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LiDAR vs Radar para Detección de Obstáculos Industriales

LiDAR vs radar es, en esencia, una compensación de ingeniería: LiDAR resuelve la forma a través de una densa nube de puntos tridimensional, mientras que el radar resuelve la velocidad y atraviesa la niebla. Para un problema de detección de máquinas industriales (un AGV que cruza un muelle de carga, una grúa pórtico que rastrea una carga, un robot colaborativo que trabaja en el mismo espacio que las personas), esta diferencia puede estar entre ver el borde de una plataforma y simplemente ver... un retorno. Esta guía analiza tanto la precisión, el alcance, la resistencia a la intemperie, el precio y la aplicación para ayudar a identificar casos de uso en los que puede ser preferible o incluso mejor combinar las tecnologías. (Actualizado en junio de 2026).

Respuesta corta: LiDAR envía un pulso de luz en el infrarrojo cercano (longitud de onda de 905 a 1550 nm), multiplicado por el eco, para generar una nube de puntos 3D con precisión milimétrica. El radar envía un pulso de ondas de radio de 24 a 77 GHz, midiendo el cambio en la frecuencia de retorno para determinar el alcance y la velocidad. LiDAR es mejor para la forma y resolución de los objetos, mientras que el radar es superior para mediciones de velocidad y protección contra la intemperie.

Conclusiones clave

  • Incluso un radar capaz de ver un objetivo de un metro de ancho a 50 metros no puede distinguir entre la pierna de una persona y un bolardo estático (la ilusión de la sección transversal).
  • Si bien nuestros sistemas LiDAR industriales pueden resolver formas con una precisión de 2 a 10 milímetros, los radares de ondas de mm tienen una resolución de sólo 50 a 200 mm y carecen de la capacidad de determinar la forma.
  • “Sin embargo, ”Radar siempre gana con mal tiempo” no es del todo cierto, ya que aunque el LiDAR en el infrarrojo cercano aún puede funcionar con éxito en condiciones climáticas templadas, el radar ofrece una clara ventaja en términos de efectividad en caso de niebla intensa, lluvia o humo.
  • Un único sistema lidar de 270 grados puede cubrir el campo de visión equivalente a aproximadamente ocho sensores ultrasónicos; por lo tanto, un precio de compra inicial más alto a menudo conduce a costos reducidos para todo el sistema.
  • Por otro lado, para la identificación de personas para robots móviles como los AGV, normas como la ISO 3691-4:2023 y la IEC 61496 exigen cada vez más el uso de dispositivos optoelectrónicos activos certificados (similares a LiDAR) frente a otros tipos de sensores.

Especificaciones rápidas: LiDAR vs Radar de un vistazo

Método LiDAR: pulsos láser de infrarrojo cercano (905 / 1550 nm) · Radar: ondas de radio (24 / 77 GHz)
Precisión LiDAR ±2-10 mm · Radar ±50-200 mm
Gama (industrial) LiDAR 0,1-200 m · Radar 0,2-300 m
Campo de visión LiDAR 270-360° · Radar 60-120°
Salida de datos Nube de puntos LiDAR 3D (forma) · Rango de radar + velocidad (Doppler)
Tiempo LiDAR se degrada en niebla densa · Radar en gran medida inmune al clima
Costo unitario LiDAR ~$300-5.000 · Radar ~$200-3.000

Las especificaciones operativas y de medición se basan en nuestros datos del sensor QJKH, así como en información de especificaciones relacionadas con los radares de ondas mm.

LiDAR vs Radar de un vistazo, la cuadrícula de capacidad de 4 sensores

LiDAR vs Radar de un vistazo, la cuadrícula de capacidad de 4 sensores

La mayoría de las páginas que comparan LiDAR y radar limitan su análisis a dos opciones. En realidad, al elegir un sensor para uso industrial, es probable que tenga cuatro opciones de detección remota activa (LiDAR, radar, ultrasónico e infrarrojo) para elegir. Nuestra comparación utiliza una cuadrícula de capacidad de cuatro sensores, en lugar de la comparación limitada de dos columnas, para determinar qué tecnología se adapta mejor a las necesidades únicas de su aplicación. En esencia, hay una compensación fundamental a la que nos referiremos como división de forma versus velocidad.

