How to Use Laser Survey on RTK GNSS: AP30 & AP40 Field Guide
The laser survey function on APEKS AP30 Laser and AP40 Laser+ allows you to measure the 3D coordinate of any point that the pole tip cannot physically reach — a wall face, a building corner across a road, a pipe invert across a trench, or a slope face on an embankment. The receiver calculates the target coordinate by combining the RTK position of the GNSS antenna, the measured pole height, the laser distance, and the laser aiming angle. The result is a survey-grade coordinate for a point you never touched. AP30 reaches 30 metres; AP40 Laser+ reaches 120 metres. Both use the front-facing camera to aim the laser precisely using a crosshair overlay on the controller.
- What Does the Laser Survey Function Do?
- AP30 Laser vs AP40 Laser+: Which Range Do You Need?
- How the Laser Coordinate Calculation Works
- Step-by-Step: Laser Survey (Measuring an Inaccessible Point)
- Step-by-Step: Laser Stakeout (Setting Out with Laser Offset)
- Camera and Laser Aiming Tips
- Accuracy and Limitations
- Common Laser Survey Mistakes
- FAQ
You are surveying a building façade across a busy road. The pole tip cannot reach the corner. A total station would need a separate setup. Without a laser, you skip the point or access it unsafely. With the AP30 or AP40 Laser+, you stand on the footpath, aim the front camera crosshair at the corner, fire the laser, and ApekSurv records the building corner's coordinate — from 30 metres away, without moving. The laser survey function on APEKS laser receivers turns otherwise inaccessible survey points into standard RTK observations. This guide covers the complete workflow: how to activate and use laser survey for measurement, how to use laser offset for stakeout, aiming technique, and the common mistakes that reduce laser accuracy.
What Does the Laser Survey Function Do?
The laser on AP30 Laser and AP40 Laser+ solves one problem: the pole tip cannot reach the point you need to measure.
Inaccessible Measurement Points. Building corners across busy roads, pipe inverts across drainage channels, bridge abutment faces, utility poles on the far side of a fence, wall faces in confined spaces. Without laser, these points require unsafe access or a separate total station setup. With laser, you measure from a safe distance in seconds.
Slope and Embankment Survey. Road embankment toe and crest, quarry bench faces, batter slope faces on cuttings — surfaces that cannot be safely accessed with a pole. The laser measures the face from the bench or carriageway.
Laser Stakeout Offset. Setting out a design point that falls inside a wall, under water, or on a surface where a physical mark cannot be placed. The laser calculates the offset position from the receiver to the design point and guides you to the correct standoff distance.
The Camera Role. The front-facing camera on AP30 and AP40 Laser+ is not for photography — it provides the live aiming view on the controller screen. You see the target through the camera feed with a crosshair overlay and fire the laser precisely at the point to be measured.
AP30 Laser vs AP40 Laser+: Which Range Do You Need?
The right model depends entirely on the distances you routinely face. The table below shows typical field scenarios and which receiver covers them.
| Scenario | AP30 (30 m) | AP40 Laser+ (120 m) |
|---|---|---|
| Building corner across a 2-lane road (~15 m) | ✓ Sufficient | ✓ Sufficient |
| Road edge from centreline — wide highway (>30 m) | ✗ Out of range | ✓ Required |
| Pipeline invert across small drain (~10 m) | ✓ Sufficient | ✓ Sufficient |
| Pipeline invert across large channel (>30 m) | ✗ Out of range | ✓ Required |
| Embankment face measurement (~20 m) | ✓ Sufficient | ✓ Sufficient |
| Quarry bench face (~60 m) | ✗ Out of range | ✓ Required |
| Bridge abutment from riverbank (~50 m) | ✗ Out of range | ✓ Required |
| Urban cadastral — narrow streets (<20 m) | ✓ Sufficient | ✓ Sufficient |
If your work consistently involves targets within 30 metres — urban building survey, narrow road utilities, confined site detail — AP30 Laser is sufficient. If targets regularly exceed 30 metres — infrastructure, highways, pipelines, bridges — AP40 Laser+ is required. When in doubt, the AP40 Laser+'s 120 m range eliminates the risk of being range-limited on site.
How the Laser Coordinate Calculation Works
When you fire the laser in ApekSurv, the software combines four measurements to calculate the target's 3D coordinate:
1. RTK Position of the GNSS Antenna. The receiver's Fixed RTK position at the moment of laser firing — ±8 mm horizontal accuracy.
2. Pole Height. The vertical distance from the ground to the GNSS antenna phase centre, entered in ApekSurv before the session. Errors in pole height become errors in every laser measurement — enter it precisely.
3. Laser Distance. The measured distance from the laser emitter to the target surface. AP30: ±(8 mm + 5 mm/m) within 30° tilt. AP40 Laser+: same accuracy specification.
