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Chameleon Knowledge Base · The Complete Online HF Antenna Handbook

CHA LEFS 4010 Configuration Guide: Parks on the Air (POTA)

For POTA, deploy the CHA LEFS 4010 as a one-support sloper or two-support horizontal EFHW and operate on 40, 20, 15, and 10 meters without a tuner under normal installation conditions.

Product Installation Guides CHA LEFS 4010 Reviewed 2026-07-14
Quick Answer: For POTA, deploy the CHA LEFS 4010 as a one-support sloper or two-support horizontal EFHW and operate on 40, 20, 15, and 10 meters without a tuner under normal installation conditions.

Application Overview

Quick Answer: For POTA, deploy the CHA LEFS 4010 as a one-support sloper or two-support horizontal EFHW and operate on 40, 20, 15, and 10 meters without a tuner under normal installation conditions. Why It Works Well for POTA The CHA LEFS 4010 combines a resonant 65-foot radiator, compact 49:1 transformer, integrated line winder, and lightweight construction. One operator can normally deploy it in approximately ten minutes. Choose the Deployment Available support Recommended deployment Primary advantage One tree or mast End-fed sloper Fastest standard setup Two trees or supports Horizontal EFHW Flexible height and orientation Regional 40-meter objective Horizontal at approximately 12–15 feet NVIS-oriented high-angle radiation What to Bring CHA LEFS 4010 End Assembly and 65-foot radiator Selected Chameleon feed line with integrated RFI choke Support cord such as CHA PARACORD-50 Throw bag or another safe method of placing support cord Tent stake when needed for the low end Compact analyzer or the radio's low-power SWR indication Band Coverage Use 40, 20, 15, and 10 meters without a tuner after confirming a suitable installation. A tuner may extend the standard EFHW configuration to 30, 17, and 12 meters. Operators wanting resonant dipole operation can use the CHA LINK-D, CHA LINK-D15, or CHA WARC-D optional wire sets with the dedicated DIPOLE connections. Field Procedure Inspect the site for power lines, pedestrian paths, and conductive hazards. Place the End Assembly approxima

This application is a complete system problem. Antenna geometry, propagation objective, supports, feed line, matching components, return current, operating power, weather, and deployment time must agree with the mission. The goal is not merely to obtain a match; it is to produce a safe, repeatable station with useful radiation and known limitations.

Mission Definition

Record required bands, contact range, mode, duty cycle, power, operating duration, setup time, available footprint, support height, terrain, weather, transport limit, and operator experience. Identify whether the objective is regional high-angle coverage, lower-angle DX, rapid frequency agility, low receive noise, concealment, unattended use, or repeated relocation.

Write disqualifiers before selecting hardware. A system should be rejected when it exceeds space, support, transport, tuning, weather, compatibility, or safety boundaries—even if it performs well in another mission.

Engineering Basis

Treat the radio, feed line, transformer or tuner, loading network, radiator, counterpoise or radial system, mast, ground, and nearby conductors as one RF system. Use λ ≈ 300/f(MHz) metres to compare dimensions and height with wavelength. Current distribution controls radiation; loss in conductors, coils, ferrites, line, soil, and poor contacts becomes heat.

A tuner transforms impedance presented at its reference plane. It cannot recover dissipated energy or guarantee a favorable pattern. Likewise, broad bandwidth can represent useful operating range or added loss. Compare impedance, stability, receive SNR, repeatable on-air observations, geometry, and component condition rather than using SWR as the only score.

Documented Configuration

For CHA LEFS 4010, verify the exact current guide, included components, radiator, matching device, counterpoise, feed line, choke, supports, adapters, bands, power limitations, and environmental instructions. Physical fit does not prove electrical or mechanical compatibility. Undocumented combinations must be labeled experimental and must not be promoted as verified Chameleon recipes.

The System Builder “Build with it” action remains limited to CHA MPAS 2.0, CHA MPAS Lite, CHA TDL, CHA PRV/PRV 2.0, CHA BV, and CHA V-DIPOLE. MPAS operators must select the documented HYBRID-MINI or HYBRID-MICRO variant. Other systems use “Explore handbook” until a current verified recipe exists.

Field Workflow

  1. Survey the site. Identify power lines, public paths, unstable ground, nearby metal, wind exposure, and safe operating boundaries.
  2. Inspect every component. Check conductors, connectors, insulation, strain relief, mounts, guys, anchors, feed line, and weather seals.
  3. Build from the current guide. Record all parts, geometry, height, orientation, counterpoise, feed-line routing, and tuning settings.
  4. Measure a baseline. Save frequency, impedance or SWR, reference plane, receive noise, known signals, and environmental conditions.
  5. Test at low power. Watch for arcing, heating, RF feedback, instability, movement, or intermittent behavior.
  6. Change one variable. Repeat the same measurement after each controlled adjustment.
  7. Preserve a build sheet. Record the final reproducible configuration and its limitations.

Worked Interpretation

Assume the deployment produces a good station-end SWR but disappointing reports. First confirm that the intended geometry supports the desired elevation angles. Then inspect feed-line loss, common-mode current, coil or transformer heating, counterpoise continuity, nearby lossy material, and whether the station-end reading hides a different feed-point condition.

Move or replace only one suspected element, repeat the same test, and compare within a short time. If receive noise falls when the feed line is rerouted or a choke is correctly located, common-mode pickup was probably contributing. If bandwidth becomes unusually broad while signals weaken, investigate added loss rather than declaring the match improved.

Operational Optimization

Optimize for the mission rather than the analyzer trace. For regional work, height and geometry that support higher elevation angles may be preferable. For DX, a suitable lower-angle pattern and clear direction may matter more. For rapid frequency changes, agility and repeatability may outweigh the peak performance of a narrow single-band arrangement.

On receive, compare signal-to-noise ratio. On transmit, use repeatable field-strength or on-air comparisons while controlling band conditions as much as practical. Log UTC, frequency, geometry, power, and observations. A single contact proves possibility, not consistent performance.

Common Errors

  • Selecting by product name or band count without defining the propagation objective.
  • Treating a matched impedance as proof of efficiency.
  • Inferring compatibility from a connector, thread, or older guide.
  • Changing several variables and losing diagnostic evidence.
  • Ignoring return current, feed-line routing, nearby conductors, soil, or support conductivity.
  • Inventing wind, load, exposure, power, or permanence claims without current documentation.

Safety and Stop-Work Conditions

Maintain generous clearance from overhead conductors; treat carbon-fiber supports as conductive. Stop for lightning, unsafe wind, unstable supports, damaged insulation, loose or hot connectors, arcing, RF feedback, uncontrolled public access, or uncertain compatibility. Evaluate RF exposure with current applicable requirements and the actual frequency, power, mode, duty cycle, geometry, and access conditions. Never infer a universal safe distance from antenna type or SWR.

Related Handbook Pages

  • CHA LEFS 4010 Product DNA: Complete System Overview
  • Antenna Selection: A Mission-First Decision Guide
  • Engineering Design Tradeoffs in Portable HF Antennas
  • Feedline Loss and Overall System Efficiency
  • Understanding Common-Mode Current
  • Modular Antenna Build Sheets and Field Repeatability

Source and Revision Note

This page is an independent Chameleon Knowledge Base synthesis informed by The ARRL Handbook for Radio Communications, 99th edition (2022), and The ARRL Antenna Book for Radio Communications, 24th edition (2019), together with current Chameleon documentation. It does not reproduce ARRL prose, tables, drawings, photographs, or extended passages. Use the live product page for availability and included parts, and the newest user guide for assembly, specifications, operation, and safety.

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