La cuadrícula de capacidad de 4 sensores: para la detección de obstáculos, LiDAR proporciona datos de forma de ±2-200 mm, mientras que el radar proporciona velocidad a través de la niebla a ±50-200 mm.
Sensor Principio Rango Precisión Datos Tiempo
LiDAR Tiempo de vuelo láser 0,1-200 m ±2-10 mm Nube de puntos 3D Degradaciones en niebla densa
Radar (mmWave) Ondas de radio + Doppler 0,2-300 m ±50-200 mm Rango + velocidad Weather-immune
Ultrasonic Sound waves 0.02–10 m ±10–30 mm Distance only Sensitive to airflow
Infrared / PIR Thermal radiation < 10 m Presence only Motion / presence Affected by heat

QJKH source – published sensor specs on LiDAR, radar, ultrasonic, infrared sensors.

Since both lidar and radar employ similar methods for active remote sensing, our comparison of these technologies presents their opposite strengths instead of classifying them as competitors. While lidar relies on the principles of light to characterize the physical attributes of an object, radar primarily uses radio frequency energy and is resilient to atmospheric interference. Few pages on the distinction between LiDAR vs. radar will include four options from a single manufacturer, but here at QJKH, we provide a four-sensor capability grid as we understand the question is rarely “should I use Lidars or Radars?” in a generic sense, but rather “should I use Lidars or Radars in this specific lane, dock, cell, or other space?”. Picking the wrong sensor here is the most common and costly mistake, because each one fails differently — so QJKH benchmarks all four against ISO 3691-4 person-detection requirements before recommending one. We’ll break down each factor in the table below:

Cómo funciona LiDAR (detección de luz y alcance)

Cómo funciona LiDAR (detección de luz y alcance)

LiDAR — short for light detection and ranging — operates by emitting a laser pulse and timing the return. With light speed a known constant, the time it takes to return converts to range. Because lidar systems emit tens of thousands to millions of laser pulses per second, they capture 3D data of whatever surrounds them, creating a 3D “point cloud” of any landscape or structure.

LiDAR uses laser light as an active form of remote sensing to detect objects and fix their position in space. The trade-off is that this millimetre precision depends on clean optics: because near-infrared light scatters in dense fog, a LiDAR’s range can drop and create a detection risk just when an outdoor robot needs it, which is why eye-safe Class 1 designs certified under ISO and IEC 60825-1 standards dominate industrial use and why QJKH engineers specify them for shared workspaces.

Each industrial lidar system comprises three components: a laser light source (usually 905 nm or 1550 nm), a scanner that precisely angles and redirects the laser light as it moves across the environment (like a spinning mirror or mems micro-mirror), and a detector that catches reflected light to convert it to digital data and ultimately position and image. Time-of-flight measurements of distance gives lidar millimetre class accuracy. If long distances are required in demanding outdoor environments, the 1550nm laser offers increased pulse power with inherent eye-safety properties.

📐 Nota de ingeniería

With the exception of a few industrial applications, industrial lidar generally uses Class 1 lasers in compliance with IEC 60825-1. That makes the laser light “safe under reasonably foreseeable conditions of use”, without the need for specialized protective eyewear. When ordering safety scanners that are intended for use in areas shared by humans, make sure the devices bear a Class 1 rating, and note the laser wavelength (905nm is the more common, less expensive choice, but 1550nm provides better range and safety margins.)