4. Laser Aiming Angle. The horizontal and vertical angle of the laser beam relative to the receiver, measured by the IMU at the moment of firing. The 120° IMU records the receiver tilt precisely so the angular offset to the target is computed correctly.
ApekSurv combines these four values in real time and outputs the target's easting, northing, and elevation directly — stored in the project file alongside your standard RTK observations. You see no maths; the result appears on screen within one second of firing.
Step-by-Step: Laser Survey (Measuring an Inaccessible Point)
Step-by-Step: Laser Stakeout (Setting Out with Laser Offset)
Camera and Laser Aiming Tips
Stabilise the receiver before firing. The IMU records receiver tilt at the moment of laser firing. Any movement during firing introduces angular error into the coordinate calculation. Rest the pole against your body, a vehicle, or a solid surface. On windy days, shelter the receiver before firing.
Use zoom on the camera feed. ApekSurv allows digital zoom on the camera feed for precise crosshair placement on distant targets. At 80–120 m (AP40 Laser+), zoom in before firing to confirm the crosshair is on the exact target point.
Bright sunlight aiming. Green lasers are significantly more visible than red lasers in daylight. In direct equatorial sunlight at long distances, shade the target surface with a hand or hat to make the green dot visible for visual confirmation of aim.
Multiple shots on critical points. For important points (building corners, boundary marks, structural features), fire three times and compare the three coordinate results. If all three agree within 20 mm, accept the average. If one result differs significantly, it likely reflects off a wrong surface — discard it.
Tilt within 30°. Laser accuracy is specified within 30° of tilt. For near-horizontal laser shots (aiming at a wall at the same height as the receiver), tilt is minimal. For steeply angled shots down a slope or up a building, minimise tilt where possible.
Accuracy and Limitations
Laser Accuracy Specification: ±(8 mm + 5 mm/m) within 30° tilt angle. At 10 m: ±58 mm theoretical maximum error from laser alone. At 30 m: ±158 mm theoretical maximum. In practice, careful aiming and stable receiver position typically achieve ±20–50 mm at typical survey distances.
RTK Component: The RTK Fixed position of the receiver contributes ±8–15 mm to the total error. On short baseline Base+Rover deployments, this is typically ±8 mm.
Total Error Budget: For a 20 m laser shot with good technique, expect ±20–40 mm combined accuracy. Sufficient for detail survey, as-built documentation, and offset stakeout. Not sufficient for precise structural setting-out at ±5 mm tolerance — use a total station for that.
Limitations: Laser cannot penetrate glass, water, or mesh. Transparent or highly reflective surfaces may return false readings. Maximum range is reduced in rain, dust, or haze. Dark matte surfaces absorb more laser energy — range may be reduced on very dark targets.
Common Laser Survey Mistakes
Cause: Pole height was not updated after changing pole length, or was entered incorrectly at the start of the session.
Fix: Always verify pole height in ApekSurv before the first laser measurement of each session. Measure with a tape if there is any doubt. The pole height error propagates into every laser calculation in the session — one wrong entry corrupts every laser point.
Cause: The laser has reflected off a nearer surface in the beam path — a chain-link fence, a vehicle, vegetation, or a pole between the receiver and the target.
Fix: Check the line of sight between the receiver and target before firing. Clear any obstructions in the beam path. Fire again and verify the displayed distance matches your visual estimate. On critical points, fire three times and compare.
Cause: The receiver was in Float solution at the time of laser firing. ApekSurv allows laser measurements in Float but the RTK position component carries Float-level error.
Fix: Always confirm Fixed solution before activating laser survey. Check solution status and differential age on the controller before firing. If the site causes persistent Float (urban canyon, scaffolding), achieve Fixed in open sky first, then return to the measurement location — the receiver maintains Fixed better than it initialises under obstruction.
FAQ
Can I use the laser in AR stakeout mode?
What is the maximum range in bright sunlight?
Can I measure a point below the receiver — looking down?
Does laser survey work without RTK Fixed?
Can the AP40 Laser+ replace a total station?
LASER SURVEY TO 120 METRES. NO PRISM. NO SETUP.
APEKS AP40 Laser+ measures any inaccessible point up to 120 metres away — building corners, pipe inverts, slope faces, bridge abutments — in a single laser shot from Fixed RTK. Front camera crosshair aiming, instant coordinate output, no reflector required.
View AP40 Laser+ →References
- ISO 17123-8:2015 — Field Procedures for GNSS RTK
- APEKS AP40 Laser+ Technical Datasheet, 2026
- APEKS AP30 Laser Technical Datasheet, 2026
- ApekSurv Field Software User Guide, 2026