every detection function fit.

head(tree.ds$par)
#>              P.hn.scale P.hn.cov.scale.intercept P.hn.cov.dbh P.hr.scale
#> X.Intercept.   35.84341                 64.17593    -2.231185   21.85271
#>              P.hr.shape P.hr.cov.scale.intercept P.hr.cov.dbh P.hr.cov.shape
#> X.Intercept.   3.544516                 26.38362   -0.7110327       3.832857

head(tree.ds$AIC)
#>       P.hn P.hn.cov     P.hr P.hr.cov
#> 1 3375.162 3376.521 3374.114 3375.123

Additional information about trees through field data

If supplementary field data is available for the sample plots, a data frame containing this information can be included in tree.field. Each row of the data frame must represent a tree and the data frame must contain at least the following columns:

id: plot identification number (character string or numeric), which must coincide with those in the id column of the tree.tls argument i.e., the list of trees yielded by the tree detection functions
tree: number of the tree
h.dist: horizontal distance (in m) of the tree’s center to the plot’s center, which must coincide with the centers of their corresponding TLS plots
dbh: tree diameter (in cm) at breast height (1.3 m)
h: total tree height (in m)
dead: integer value indicating whether the tree is dead (1) or not (NA)

Further optional columns are h.blc (height based live crown, in m), h.bdc (height based dead crown, in m), v.user (tree volume, in m\(^3\)) and w.user (tree biomass, in Mg).

Selecting trees to be included in the calculations

The arguments dbh.min, h.min and max.dist are used to determine the trees that are included in the calculations. The minimum diameter at breast height (\(dbh\)) and the minimum tree height can be specified in dbh.min (in cm) and h.min (in m) and are set to 4 cm and 1.3 m respectively by default. In max.dist, the maximal horizontal distance (in m) of a tree from the plot’s center to be included in the calculations can be defined. If not specified, no trees are discarded because of their distance.

Plot design and parameters

The metrics and variables can be computed for different plot designs which are specified by plot.design and plot.parameters. There are three different plot designs, which are similar to the procedure used in conventional forest inventories. The plot design, which is to be used can be specified in plot.design. By default, all plot designs will be considered.

As the name implies, circular fixed area plots ("fixed.area") are plots with a circular area defined by the plot radius (in m). The size of k-tree plots ("k.tree") is determined by the number of trees (k) that enter the plot. The basal area factor (BAF in m\(^2\)/ha) defines the size of angle-count plots ("angle.count"). The parameters radius, k and BAF have to be specified as data frame in plot.parameters. If one of these parameters is not specified, the corresponding plot design will not be considered in the calculations. To calculate the dominant height and diameter, the number of dominant trees per ha (trees/ha) can be indicated by the argument num.tree. By default, the number of dominant trees is set to 100 trees/ha.

Output files

The function metrics.variables generates a list in which each element represents one of the considered plot designs (fixed area, k-tree and angle-count plots). These elements are data frames containing the estimated metrics and variables at stand-level as columns (described below). Further columns include information about the plot, such as the identification number (id) and the stratum identification (stratum) both coinciding with the respective columns in the output file of the tree.detection functions. Each row represents a simulated plot i.e., a plot with a certain size (defined by the values for radius, k and BAF shown in the respective columns).

If save.result = TRUE, the data frames will be saved as seperate .csv files (one for each plot design) to the directory indicated in dir.result (or if not specified to the working directory). The .csv files (without row names) will be created using the write.csv function from the utils package.

Stand-level metrics

metrics[1:6, -c(3:36)]