Lidar stands for light detection and ranging, and lidar systems operate the same way whether they are airborne lidar systems on a drone or fixed lidar devices that use light to range on a loading dock: lidar operates on reflected light, so the shorter the time it takes for a pulse to return, the closer the object. Because lidar provides detailed 3D data, lidar excels where shape matters — lidar can detect a person’s outline, not just their presence, and that lidar data lets autonomous systems classify objects. That is why the applications of lidar span autonomous driving, autonomous cars, self-driving cars, 3D mapping and warehouse safety.

We use that dense point cloud and lidar technology for industrial applications like our industrial lidar sensors for safety and security, autonomous driving, and 3D mapping. Interested in how these industrial LiDAR sensors do it? Check out this explanation of how a 3D LiDAR sensor builds volumetric data instead of flat scan images.

Cómo funciona el radar (detección de radio y rango/onda mm)

Cómo funciona el radar (detección de radio y rango/onda mm)

Radar — radio detection and ranging — operates like LiDAR but uses radio waves rather than light. Radar relies on radio waves to detect objects: it sends radio waves that hit a target and reflect back to the radar unit, then measures both their flight time and any frequency shift. That Doppler shift lets radar report an object’s speed in a single measurement, whereas lidar can’t.

Radar systems use a band of radar wavelengths across the radio frequency spectrum, and because a radio wave is a long electromagnetic wave that penetrates obstacles unlike visible light, longer radar waves see through conditions that blind optical sensing technology. Radar can detect objects and their velocity at once, producing radar data that pairs range with speed for other sensors to use. Typical automotive and industrial radar systems use the 24 GHz and 77 GHz millimeter-wave bands. Radar’s weakness is resolution: because the radio wavelength is long, two objects 30 cm apart can blur into a single return, which is a real problem when a safety function must pick a person out of clutter. That structural limitation is the reason QJKH pairs radar with a certified laser scanner rather than relying on radar alone for person-detection.

¿el radar o lidar tiene una longitud de onda más corta?

LiDAR has the much shorter wavelength. Light waves in LiDAR are in the ~700-1550 nanometer range, while radio waves used in radar have wavelengths from roughly 0.3-100 cm. This disparity is the origin of almost all of the subsequent differences between the two technologies: short waves “see” small things (LiDAR), while long waves “blast through” the haze (radar). Radar exchanges detail for penetration.

Modern radars are generally frequency-modulated continuous-wave (FMCW) and sweep their radio frequency back and forth to determine both the range and the velocity at a single pulse; this contrasts with earlier pulsed radar simply detecting range and velocity on individual pulses. According to mm wave sensing research compiled by the U.S. National Library of Medicine (PMC), 77GHz Automotive radars can reliably “identify vehicles located 200-250 meters away” (long range is needed). Compared to lidar, radar technology also dominates traffic management, weather forecasting, and environmental monitoring, where range takes precedence over resolution. And unlike sonar technology, which relies on sound waves underwater, or passive sensors like cameras that read ambient light, radar works actively in air through nearly any weather or lighting. Radar sacrifices resolution for reach – which the next section quantifies.

Precisión y resolución espacial, donde LiDAR avanza

Accuracy & Spatial Resolution, Where LiDAR Pulls Ahead

¿lidar es más preciso que el radar?

Yeah, for shape and position, LiDAR is vastly superior. For example, Industrial LiDAR has a resolution of about 2-10 mm, returns a full point cloud and costs under $5,000 for an adequate model, whereas mm wave radar returns the speed of objects (but not shape, at least not reliably or very precisely) to maybe 50-200 mm with over a hundred times the form factor and price.

This isn’t a configuration issue, it’s a physics limitation. Radar’s large wavelengths and small apertures are unable to separate points closely spaced in any dimension except their travel time (the return trip).

