Calculate J-pole antenna dimensions for any frequency. Get radiator length, stub length, gap, and feed point for VHF/UHF bands.
The J-pole antenna is one of the most popular and versatile antenna designs for amateur radio operators, first-responder communications, and hobbyist radio enthusiasts. Named for its J-shaped profile, this end-fed half-wave antenna combines a three-quarter wavelength radiating element with a quarter-wavelength matching stub, producing an omnidirectional radiation pattern with approximately 3 dBi gain when properly constructed.
What makes the J-pole particularly attractive is its simplicity and excellent performance. Unlike ground-plane antennas, the J-pole does not require radials or a ground plane, making it ideal for portable operations, apartment installations, and field deployments. It can be built from inexpensive materials like copper pipe, aluminum tubing, or even 300-ohm twin-lead cable.
This calculator provides precise dimensions for building a J-pole antenna at any design frequency. Simply enter your target frequency, and the calculator determines the radiator length, stub length, gap, and optimal feed point location. Whether you are building for the 2-meter band, 70-centimeter band, or MURS frequencies, getting these measurements accurate is critical for achieving low SWR and maximum efficiency.
Building an antenna requires precise measurements to achieve proper resonance and low SWR. Even small errors — a quarter inch at VHF frequencies — can shift the resonant frequency by several megahertz and raise your SWR above acceptable levels.
This calculator eliminates the guesswork from J-pole antenna construction. It accounts for velocity factor differences between materials, provides dimensions in your preferred units, and includes a reference table of standard amateur radio bands so you can quickly compare designs.
J-Pole Antenna Dimensions: • Wavelength: λ = (c × VF) / f • Radiator (long element): L = 0.75 × λ • Matching stub (short element): S = 0.25 × λ • Gap at bottom: G ≈ 0.01 × λ • Feed point height: F ≈ 0.045 × λ above stub base Where c = speed of light (299,792,458 m/s), VF = velocity factor, f = frequency (Hz)
Result: Radiator = 58.43 in, Stub = 19.48 in, Gap = 0.78 in, Feed = 3.51 in
For 146 MHz with VF of 0.95: wavelength is 1.953 m. The ¾λ radiator is 58.43 inches, the ¼λ stub is 19.48 inches, the bottom gap is about 0.78 inches, and the feed point is 3.51 inches above the base.
The J-pole is fundamentally an end-fed half-wave dipole with an integrated quarter-wave matching section. The three-quarter wavelength radiator element creates the main radiation, while the shorter quarter-wavelength stub acts as an impedance transformer, matching the high impedance at the end of the half-wave element down to approximately 50 ohms suitable for coaxial feed.
The beauty of this design is that the matching section is physically part of the antenna structure, eliminating the need for external baluns or matching networks. The feed point position along the stub controls the impedance — moving higher increases impedance, moving lower decreases it. This adjustability makes the J-pole forgiving to build and easy to tune.
The most common construction uses ½-inch or ¾-inch copper pipe with soldered joints. Start by cutting the radiator and stub to calculated lengths, then connect them at the bottom with a horizontal section (maintaining the specified gap between them). A copper tee fitting at the bottom makes an excellent connection point.
For portable or emergency use, the Slim Jim variant uses 300Ω twin-lead cable. Simply cut the cable to the total length (¾λ + ¼λ), split the conductors for the radiator section, and leave them connected at the top of the stub. The Slim Jim rolls up compactly and weighs almost nothing.
After construction, use an SWR meter or antenna analyzer to verify performance. First, check resonant frequency — if it is too low, shorten the radiator slightly. If SWR is high at resonance, adjust the feed point position. Moving the feed point up increases impedance; moving it down decreases it. The goal is SWR below 1.5:1 across your target frequency range, with a minimum at your most-used frequency.
Copper pipe (½" or ¾") is the most popular choice for permanent installations due to its durability, easy soldering, and good conductivity. Aluminum tubing works well for lightweight builds. For portable use, 300Ω twin-lead (Slim Jim variant) is extremely portable and lightweight.
Use 0.95 for copper pipe, 0.95-0.96 for aluminum tubing, 0.80-0.82 for 300Ω twin-lead (Slim Jim design), and 0.96-0.98 for open wire with air dielectric.
A properly built J-pole should achieve an SWR of 1.5:1 or better across most of the target band. Many builders achieve SWR below 1.2:1 at the design frequency by carefully adjusting the feed point position.
A Slim Jim is a J-pole variant where the radiator element is folded back, creating a folded half-wave dipole on top of the matching stub. The Slim Jim offers slightly higher gain (~4-5 dBi vs ~3 dBi) but has a wider profile.
For copper pipe construction, a spacing of ½ inch to 1 inch between the radiator and stub works well. The exact spacing affects impedance matching — closer spacing gives lower feed impedance.
While a J-pole is resonant on its design frequency, it also works on odd harmonics of the fundamental. A 2m J-pole may also work on 70cm, although the radiation pattern changes on harmonics.