Building a 915 MHz Yagi Antenna

A yagi antenna provides significant directional gain for point-to-point links - ideal for connecting two backbone nodes across a valley, mountain, or city. Building your own 915 MHz yagi is a rewarding project that costs $10-20 in materials vs. $50-150 for a commercial equivalent.

Yagi Design Fundamentals

A yagi consists of three element types mounted on a boom:

Reflector - Behind the dipole; slightly longer than a half-wavelength; increases gain in forward direction
Driven element (dipole) - The active element connected to the feedline
Directors - In front of the dipole; slightly shorter than a half-wavelength; focus the beam forward

At 915 MHz, a half-wavelength in free space is approximately ~~163mm~~164 mm (6.4 inches). Note that a real resonant element is about 5% shorter than the free-space half-wave due to end effect, so a driven dipole element typically cuts to around 155 mm rather than the full 164 mm. Each element is cut to a specific length and spaced precisely on the ~~boom.~~boom, then tuned with a NanoVNA.

5-Element Yagi Plans for 915 MHz

A typical 5-element yagi provides approximately 8-9-10 ~~dBd~~dBi (~~10-12~~roughly ~~dBi)~~7-8 dBd) gain with a tight forward ~~beam~~beam. -Reaching ~~good~~12 ~~for~~dBi generally requires 7-8 elements. With clear line of sight, a full Fresnel zone, adequate height, and a matching antenna on the far end, such a yagi can support links of ~~10-50+~~10 ~~km.~~km or more; the realistic range depends on transmit power, terrain, and spreading factor as much as on antenna gain, so treat long-range figures as best-case line-of-sight, not routine.

FCC compliance note: A yagi above 6 dBi exceeds the 6 dBi reference gain in FCC 15.247(b)(4)(i). When used at 902-928 MHz, conducted transmit power must be reduced dB-for-dB for every dB of antenna gain above 6 dBi (for example, a 10 dBi antenna requires conducted power no greater than 26 dBm). The EIRP ceiling of about 36 dBm (4 W) is a derived limit (30 dBm conducted + 6 dBi), not a bonus you add gain on top of, and there is no relaxed point-to-point antenna allowance at 915 MHz.

Element dimensions (915 MHz, 5-element)element, nominal - tune with a NanoVNA):
Reflector: 178 mm (7.01")
Driven element: 163 mm (6.42") - center-fed dipole (trim toward ~155 mm for resonance)
Director 1: 151 mm (5.94")
Director 2: 147 mm (5.79")
Director 3: 144 mm (5.67")

Spacing from reflector:
Driven element: 49 mm (1.93")
Director 1: 115 mm (4.53")
Director 2: 210 mm (8.27")
Director 3: 330 mm (13.0")

Materials

Elements: 3/16" (4.8mm) aluminum rod or welding rod. Available at hardware stores.
Boom: 1/2" (12mm) square aluminum extrusion, 400mm long. Also available as wooden dowel (slightly less rigid but fine for hobby use).
Driven element: ~~Requires~~Built as a ~~folded~~split (center-fed) dipole orfed through a gamma ~~match;~~match or ~~use a commercial~~ 50-ohm hairpin ~~match.~~match ~~The~~- ~~easiest approach: use 1/8" aluminum rod with a coax connector at~~see the ~~center.~~construction steps below.
Feedline: Use RG-174 or LMR-~~195;~~195 only for a short (under ~1 m) pigtail, since RG-174 loses roughly 1 dB per metre (~30 dB per 100 ft) at 915 MHz. For any real cable run, use low-loss LMR-240 or LMR-400-class coax. SMA connector at the antenna end.
Hardware: 1/4-20 stainless bolts and nylon locknuts to mount elements to boom.

Construction Steps

Cut all elements to specified lengths using a hacksaw or pipe cutter. Deburr ends.
Mark boom at element spacing positions.
Drill 3/16" holes through boom at each position.
Thread ~~elements~~the reflector and directors through their boom holes and secure with nylon locknuts (finger-tight then 1/4 turn more). These are single, continuous rods.
~~Center-solder~~Build ~~SMA~~the ~~connector~~driven element as a split dipole: instead of one continuous rod, use two collinear half-elements (each about a quarter-wavelength, ~38 mm) mounted on an insulating block at the boom center, with a small gap (~3-5 mm) between their inner ends.

Feed it with one of these matches:

Direct/gap feed (simplest): Solder the coax center conductor to one half-element and the coax shield to the other half-element across the center gap. A bare split dipole presents roughly 50-70 ohms, close enough to test; add a current balun (a few turns of the coax through a ferrite at the feed point) to keep RF off the coax shield. Gamma match (for a continuous-rod driven element): If you prefer one solid driven rod grounded to the boom at its center, run a parallel gamma rod (about 1/10 the driven-element length) spaced ~10-15 mm alongside one half, connect the coax center to the gamma rod through a small series capacitor (a few pF, often a short coax-sleeve trombone), and bond the coax shield to the driven element at center. Adjust the ~~exact~~gamma ~~center~~rod ~~point.~~length, spacing, and capacitance for lowest SWR. ~~Attach~~Weatherproof ~~feedline~~the tofeed ~~driven~~point ~~element.~~and connector after tuning.

Testing Your Yagi

After construction, verify performance:

Use a NanoVNA to check SWR at 915 MHz. Target: SWR less than 2:1, ideally below 1.5:1. Adjust the match (and trim the driven element toward resonance) as needed.
Compare RSSI at a fixed test point vs. a reference omni - the yagi should show roughly 6-10 dB improvement in its forward direction. Measured improvement varies with the environment, multipath, and reference antenna, so this is a typical figure, not a guarantee.
Note the half-power beamwidth: a 5-element yagi has ~~approximately~~roughly ~~50-60~~55 degree horizontal beamwidth. ~~Alignment~~For ~~must~~best beperformance, ~~accurate to~~aim within 25about +/-15 degrees ~~for~~(roughly ~~full~~half ~~performance.~~the half-power beamwidth) of the far station.