radio plot cleanup

aerpaw/results/plotRadioLogs.m

@@ -43,12 +43,44 @@ function [f, fDist, R] = plotRadioLogs(resultsPath, G, tLim)
 
     metricNames = ["SNR", "Power", "Quality", "PathLoss", "NoiseFloor", "FreqOffset"];
     yLabels     = ["SNR (dB)", "Power (dB)", "Quality", "Path Loss (dB)", "Noise Floor (dB)", "Freq Offset (MHz)"];
+    nMetrics    = numel(metricNames);
 
     % --- Time-based figure ---
     f = figure;
-    tl = tiledlayout(numel(metricNames), 1, 'TileSpacing', 'compact', 'Padding', 'compact');
+    tl = tiledlayout(nMetrics + 1, 1, 'TileSpacing', 'compact', 'Padding', 'compact');
 
-    for mi = 1:numel(metricNames)
+    % Distance vs time tile (first)
+    ax = nexttile(tl);
+    hold(ax, 'on'); grid(ax, 'on');
+    legendEntries = string.empty;
+    ci = 1;
+    if ~isempty(G)
+        for rxIdx = 1:nUAV
+            tbl = R{rxIdx};
+            txIDs = unique(tbl.TxUAVID);
+            for ti = 1:numel(txIDs)
+                txID = txIDs(ti);
+                rows = tbl(tbl.TxUAVID == txID, :);
+                rows = rows(rows.Timestamp >= tLim(1) & rows.Timestamp <= tLim(2), :);
+                if isempty(rows), continue; end
+                [~, ia] = unique(rows.Timestamp);
+                [radioPt, dist] = pairDist(rows(ia, :), G);
+                if isempty(dist) || all(isnan(dist)), continue; end
+                valid = ~isnan(dist);
+                si = mod(ci - 1, numel(styles)) + 1;
+                plot(ax, datetime(radioPt(valid), 'ConvertFrom', 'posixtime'), dist(valid), ...
+                    styles(si), 'Color', colors(ci, :), 'MarkerSize', 3, 'LineWidth', 0.5);
+                legendEntries(end+1) = sprintf("TX %d → RX %d", txID, rows.RxUAVID(1)); %#ok<AGROW>
+                ci = ci + 1;
+            end
+        end
+    end
+    ylabel(ax, 'Distance (m)');
+    xlabel(ax, 'Time');
+    legend(ax, legendEntries, 'Location', 'best');
+    hold(ax, 'off');
+
+    for mi = 1:nMetrics
         ax = nexttile(tl);
         hold(ax, 'on');
         grid(ax, 'on');
@@ -63,21 +95,30 @@ function [f, fDist, R] = plotRadioLogs(resultsPath, G, tLim)
                 rows = tbl(tbl.TxUAVID == txID, :);
                 rows = rows(rows.Timestamp >= tLim(1) & rows.Timestamp <= tLim(2), :);
                 vals = rows.(metricNames(mi));
+                valid = ~isnan(vals);
+                rows = rows(valid, :);
+                vals = vals(valid);
 
-                if isempty(rows) || all(isnan(vals))
+                if isempty(rows)
                     continue;
                 end
 
                 si = mod(ci - 1, numel(styles)) + 1;
                 plot(ax, rows.Timestamp, vals, styles(si), ...
-                    'Color', colors(ci, :), 'MarkerSize', 3, 'LineWidth', 1);
+                    'Color', colors(ci, :), 'MarkerSize', 3, 'LineWidth', 0.5);
                 legendEntries(end+1) = sprintf("TX %d → RX %d", txID, tbl.RxUAVID(1)); %#ok<AGROW>
+
+                % Median per 1/3-second time bin
+                [t_med, v_med] = timeBinMedian(posixtime(rows.Timestamp), vals, 1/3);
+                plot(ax, datetime(t_med, 'ConvertFrom', 'posixtime'), v_med, '-', ...
+                    'Color', 'r', 'LineWidth', 2);
+                legendEntries(end+1) = sprintf("TX %d → RX %d (median)", txID, tbl.RxUAVID(1)); %#ok<AGROW>
                 ci = ci + 1;
             end
         end
 
         ylabel(ax, yLabels(mi));
-        if mi == numel(metricNames)
+        if mi == nMetrics
             xlabel(ax, 'Time');
         end
         legend(ax, legendEntries, 'Location', 'best');
@@ -93,9 +134,38 @@ function [f, fDist, R] = plotRadioLogs(resultsPath, G, tLim)
         return;
     end
 