id	radius	n.pts	n.pts.est	n.pts.red	n.pts.red.est	P01	P05	P10	P20	P25	P30	P40	P50	P60	P70	P75	P80	P90	P95	P99	mean.z	mean.q.z	mean.g.z	mean.h.z	median.z	mode.z	max.z	min.z	var.z	sd.z	CV.z	D.z	ID.z	kurtosis.z	skewness.z	p.a.mean.z	p.a.mode.z	p.a.2m.z	p.b.mean.z	p.b.mode.z	p.b.2m.z	CRR.z	L2.z	L3.z	L4.z	L3.mu.z	L4.mu.z	L.CV.z	median.a.d.z	mode.a.d.z	weibull_c.z	weibull_b.z	mean.rho	mean.q.rho	mean.g.rho	mean.h.rho	median.rho	mode.rho	max.rho	min.rho	var.rho	sd.rho	CV.rho	D.rho	ID.rho	kurtosis.rho	skewness.rho	p.a.mean.rho	p.a.mode.rho	p.b.mean.rho	CRR.rho	L2.rho	L3.rho	L4.rho	L3.mu.rho	L4.mu.rho	L.CV.rho	median.a.d.rho	mode.a.d.rho	weibull_c.rho	weibull_b.rho	mean.r	mean.q.r	mean.g.r	mean.h.r	median.r	mode.r	max.r	min.r	var.r	sd.r	CV.r	D.r	ID.r	kurtosis.r	skewness.r	p.a.mean.r	p.a.mode.r	p.b.mean.r	p.b.mode.r	CRR.r	L2.r	L3.r	L4.r	L3.mu.r	L4.mu.r	L.CV.r	median.a.d.r	mode.a.d.r	weibull_c.r	weibull_b.r
1	10	9788.667	1796.620	444.6667	322.3520	1.1763271	4.149327	5.984327	7.555327	7.824327	7.932327	8.176327	8.646327	9.357327	10.00233	10.32033	10.68533	11.39733	12.03533	13.43333	8.686622	8.991724	8.185912	6.949452	8.601327	7.935327	15.11633	0.2503271	5.393706	2.322435	0.2673577	14.866	2.423	4.535413	-0.8176501	48.55133	69.29800	98.07203	51.44867	30.64412	1.927974	0.5746516	112023087	1088745309	10962245432	-1830560027	23849979309	1e-07	1.223295	0.7512949	4.218465	9.554482	4.455202	5.325242	3.203021	1.745464	3.977145	0.1000033	9.999991	0.1000033	8.509383	2.917085	0.6547593	9.899988	5.068693	1.782223	0.2812223	46.60337	99.99993	53.39663	0.4455206	39291647	289779246	2301164191	-235377229	1816420654	1e-07	2.562719	4.355199	1.560419	4.957027	10.17625	10.45033	9.878583	9.541126	10.03613	7.939957	18.04629	1.9854031	5.653233	2.377653	0.2336472	16.06089	3.486677	2.864220	0.0953509	48.15005	85.54384	51.84995	14.45609	0.5638970	151314734	1701009907	19924353576	-2918437931	44702069599	1e-07	1.765318	2.2362936	4.892407	11.09717
2	10	11222.000	2815.061	611.1667	506.5021	1.0425898	4.121590	5.898590	7.335590	7.912590	8.448590	9.110590	9.663590	10.223590	10.64959	10.79059	10.87959	11.37959	11.90259	13.43459	9.052322	9.383953	8.475137	7.020125	9.605590	10.788590	16.82859	0.2505898	6.114052	2.472661	0.2731521	16.578	2.933	4.501117	-1.0871433	60.10169	23.93897	97.82422	39.89831	75.97166	2.175783	0.5379133	101884570	1031348422	10753389699	-1735525894	23502278857	1e-07	1.586268	1.7362678	4.119804	9.970272	5.443356	6.210808	4.027388	1.859293	5.913727	0.1000035	9.999995	0.1000035	8.944021	2.990656	0.5494140	9.899991	5.164815	1.754274	-0.2467470	52.36865	99.99991	47.63135	0.5443358	44630617	347962930	2851615225	-380857693	3209731874	1e-07	2.607957	5.343352	1.892479	6.133511	11.06990	11.25312	10.857815	10.592588	10.95586	10.778054	18.13256	1.1552180	4.090119	2.022404	0.1826941	16.97734	2.092208	4.720474	-0.3191920	47.73584	57.02047	52.26416	42.97944	0.6104983	146515187	1723625155	20809992902	-3142095776	52214652344	1e-07	1.040121	0.2918422	6.395220	11.89079
3	10	7931.000	3522.606	644.6667	676.3987	0.7535283	3.119528	5.446528	7.362528	7.852528	8.331528	8.914528	9.612528	10.219528	10.81653	11.00853	11.29753	12.37553	13.04753	14.07753	9.177116	9.598251	8.419140	6.533724	9.612528	10.845528	15.92853	0.2505283	7.906972	2.811934	0.3064071	15.678	3.156	3.930470	-0.9284260	56.40392	29.20901	96.89650	43.59608	70.75913	3.103504	0.5761434	92236146	971093853	10589014798	-1568290062	21550099741	1e-07	1.685412	1.6684122	3.627730	10.180048	6.672340	6.885693	6.452606	6.234672	6.568161	1.0608273	9.999985	1.0608273	2.892645	1.700778	0.2548997	8.939158	3.089093	1.845899	0.1775212	48.04518	99.99990	51.95482	0.6672350	47469238	356252676	2796808210	-593939497	5968664998	1e-07	1.542566	5.611513	4.446252	7.316667	11.64407	11.81267	11.457447	11.243853	11.75383	1.180774	18.26309	1.1807736	3.954716	1.988647	0.1707862	17.08232	2.547107	3.769785	-0.2945041	52.92946	99.99990	47.07054	0.00000	0.6375741	139705385	1716628700	21577086613	-3163588038	55274110885	1e-07	1.274854	10.4633013	6.878014	12.45916