This is our “Cross-Section Illusion.” Radar confidently says that at the five-meter depth of field, something has roughly 1 m² in radar cross-section, but it can’t distinguish a human’s leg from a pallet edge at that same range. The system “knows” something is there but sees it in the wrong shape. Such limitations can feel painful for researchers, and they’re one of the main motivations for efforts that teach machine-learning systems to upsample radar images to a LiDAR-style point cloud — this is the kind of work that Duke’s RadCloud framework is designed to enable, since raw radar isn’t as high resolution as the scan lines of a laser.

✔ LiDAR advantages

  • Millimetre accuracy and true 3D shape
  • Classifies objects (person vs forklift vs rack)
  • Wide 270–360° field of view per unit
  • Dense point cloud for zone gating

⚠ LiDAR limitations

  • Range drops in dense fog, smoke or heavy dust
  • No direct velocity in a single shot
  • Higher unit cost than radar or ultrasonic
  • Moving parts in spinning designs (solid-state fixes this)
⚠¦ Concepto erróneo común

”More accurate is always better” is false for most things. If all that matters is that a car is approaching at 12 m/s, radar tells you in real time, but LiDAR takes multiple frames to tell you that. Accuracy matters for when shape or location affect your safe action, not your need for speed.

Rango de detección y campo de visión

Detection Range & Field of View

In a sense, radar penetrates the farthest – Industrial Radar covers a span of roughly 0.2-300 meters while the range of a LiDAR product falls from 0.1 to 200 meters; even longer, in fact, for some dedicated long-range surveillance RADAR products. However, range isn’t often the limiting factor indoors. Field of view is. A single 270-degree safety laser scanner covers an entire corner of the mobile robot path, where a 60-120 degree RADAR node must have siblings to cover the same area. The gap matters because every blind wedge between narrow radar cones is a place where an AGV can clip a pallet or a person, so integrators either add nodes or accept the risk. In a busy three-aisle pick zone, one 270° scanner does the job of three 90° radar nodes.

📐 Nota de ingeniería

Coverage math beats datasheet range. To wrap a 270° protective field around an AGV using 90° radar nodes you need at least 3 radar units plus the mounting, wiring and fusion logic — versus one 270° LiDAR. When you compare range, compare how many units it takes to cover the angle you actually need. Our industrial LiDAR sensor selector models this coverage math per layout.

For long-range outdoor perimeter sensing, radar’s reach and weather resilience are very real advantages. For confined indoor angular coverage – by far the most common obstacle avoidance task – LiDAR’s broad field of view generally wins in number of units/zone.

Clima y medio ambiente, donde gana el radar

Weather & Environment, Where Radar Wins

Radar’s long radio waves greatly reduce the effects of haze, fog, cloud, rain and dust, making it the fundamental standard for air traffic control and maritime navigation. LiDAR’s near-infrared laser light bounces off the same airborne particles. Both the RAND Corporation classic study on the attenuation of electromagnetic radiation by haze, fog, cloud and rain, and published US military measurements of fog attenuation at millimeter frequencies follow a similar pattern: higher frequency waves lose orders of magnitude more energy to aerosols than lower ones. The practical risk is real — in dense fog a LiDAR’s effective range can collapse exactly when an outdoor AGV most needs to see, because the laser scatters off droplets the radio waves pass through. That is the structural reason QJKH pairs a scanner with mmWave radar in fog-prone yards.

However the popular maxim “radar is always better in bad weather” doesn’t hold up: in light rain or light fog, a 905 nm LiDAR still provides usable data — experienced practitioners in robotics communities report that rain affects it much like a camera, not catastrophically. Only in very dense fog or smoke does the advantage become clear, with laser light losing around 200 dB/km in the most extreme cases. So, the true rule is conditional, not absolute. In practice, an outdoor logistics yard with seasonal fog and 200 m sightlines runs radar as its primary outdoor obstacle detection sensor, while the same operation uses LiDAR for the precise indoor docks — a split QJKH sees across most mixed-environment sites.

💡 When to let environment decide
  • Clean indoors climate-controlled LiDAR; weather not an issue.
  • Outdoors yard with periodic fog, welding smoke, grain or cement dust radar, or combine with both.
  • Freezer with frost and condensation tests on location, both can have trouble, radar usually wins.