-    tl2 = tiledlayout(numel(metricNames), 1, 'TileSpacing', 'compact', 'Padding', 'compact');
+    tl2 = tiledlayout(nMetrics + 1, 1, 'TileSpacing', 'compact', 'Padding', 'compact');
 
-    for mi = 1:numel(metricNames)
+    % Distance vs time tile (first)
+    ax = nexttile(tl2);
+    hold(ax, 'on'); grid(ax, 'on');
+    legendEntries = string.empty;
+    ci = 1;
+    for rxIdx = 1:nUAV
+        tbl = R{rxIdx};
+        txIDs = unique(tbl.TxUAVID);
+        for ti = 1:numel(txIDs)
+            txID = txIDs(ti);
+            rows = tbl(tbl.TxUAVID == txID, :);
+            rows = rows(rows.Timestamp >= tLim(1) & rows.Timestamp <= tLim(2), :);
+            if isempty(rows), continue; end
+            [~, ia] = unique(rows.Timestamp);
+            [radioPt, dist] = pairDist(rows(ia, :), G);
+            if isempty(dist) || all(isnan(dist)), continue; end
+            valid = ~isnan(dist);
+            si = mod(ci - 1, numel(styles)) + 1;
+            plot(ax, datetime(radioPt(valid), 'ConvertFrom', 'posixtime'), dist(valid), ...
+                styles(si), 'Color', colors(ci, :), 'MarkerSize', 3, 'LineWidth', 0.5);
+            legendEntries(end+1) = sprintf("TX %d → RX %d", txID, rows.RxUAVID(1)); %#ok<AGROW>
+            ci = ci + 1;
+        end
+    end
+    ylabel(ax, 'Distance (m)');
+    xlabel(ax, 'Time');
+    legend(ax, legendEntries, 'Location', 'best');
+    hold(ax, 'off');
+
+    for mi = 1:nMetrics
         ax = nexttile(tl2);
         hold(ax, 'on');
         grid(ax, 'on');
@@ -119,61 +189,39 @@ function [f, fDist, R] = plotRadioLogs(resultsPath, G, tLim)
                 end
 
                 vals = rows.(metricNames(mi));
-                if all(isnan(vals))
+                valid = ~isnan(vals);
+                rows = rows(valid, :);
+                vals = vals(valid);
+
+                if isempty(rows)
                     continue;
                 end
 
-                % Map 0-based UAV IDs to 1-based GPS cell indices
-                txGpsIdx = double(txID) + 1;
-                rxGpsIdx = double(rows.RxUAVID(1)) + 1;
+                [radioPt, dist] = pairDist(rows, G);
+                if isempty(dist) || all(isnan(dist)), continue; end
 
-                if txGpsIdx > numel(G) || rxGpsIdx > numel(G)
-                    continue;
-                end
-
-                Gtx = G{txGpsIdx};
-                Grx = G{rxGpsIdx};
-
-                if ~ismember('East', Gtx.Properties.VariableNames) || ...
-                   ~ismember('East', Grx.Properties.VariableNames)
-                    continue;
-                end
-
-                % Strip timezone before posixtime so radio and GPS timestamps
-                % are treated on the same scale (both are AERPAW wall-clock time)
-                txTs = Gtx.Timestamp; txTs.TimeZone = '';
-                rxTs = Grx.Timestamp; rxTs.TimeZone = '';
-                txPt = posixtime(txTs);
-                rxPt = posixtime(rxTs);
-                radioPt = posixtime(rows.Timestamp);
-
-                % Interpolate GPS positions at radio measurement times.
-                % Exclude NaN ENU entries (outside algorithm flight range).
-                validTx = ~isnan(Gtx.East);
-                validRx = ~isnan(Grx.East);
-
-                txE = interp1(txPt(validTx), Gtx.East(validTx),  radioPt, 'linear', NaN);
-                txN = interp1(txPt(validTx), Gtx.North(validTx), radioPt, 'linear', NaN);
-                txU = interp1(txPt(validTx), Gtx.Up(validTx),    radioPt, 'linear', NaN);
-                rxE = interp1(rxPt(validRx), Grx.East(validRx),  radioPt, 'linear', NaN);
-                rxN = interp1(rxPt(validRx), Grx.North(validRx), radioPt, 'linear', NaN);
-                rxU = interp1(rxPt(validRx), Grx.Up(validRx),    radioPt, 'linear', NaN);
-
-                dist = vecnorm([txE - rxE, txN - rxN, txU - rxU], 2, 2);
-
-                if all(isnan(dist))
-                    continue;
-                end
+                % Drop points where GPS interpolation returned NaN
+                validDist = ~isnan(dist);
+                rowTs = radioPt(validDist);
+                dist  = dist(validDist);
+                vals  = vals(validDist);
 