4	10	14815.833	2391.316	253.5000	228.6277	0.8293213	3.240321	5.588321	7.137321	7.584321	7.896321	8.796321	9.439321	9.999321	10.67532	11.14432	11.66732	13.05332	13.78632	15.08332	9.208836	9.676083	8.445007	6.697945	9.439321	9.490321	35.28932	0.2503213	8.823948	2.970513	0.3225720	35.039	3.560	3.513803	-0.5324590	54.14860	48.89439	97.14021	45.85140	51.07578	2.859793	0.2609525	28567998	308407516	3490877952	-480824942	6666412747	3e-07	1.767485	0.2814852	3.426340	10.246363	4.801007	5.401068	4.067086	3.284440	4.668175	0.6118197	9.999958	0.6118197	6.121887	2.474245	0.5153596	9.388139	3.940113	2.071634	0.2721649	47.95151	99.99967	52.04849	0.4801027	8901023	61927806	468289564	-66273596	510018428	5e-07	2.021859	4.189187	2.031767	5.418747	10.78393	11.08143	10.423270	9.950309	10.50525	9.212659	35.48690	2.2008590	6.504908	2.550472	0.2365066	33.28604	3.332113	3.510630	-0.3286589	44.53457	77.13968	55.46543	22.85999	0.3038850	37469021	445207961	5485056120	-766979859	12425003393	3e-07	1.618794	1.5712744	4.827566	11.76894
5	10	13582.333	4682.324	574.6667	445.8058	0.8972930	4.469293	7.796293	8.695293	9.044293	9.561293	10.514293	10.960293	11.478293	12.07729	12.46029	12.85829	13.79829	14.36229	15.39429	10.584187	10.963716	9.863618	7.785157	10.964293	10.945293	16.88629	0.2502930	8.178051	2.859729	0.2701888	16.636	3.426	5.038409	-1.1877711	58.91270	50.64919	97.66575	41.08730	49.31287	2.334252	0.6267916	151746390	1789588757	21722917667	-3028745442	47953862766	1e-07	1.718894	0.3611058	4.169715	11.649419	5.359885	6.080607	4.037565	2.053025	5.693991	0.1000073	9.999996	0.1000073	8.245425	2.871485	0.5357363	9.899989	4.844945	1.909141	-0.2794109	54.17449	99.99992	45.82551	0.5359887	46676336	353412044	2820930172	-397127026	3289545553	1e-07	2.451160	5.259878	1.946119	6.044389	12.22845	12.53702	11.850902	11.333547	12.47152	11.346734	18.43135	0.8785378	7.641773	2.764376	0.2260609	17.55282	4.173565	2.992009	-0.5124616	53.34442	63.06284	46.65558	36.93708	0.6634594	198422726	2648674843	36436151565	-4630530899	84906244333	1e-07	2.160321	0.8817201	5.072474	13.30724
6	10	6254.500	1674.809	448.0000	364.1714	0.6060312	3.035031	6.009031	8.205031	8.697031	9.233031	10.052031	10.662031	11.199031	11.60703	11.80803	12.04303	12.86603	13.40603	14.68603	9.948021	10.370678	9.078045	6.626844	10.662031	11.459031	16.45303	0.2500312	8.587836	2.930501	0.2945813	16.203	3.111	4.773276	-1.3195711	61.54501	33.64629	96.60452	38.45499	66.31770	3.395478	0.6046315	85730909	962580012	11098719111	-1595976775	23700818001	1e-07	1.688990	1.5110099	3.789572	11.008726	6.594068	6.949814	6.180656	5.719248	6.507049	0.9677901	9.999993	0.9677901	4.818198	2.195039	0.3328809	9.032203	3.993594	1.867432	-0.0993663	48.84616	99.99987	51.15384	0.6594072	38500784	303690374	2521537499	-457939362	4555795906	2e-07	1.978972	5.626277	3.308526	7.350166	12.25927	12.48402	11.988194	11.639040	12.45260	1.071134	18.74465	1.0711337	5.561109	2.358200	0.1923605	17.67352	2.645716	4.167097	-0.6340967	54.22377	99.99987	45.77623	0.00000	0.6540144	124231693	1625048934	21779500092	-2943918051	54116275529	1e-07	1.326611	11.1881392	6.047834	13.20862