Integración de costos y sistemas, el total real

Cost & System Integration, The Real Total

Per unit, radar is often lower cost: industrial radar costs generally $200-3,000; industrial LiDAR is $300-5,000. Exact prices depend upon quantity, model and supplier and should be checked with a current quote. Automotive solid-state LiDAR average selling prices fell over 30% between 2023 and 2025 by one market estimate, but unit value shouldn’t be the consideration when designing.

The figure that drives a project is total system cost for the coverage you need. In QJKH deployments, one 270° industrial LiDAR replaces roughly eight ultrasonic obstacle-avoidance sensors, because a single scanner sweeps the whole forward arc that eight fixed ultrasonic cones would otherwise cover. When you include the wiring, controller channels, mounting hardware and system integration time needed for that array, the single LiDAR with a higher list price often results in a lower installed cost — a lower-priced sensor that requires eight mounts is not a net saving. The trade-off only flips outdoors, where a machine shop or yard fighting dust may still need radar.

Cost factors that move the total

  1. Sensors per zone (field of view ÷ coverage angle)
  2. Controller inputs, cabling and IP-rated connectors
  3. Installation and programming hours (point-cloud zone gating vs simple range gating)
  4. Calibration and maintenance over the sensor’s life
  5. Certification effort for the safety function

Take a full picture before you make decisions about unit price alone – our LiDAR ROI estimator calculates the installed price across sensor quantities, and solid state LiDAR doesn’t have moving parts that rack up maintenance expenses.

Ajuste de casos de uso, el mapa de decisión de geometría o velocidad

Ajuste de casos de uso, el mapa de decisión de geometría o velocidad

¿cuál es mejor para la detección de obstáculos, LiDAR o radar?

For most indoor industrial obstacle detection, LiDAR is the better primary sensor because the safety question is geometric: exactly where is the person, the rack, the load edge. Radar becomes the better choice when the environment defeats optics — dust, glare, dense fog — or when velocity is the real decision variable. The Geometry-or-Velocity Decision Map below routes the common industrial scenarios.

The Geometry-or-Velocity Decision Map: matching the lidar vs radar choice to nine industrial obstacle-detection scenarios by environment class.
Aplicación Environment class Recommended sensor Why
Indoor AGV navigation Clean indoor LiDAR Wide FOV, person-detection geometry, clean air
Outdoor fleet in fog / dust Harsh outdoor Radar (or fusion) Weather immunity, longer range
Gantry / overhead crane Indoor overhead LiDAR (2D safety scanner) mm-level edge and intrusion detection along the track
Cobot / shared cell Collaborative LiDAR Precise zone gating around people
Long perimeter security Outdoor wide-area Radar Range and velocity over wide areas
Automotive ADAS Mixed / road Fusion (radar + LiDAR + camera) Redundancy across weather and speed
AS/RS shuttle & stacker Indoor high-density LiDAR Point-cloud collision avoidance around racking and protruding cargo
Pallet truck / tugger AMR Indoor mixed traffic LiDAR Person detection in shared aisles, ISO 3691-4 performance level
Dock & yard interface Indoor-outdoor transition Fusion Handles changing light and weather at the threshold

Source: QJKH application engineering across AGV, gantry-crane and cobot deployments.

The field results mirror the map. At a 40,000 m² port distribution centre, updating an AGV fleet to LiDAR zone gating reduced false-positive emergency stops by 87% (from 4.2 to 0.5 stops per 8-hour shift across 25 days of data) because the point cloud could tell an actual personnel intrusion from a fleeting shadow. A container port crane anti-collision system recorded no near misses across 14 months when updated from ultrasonic sensing, with each prevented incident equivalent to $120,000. Work-in-process inventory and production efficiency has also been raised as work in a cobot cell increased from 62 to 91% of its capacity thanks to LiDAR zones enabling human and robot to co-locate safely and closely, without irritating shutdown.

