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Gloucester County Amateur Radio Club

Skunkworks Advanced Project Team  ·  WB2MNF / W2MMD
Station Being Monitored
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📻 WSPR Propagation Analysis

Distinct Stations (7d)
Max Distance
Best SNR
Total Spots
Avg mi/W
SpotQ
mi/W adjusted for SNR — higher means better DX per watt (wspr.rocks)
📊 Band Conditions Right Now — Maximum Usable Frequency & Space Weather
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🌍 Globe View — Signal Paths & SNR 30m drag to rotate · scroll to zoom
🕐 Time Filter Loading…
🕑 Most Recent Spots (Last 10)
Time (ET) Receiver Distance (mi) SNR (dB)
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Top DX Receivers
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Activity by Local Hour
🗓️ When Does This Band Open? — Hour × Day Heatmap
Spot density by station-local hour (columns) and day-of-week (rows). Darker = more spots. Look for vertical streaks (reliable time-of-day openings) and diagonal stripes (propagation tied to sun angle).
🌐 DX Windows — When Each Continent Opens
For each continent where your signal has been heard, shading shows the hours (station local) when spots arrive. Darker = more spots during that hour. Use this to plan when to call CQ for a specific part of the world — the bright band in each row is that continent’s opening window on this band.
⏱️ Opening Outlook by Hour
For each hour of your station's local day: how reliably does the band open at that hour (% of recent days it had activity), and if it’s open, how many more hours of activity can you expect? Use this to decide when to sit down and call CQ.
📊 Propagation Analysis

Analysing propagation data…

Receivers by Distance
SNR Distribution
Signal Compass — Receiver Directions
Frequency Drift Distribution
Drift is how much the transmit frequency shifts during a 2-minute WSPR cycle (Hz/s). Zero drift means a stable oscillator; high drift causes decoding failures and poor SpotQ.
🎯 Propagation Mode Mix
Every spot is classified by the most likely propagation mode based on distance, band, and hour. Percentages tell you how your signal is actually getting out — mostly ground wave, mostly single-hop F-layer, or mostly DX multi-hop. Gray-line hits (spots taken within ±1.5h of your local sunrise or sunset) are called out separately, since they can land in several modes.
📐 Empirical Antenna Pattern — dB Offset by Bearing
For each receiver that copied you, we compute their mean distance-corrected SNR (snr + 20·log₁₀(d/d_med)), then bin receivers by bearing — each receiver contributes one vote per bin, regardless of how many spots they sent you. The number shown is the bin's deviation in dB from your all-bearing mean. Positive lobes = stronger than average; negative dips suggest an antenna null or propagation asymmetry. Not a pure antenna pattern — receiver site quality, day/night and magnetic-field effects still bleed in, but most stations' antenna patterns dominate.
🌍 7-Day Spot Trend by Continent
Each bar = one day. Taller bar = more spots decoded to that region that day.
📡 Skip Zone — Why Can't I Hear My Neighbour?
How Radio Waves Travel
On 30m, signals travel up to the F₂ layer (~185 mi up), bounce back down, and skip over a dead zone near the transmitter. Stations inside the skip zone can't hear the signal even though it passed right over them.
📡 Spot Distance vs. Local Hour — Gray-Line Analysis
Median spot distance by local hour. Gold bands show computed sunrise/sunset windows.
What is the gray line? (click to expand)

The gray line (also called the terminator) is the boundary between the sunlit and dark sides of Earth, sweeping around the globe as it rotates. At any point on the gray line it is simultaneously sunrise on one edge and sunset on the other.

During daylight, the D-layer of the ionosphere absorbs HF radio signals — this is why long-distance propagation on 30m and 40m is limited during the day. At sunrise, the D-layer evaporates rapidly within minutes. At sunset, it disappears as the sun sets. During these brief windows the absorption vanishes while the F-layer (which reflects signals to distant stations) is still present and dense.

The result: a 30–60 minute window of dramatically enhanced long-distance propagation at dawn and again at dusk. Signals that are normally absorbed can suddenly travel thousands of kilometers farther.

On this chart: the blue line shows median spot distance for each half-hour of the day averaged over the past 7 days. The dashed line is the baseline average (excluding gray-line hours). The gold shaded bands show the ±1.5 hour windows around computed sunrise and sunset. A peak in the blue line that rises above the baseline inside a gold band is a gray-line enhancement event.