The stand-level metrics are statistical descriptive values, such as percentiles, standard deviation or means, as well as the number of points belonging to the normal section of the point cloud.

The values n.pts, n.pts.est, n.pts.red and n.pts.red.est indicate the number of points and the estimated number of points respectively that belong to the tree’s normal section (1.3 m +/- 0.05 m). This is calculated for the original point cloud (n.pts, n.pts.est) and the reduced point cloud (n.pts.red, n.pts.red.est).

Furthermore, the height percentiles (P01, P05, P10, P20, P25, P30, P40, P50, P60, P70, P75, P80, P90, P95, P99, numbers indicating the k-th percentile) are calculated for the \(z\) coordinate of the TLS point cloud. Therefore they denominate the height (in m) above ground level.

Statistics of the z, rho and r

To describe the tendencies and distribution of the spherical coordinates z, \(\rho\) (horizontal distance, rho) and r (euclidean distance), the following statistics are calculated:

arithmetic (mean.arit.z/rho/r), quadratic (mean.qua.z/rho/r), geometric (mean.geom.z/rho/r) and harmonic means (mean.harm.z/rho/r)
median (median.z/rho/r)
mode (mode.z/rho/r)
variance (var.z/rho/r)
standard deviation (sd.z/rho/r)
coefficient of variation (CV.z/rho/r)
range (D.z/rho/r)
interquartile range (ID.z/rho/r)
maximum (max.z/rho/r)
minimum (min.z/rho/r)
kurtosis (kurtosis.z/rho/r)
skewness (skewness.z/rho/r)
percentage of points above the arithmetic mean (p.a.mean.z/rho/r) and the mode (p.a.mode.z/rho/r)
percentage of points below the arithmetic mean (p.b.mean.z/rho/r) and the mode (p.b.mode.z/rho/r)
percentage of points above a height of 2 m (p.a.2m.z, only for the \(z\) coordinate)
percentage of points below a height of 2 m (p.b.2m.z, only for the \(z\) coordinate)
L-moments of order 2, 3 and 4 (L2.z/rho/r, L3.z/rho/r and L4.z/rho/r)
third and forth central L-moments (L3.mu.z/rho/r and L4.mu.z/rho/r)
ratio of L1 and L2 moments (L.CV.z/rho/r)
median of the absolute deviation from the overall median (median.a.d.z/rho/r)
mode of the absolute deviation from the overall mode (mode.a.d.z/rho/r)
Canopy relief ratio i.e., the ration of mean.z/rho/r to max.z/rho/r (CRR.z/rho/r)
scale and shape parameters of the Weibull distribution fitted for the spherical coordinates (weibull_c.z/rho/r, weibull_b.z/rho/r)