“Buyers ask whether radar or LiDAR is ‘better,’ but on the floor the question is always geometry or velocity. If the safety case depends on knowing exactly where a person is, we specify a LiDAR scanner. If it depends on how fast something is closing across an open yard, radar earns its place, and in fog we run both.”

Applications Engineer, QJKH technical team

For crane-related guidance, see overhead crane LiDAR; for tight indoor footprints, a 2D LiDAR sensor handles single-plane protective fields efficiently.

Cuándo combinar ambos, LiDAR + Fusión de sensores de radar

Cuándo combinar ambos, LiDAR + Fusión de sensores de radar

Combine LiDAR and radar when no single sensor covers every condition the application throws at it. Use fusion for outdoor AGVs, yard automation, and dock or crane work where fog, dust, or rain can blind a laser scanner but a 77 GHz radar still reports range and velocity. LiDAR supplies the certified shape and person-detection; radar adds the all-weather speed backup.

¿se pueden utilizar LiDAR y radar juntos?

Yes – and the common solution for all-condition coverage is often to marry them. Rather than being rivals, radar and LiDAR are complementary: sensor fusion pairs LiDAR’s shape and category data with radar’s speed and environmental immunity, so the system keep a usable picture when either sensor alone would fail.

There’s plenty of prior art in patent literature on this topic, for instance, a United States patent for a camera-radar fusion sensor system (US10852419B2) and a long-range steerable LiDAR system (US9880263B2) based on time of flight detection technology.

A handy industrial one-two, used in practice on outdoor AGV and yard applications, is to place the LiDAR scanner in the primary guard for accurate person-detection and mount the 77 GHz mm wave radar on the front for both velocity and an inclement-weather backup. This all has compliance significance: With an “active sensing” regulation – the sort defined in IEC 61496 – the protective product itself has to sense a person and come to rest in a safe state, which demands the known and predictable geometry of a laser scanner. Radar complements but generally can’t replace a certified safety scanner. The risk of skipping the pairing is concrete: a fog-blinded LiDAR with no radar backup can miss a moving forklift, so QJKH engineers a LiDAR-plus-mmWave pair for outdoor fleets because each sensor covers the other’s failure mode.

Perspectivas de la industria, qué está cambiando en 2026

Industry Outlook, What's Changing in 2026

The most compelling case to revisit your sensor strategy now isn’t marketing, it’s regulatory. The 2023 edition of ISO 3691-4, the AGV/AMR safety standard, defines person-detection safety functions using standardized performance levels. Commissioning driverless trucks in 2026? Better make sure your obstacle-detectors conform to that 2023 edition. That means buying certified active opto-electronic scanners, aka LIDAR-class, instead of just a handful of tacked-on radars.

To be fair, at the higher end, LIDAR and radar boundaries have blurred in recent years. 4D imaging radar provides vertical resolution and a crude shape profile; FMCW LIDAR offers instantaneous per-point velocities. It’s a story of two technologies adopting one another’s unique advantages. Radars are finding significant application in mobile robotics where LIDAR and vision fall short (according to coverage from the Robot Report), and sophisticated radars are narrowing the performance gap with LIDAR. Meanwhile, falling costs for LIDAR due to high volume in China are accelerating a push toward LIDAR-centric fusion of sensory information. While 4D radar and FMCW LIDAR forecasts predict steep growth curves for the coming years, focus less on the sales figures and more on what the end user is facing: tighter performance standards and lower installation costs for LIDAR-based safety.

💡 What to do in 2026

Planning to install an AGV or crane safety system this year? Address ISO 3691-4:2023 first and ensure your project meets those safety performance levels, usually via a certified LIDAR scanner, supported by radar when weather conditions dictate.

Preguntas frecuentes

¿cuál es la principal diferencia entre LiDAR y radar?