                 si = mod(ci - 1, numel(styles)) + 1;
                 scatter(ax, dist, vals, 9, colors(ci, :), strrep(styles(si), "-", ""), 'filled');
                 legendEntries(end+1) = sprintf("TX %d → RX %d", txID, rows.RxUAVID(1)); %#ok<AGROW>
+
+                % Median per 1/3-second time bin, plotted against median distance
+                [~, dv_med] = timeBinMedian(rowTs, [dist, vals], 1/3);
+                [d_med, si_sort] = sort(dv_med(:, 1));
+                v_med = dv_med(si_sort, 2);
+                plot(ax, d_med, v_med, '-', 'Color', 'r', 'LineWidth', 2);
+                legendEntries(end+1) = sprintf("TX %d → RX %d (median)", txID, rows.RxUAVID(1)); %#ok<AGROW>
                 ci = ci + 1;
             end
         end
 
         ylabel(ax, yLabels(mi));
-        if mi == numel(metricNames)
+        if mi == nMetrics
             xlabel(ax, 'Distance (m)');
         end
         legend(ax, legendEntries, 'Location', 'best');
@@ -182,3 +230,30 @@ function [f, fDist, R] = plotRadioLogs(resultsPath, G, tLim)
 
     title(tl2, 'Radio Channel Metrics vs Distance');
 end
+
+
+function [radioPt, dist] = pairDist(rows, G)
+    % Interpolate GPS-based inter-UAV distance at each row's timestamp.
+    radioPt = []; dist = [];
+    txGpsIdx = double(rows.TxUAVID(1)) + 1;
+    rxGpsIdx = double(rows.RxUAVID(1)) + 1;
+    if txGpsIdx > numel(G) || rxGpsIdx > numel(G), return; end
+    Gtx = G{txGpsIdx};
+    Grx = G{rxGpsIdx};
+    if ~ismember('East', Gtx.Properties.VariableNames) || ...
+       ~ismember('East', Grx.Properties.VariableNames), return; end
+    txTs = Gtx.Timestamp; txTs.TimeZone = '';
+    rxTs = Grx.Timestamp; rxTs.TimeZone = '';
+    txPt = posixtime(txTs);
+    rxPt = posixtime(rxTs);
+    radioPt = posixtime(rows.Timestamp);
+    validTx = ~isnan(Gtx.East);
+    validRx = ~isnan(Grx.East);
+    txE = interp1(txPt(validTx), Gtx.East(validTx),  radioPt, 'linear', NaN);
+    txN = interp1(txPt(validTx), Gtx.North(validTx), radioPt, 'linear', NaN);
+    txU = interp1(txPt(validTx), Gtx.Up(validTx),    radioPt, 'linear', NaN);
+    rxE = interp1(rxPt(validRx), Grx.East(validRx),  radioPt, 'linear', NaN);
+    rxN = interp1(rxPt(validRx), Grx.North(validRx), radioPt, 'linear', NaN);
+    rxU = interp1(rxPt(validRx), Grx.Up(validRx),    radioPt, 'linear', NaN);
+    dist = vecnorm([txE - rxE, txN - rxN, txU - rxU], 2, 2);
+end

aerpaw/results/readRadioLogs.m

@@ -70,6 +70,40 @@ function R = readRadioLogs(logPath)
 