Stand-level variables

metrics[1:6, 1:36]

id	radius	N.tls	N.hn	N.hr	N.hn.cov	N.hr.cov	N.sh	G.tls	G.hn	G.hr	G.hn.cov	G.hr.cov	G.sh	V.tls	V.hn	V.hr	V.hn.cov	V.hr.cov	V.sh	d.tls	dg.tls	dgeom.tls	dharm.tls	h.tls	hg.tls	hgeom.tls	hharm.tls	d.0.tls	dg.0.tls	dgeom.0.tls	dharm.0.tls	h.0.tls	hg.0.tls	hgeom.0.tls	hharm.0.tls
1	10	222.8169	241.4554	237.3396	239.9341	234.2128	230.5601	12.83139	13.90472	13.66770	13.81712	13.48764	13.27729	72.26462	78.30949	76.97464	77.81611	75.96057	74.77589	26.63218	27.07807	26.17896	25.72557	11.98963	12.02086	11.95768	11.92508	31.50910	31.60757	31.40772	31.30362	12.77989	12.78591	12.77382	12.76769
2	10	350.1409	379.4298	372.9622	374.9814	366.2799	364.2843	18.91537	20.49762	20.14823	20.25731	19.78724	19.67943	101.80664	110.32268	108.44214	109.02925	106.49921	105.91896	25.75150	26.22655	25.29375	24.86175	11.59380	11.66199	11.51966	11.43902	32.68378	32.75790	32.60870	32.53280	12.41950	12.44332	12.39576	12.37212
3	10	381.9719	413.9235	406.8678	414.2445	403.9974	392.6248	23.55858	25.52924	25.09407	25.54904	24.91703	24.21562	115.70695	125.38573	123.24843	125.48298	122.37892	118.93393	27.86976	28.02296	27.71227	27.55093	11.38201	11.44246	11.32332	11.26633	31.17303	31.20949	31.13698	31.10141	11.78541	11.93916	11.62884	11.47255
4	10	254.6479	275.9490	271.2452	274.7699	268.1497	265.5833	22.15673	24.01012	23.60084	23.90752	23.33151	23.10820	124.40696	134.81348	132.51548	134.23744	131.00320	129.74938	32.71822	33.28417	32.14873	31.58609	12.69636	12.81602	12.56975	12.43597	38.69937	38.87412	38.53131	38.37101	12.55974	12.57650	12.54186	12.52257
5	10	318.3099	344.9362	339.0565	360.7488	349.0381	334.1288	21.34794	23.13368	22.73934	24.19417	23.40878	22.40886	117.11494	126.91149	124.74819	132.72937	128.42070	122.93514	28.64160	29.22187	27.98239	27.23715	12.77420	12.99329	12.47878	12.08340	34.98638	35.05872	34.91178	34.83518	13.39910	13.40467	13.39359	13.38812
6	10	254.6479	275.9490	271.2452	276.1346	269.3076	260.6298	15.96468	17.30011	17.00522	17.31175	16.88375	16.33971	89.59139	97.08563	95.43073	97.15093	94.74903	91.69596	28.06921	28.25304	27.88269	27.69453	12.82381	12.84689	12.80020	12.77611	31.41186	31.44841	31.37513	31.33830	12.79379	12.81666	12.77130	12.74923

The variables are estimated based on the tree attributes of the detected trees from the point cloud data (output of the functions tree.deteection.single.scan and tree.deteection.multi.scan) similar to the procedure of conventional forest inventories. The values are computed at stand-level and are therefore extended to an area of one ha.

Stand density (N), volume (V) and basal area (G)

The stand density (N.tls, trees/ha) is calculated by the following equations. For the circular fixed area and k-tree plots, N.tls is calculated by

\[ N.tls=\frac{10000}{\pi R^2}\cdot n \]

with \(R\) being the radius of the plot (in m) and \(n\) the number of detected trees. The density of angle-count plots is calculated by

\[ N.tls=\sum_{i=1}^{n} \frac{BAF}{g_i} \]

with \(BAF\) being the basal area factor (in m\(^2\)/ha) and \(g_i\) the basal area of the tree \(i\) (in m\(^2\)).

