Calculate signal attenuation through cables, fiber, or free space. Find total loss in dB, output power, and half-power distance with connector and splice losses.
The **Attenuation Calculator** determines how much signal power is lost as it travels through a transmission medium — cables, optical fiber, free space, or even walls and water. Attenuation is measured in decibels (dB) and is critical for designing reliable communication links.
Every component in a signal path introduces loss: the cable itself, each connector, and every splice. This calculator sums all contributions to give you the total link loss in dB and the resulting output power in milliwatts and dBm. It also computes the half-power distance — the point where signal power drops by 3 dB (50%).
Use the built-in presets for common media types or enter custom attenuation coefficients. Whether you are planning an Ethernet run, a fiber-optic backbone, an RF antenna feed line, or a wireless link, this calculator gives you a first-pass loss estimate before you commit to hardware or distance. It keeps the medium loss and the accessory losses together so the signal budget can be reviewed as a single path instead of several disconnected parts.
Use this calculator to add medium loss, connector loss, and splice loss into one total so you can judge whether the remaining signal is likely to be usable. It is a quick way to screen cable runs and link budgets before you move to a more detailed design check, especially when you need a fast answer before moving on to a more detailed design workup. That makes it easier to compare one route against another before you commit to hardware.
Total Loss = (α × d / 100) + N_conn × L_conn + N_splice × L_splice [dB] Output Power: P_out = P_in × 10^(−Loss / 10) [mW] dBm: P(dBm) = 10 log₁₀(P_mW) Half-Power Distance: d₃dB = 300 / α [m] (for α in dB/100 m)
Result: 7.0 dB total loss, 19.95 mW output, 19.95% retained
A 100 mW signal over 100 m of RG-6 coax with 2 connectors loses 6 dB from cable and 1 dB from connectors, totalling 7 dB. Output power is about 20 mW (20% retained).
Losses that look small on paper become significant once you stack cable distance, connectors, splitters, and splices in the same path. That is why link-budget work is often just as much about managing many small losses as it is about the main transmission medium.
Attenuation is easiest to manage in dB because gains and losses add directly. Once the total is known, you can translate back into linear power to see how much signal remains in a more intuitive percentage form.
This kind of calculator is ideal for first-pass distance and hardware checks. Final design still needs receiver sensitivity, noise margin, operating frequency, and real installation conditions before you can treat the result as deployment-ready.
Attenuation is the reduction of signal strength as it travels through a medium, and it is usually tracked in decibels. The larger the value, the more signal has been lost along the path.
Conductor resistance, dielectric loss, imperfect shielding, and frequency-dependent effects all contribute to attenuation in real cables. Longer runs and poorer cable construction generally increase the loss.
Each connector introduces a small loss (typically 0.2–1 dB) from impedance mismatch and contact resistance. Multiple connectors can add up quickly on long runs.
dBm is a logarithmic power unit referenced to 1 milliwatt, which makes it convenient for adding gains and losses directly in link-budget work. It lets you compare signal levels on the same scale instead of switching between linear and logarithmic units.
It depends on receiver sensitivity. Wi-Fi links typically tolerate 60–80 dB; fiber links may tolerate over 30 dB. The acceptable amount is always tied to the receiver and the required margin.
Yes. Higher frequencies experience more attenuation in most media, which is why attenuation specs are stated at a specific frequency. That is why a cable rated at one frequency may not perform the same way at a higher one.