     R = sortrows(R, "Timestamp");
 
+    % Reconstruct per-measurement timestamps within GNURadio processing batches.
+    % The flowgraph accumulates one full PN sequence (4095 chips at samp_rate/sps)
+    % per measurement, but outputs the whole batch simultaneously with a single
+    % wall-clock timestamp. We reassign timestamps by counting backward from the
+    % batch processing time at the known PN period interval.
+    pn_period = 4095 / (2e6 / 16);  % 32.76 ms per PN correlation period
+
+    for txId = unique(R.TxUAVID)'
+        rows = find(R.TxUAVID == txId);
+        if numel(rows) < 2, continue; end
+
+        dt = seconds(diff(R.Timestamp(rows)));
+        break_pos = [1; find(dt > 0.5) + 1];
+        end_pos   = [break_pos(2:end) - 1; numel(rows)];
+
+        for b = 1:numel(break_pos)
+            idx      = rows(break_pos(b) : end_pos(b));
+            batch_ts = posixtime(R.Timestamp(idx));
+            t_ref    = max(batch_ts);
+
+            % Multiple metric files share the same processing timestamp for
+            % each PN period, so group by unique original timestamp rather
+            % than treating every row as a separate PN period.
+            [~, ~, group_id] = unique(batch_ts);
+            n_groups = max(group_id);
+            new_ts   = t_ref - (n_groups - 1 : -1 : 0)' * pn_period;
+
+            for g = 1:n_groups
+                R.Timestamp(idx(group_id == g)) = ...
+                    datetime(new_ts(g), 'ConvertFrom', 'posixtime');
+            end
+        end
+    end
+
     % Remove rows during defined guard period between TDM shifts
     R(R.TxUAVID == -1, :) = [];
 

aerpaw/results/timeBinMedian.m

@@ -0,0 +1,29 @@
+function [t_med, v_med] = timeBinMedian(t, v, binWidth)
+    % Compute median of each column of v within fixed-width time bins.
+    %
+    %   t        - (N,1) posixtime values
+    %   v        - (N,K) data matrix; one column per quantity
+    %   binWidth - scalar bin width in seconds
+    %
+    %   t_med    - (B,1) median time of each non-empty bin
+    %   v_med    - (B,K) median of each column per non-empty bin
+
+    edges = (floor(min(t) / binWidth) * binWidth) : binWidth : ...
+            (floor(max(t) / binWidth) * binWidth + binWidth);
+    bins  = discretize(t, edges);
+    nBins = numel(edges) - 1;
+    K     = size(v, 2);
+
+    t_all = NaN(nBins, 1);
+    v_all = NaN(nBins, K);
+    for bi = 1:nBins
+        mask = bins == bi;
+        if ~any(mask), continue; end
+        t_all(bi)   = median(t(mask));
+        v_all(bi,:) = median(v(mask,:), 1);
+    end
+
+    ok    = ~isnan(t_all);
+    t_med = t_all(ok);
+    v_med = v_all(ok, :);
+end

test/test_miSim.m

@@ -9,8 +9,8 @@ classdef test_miSim < matlab.unittest.TestCase
         plotCommsGeometry = false; % disable plotting communications geometries
 
         % Sim
-        maxIter = 50;
-        timestep = 0.05;
+        maxIter = 250;
+        timestep = 0.1;
 
         % Domain
         domain = rectangularPrism; % domain geometry
@@ -31,7 +31,7 @@ classdef test_miSim < matlab.unittest.TestCase
 
         % Agents
         initialStepSize = 0.2; % gradient ascent step size at the first iteration. Decreases linearly to 0 based on maxIter.
-        initialMaxAngleStepSize = 5; % angular step size (degrees) for tilt/azimuth gradient ascent per timestep.
+        initialMaxAngleStepSize = 0.1; % angular step size (degrees) for tilt/azimuth gradient ascent per timestep.
         minAgents = 3; % Minimum number of agents to be randomly generated
         maxAgents = 4; % Maximum number of agents to be randomly generated
         useDoubleIntegrator = false;