The basal area (G.tls, in m\(^2\)/ha) is estimated for circular fixed area and k-tree plots by the following equation:

\[ G.tls=\frac{10000}{\pi R^2}\sum_{i=1}^{n} g_i \]

and for angle-count plots, the following equation is applied:

\[ G.tls=BAF \cdot n \]

The stem volume (V.tls, in m\(^3\)/ha) is estimated by modelling the stem profile as a paraboloid. The volume is calculated as the volume of the revolution of the paraboloid function. The total heights of the detected trees are estimated as the 99th percentile of the points of the \(z\) coordinate delimited by Voronoi polygons (\(h_{P_{99}i}\), in m). The equation used for the calculation for circular fixed area and k-tree plots is

\[ V.tls=\frac{10000}{\pi R^2}\sum_{i=1}^{n} \pi \cdot \frac{h_{P_{99}i}^2}{2} \cdot \frac{(\frac{1}{2} \cdot dbh_i)^2}{(h_{P_{99}i} - 1.3)^2} \]

and for angle-count plots is

\[ V.tls=\sum_{i=1}^{n} \frac{BAF}{g_i} \cdot \pi \cdot \frac{h_{P_{99}i}^2}{2} \cdot \frac{(\frac{1}{2} \cdot dbh_i)^2}{(h_{P_{99}i} - 1.3)^2} \]

Occlusion correction

The above mentioned calculations of the stand-level variables \(N\), \(V\) and \(G\) do not consider possible occlusions of trees. Therefore, different occlusion correction approaches are included in the function.

For angle-count plots, the occlusion correction is based on the Poisson attenuation model. This approach calculates geometric gap probabilities which decreases with increasing distance from the TLS device and follow a Poisson distribution. The calculations of stand density, volume and basal area are corrected with a factor accounting for the gap probabilities and the corrected variables are called N.pam, V.pam and G.pam respectively. For further details see Strahler et al. (2008¹) and Lovell et al. (2011²).

For the other two plot designs (circular fixed area and k-tree plots) different occlusion correction approaches are applied. One approach is based on distance sampling data and can therefore only be used when the function distance.sampling was used (i.e., when the tree.ds argument is specified other than NULL). Functions based on point transect sampling that describe how the probability of tree detection decreases with increasing distance from the TLS device are used for the calculation. These functions are applied for the calculation of the variables N.hn/V.hn/G.hn and N.hr/V.hr/G.hr and are Half-Normal and Hazard-Rate respectively. Additionally, N.hn.cov/V.hn.cov/G.hn.cov and N.hr.cov/V.hr.cov/G.hr.cov are calculated with expanding the scale component of the function with \(dbh\) as covariate.

The other approach corrects shadowing effects. Tthis method calculates an expansion factor to correct the variables. The expansion factor is based on the percentage of the shaded area i.e., unsample area which is not seen from the TLS device due to masking by trees. The corrected calculated variables are called N.sh/V.sh/G.sh. For more details see Seidel and Ammer (2014³).

Mean and dominant heights (h) and diameters (d)

The mean heights (in m) and diameters (in cm) are calculated by the arithmetic (h.tls, d.tls), quadratic (h.g, d.g), geometric (h.geom, d.geom) and harmonic means (h.harm, d.harm). To calculate the dominant heights and diameters, only the \(n\) largest trees per hectar are considered. If not otherwise specified in the argument num.tree (see above), the number of dominant trees per hectare is set to 100 trees/ha. Dominant heights and diameters are also calculated as the arithmetic (h.0.tls, d.0.tls), quadratic (h.0.g, d.0.g), geometric (h.0.geom, d.0.geom) and harmonic means (h.0.harm, d.0.harm).

Strahler, A.H., Jupp, D.L.B., Woodcock, C.E., Schaaf, C.B., Yao, T., Zhao, F., Yang, X., Lovell, J., Culvenor, D., Newnham, G., Ni-Miester, W., Boykin-Morris, W., 2008. Retrieval of forest structural parameters using a ground-based lidar instrument (Echidna®). Can. J. Rem. Sens. 34 (Suppl. 2), S426–S440. https://doi.org/10.5589/m08-046.↩︎
Lovell, J.L., Jupp, D.L.B., Newnham, G.J., Culvenor, D.S., 2011. Measuring tree stem diameters using intensity profiles from ground-based scanning lidar from a fixed viewpoint. ISPRS J. Photogrammetry Remote Sens. 66 (1), 46–55. https://doi.org/10.1016/j.isprsjprs.2010.08.006.↩︎
Seidel, D., Ammer, C., 2014. Efficient measurements of basal area in short rotation forests based on terrestrial laser scanning under special consideration of shadowing. iFor. Biogeosci. For. 7 (4), 227–232. https://doi.org/10.3832/ifor1084-007.↩︎