Ver respuesta
LIDAR es una técnica óptica. Utiliza láseres de luz infrarroja cercana para determinar el alcance y la forma tridimensional capturando el reflejo de un objeto. La pequeña longitud de onda de los láseres le confiere una alta precisión espacial; LIDAR sobresale así en la definición de la forma. El radar, una técnica de ondas de radio, puede determinar el alcance y la velocidad de los objetos, beneficiándose de la capacidad de una longitud de onda de radio más larga para penetrar el clima y medir con precisión qué tan rápido se mueve un objeto.

¿Puede el radar detectar una persona u objeto pequeño?

Ver respuesta
Si bien un radar puede confirmar la presencia de un objeto similar a una persona y su velocidad, el radar tiene una precisión espacial menor. Puede identificar un objeto, pero tiene dificultades para diferenciarlo del desorden ambiental cercano, como los arbustos. Un escáner LIDAR de grado de seguridad, especialmente un tipo Fov ancho, es un mejor sensor elegido para localizar con precisión a una persona cuando el sistema de seguridad lo requiere. Luego, un sensor de radar proporciona un respaldo complementario para el clima y la velocidad.

¿la policía utiliza LiDAR o radar?

Ver respuesta
Piense en LIDAR y el radar en la vigilancia: una pistola de velocidad de radar tiene una amplia cobertura pero carece de precisión; una pistola de velocidad LIDAR “láser” es muy precisa pero se centra en un solo vehículo entre la multitud. La compensación se extiende a la robótica: mientras que el láser LIDAR, más estrecho, ofrece una precisión de detección precisa, el radar de ondas de radio ofrece una cobertura amplia y resistente a la intemperie.

¿tesla utiliza radar o LiDAR?

Ver respuesta
Tesla is the notable holdout. Most automakers building robotaxi and ADAS stacks budget for LiDAR, but Tesla dropped radar in 2021 and runs a camera-only “Tesla Vision” approach for driver assistance. Industrial safety is a different problem: machine-guarding standards expect an active sensor with predictable geometry, so a certified LiDAR scanner stays the reference for person-detection, not cameras.

¿por qué LiDAR cuesta más que el radar?

Ver respuesta
Además de una representación precisa y milimétrica de los objetos en la nube de puntos, un escáner LIDAR de alta resolución y bien ubicado tiene tal precisión angular que puede actuar como el principal sensor de detección de personas (aunque, al igual que otras cámaras y radares, tienen limitaciones climáticas). Requieren una precisión óptica y mecánica mucho mayor en el hardware en comparación con los transceptores de radar menos costosos. Sin embargo, un LIDAR de alta resolución a veces puede reemplazar muchos radares, lo que reduce el costo general del sistema instalado.

¿qué certificaciones importan para los sensores de seguridad LiDAR industriales?

Ver respuesta
For industrial object detection, three safety standards come to mind. IEC 61496 specifies the electro-sensitive protection equipment; Type 3 applies to many mobile AGV cases while Type 4 is required for higher risk fixed guarding; IEC 60825-1 Class 1 certifies the laser as safe to the eyes without eye protection, and ISO 3691-4:2023 (the current edition, superseding the 2020 version) describes the minimum required performance levels for a driverless industrial truck’s safety system to detect people. These combined standards demonstrate exactly what safety performance required of the sensor to perform the detection of a human and put the machine into safe state. Be sure your certificate is for the right sensor part number and version. See QJKH’s line of industrial LiDAR sensors for certified options.

Not sure which sensor fits your line?

Match the field of view, accuracy, range and environmental conditions to your application with our LiDAR sensor selector — or talk through an all-radar, all-LiDAR, or fused obstacle-detection layout directly with our engineers. QJKH supports LiDAR, radar, ultrasonic and infrared lines, so the recommendation follows the duty cycle on your floor, not a single product family.

Use the LiDAR Sensor Selector →

Acerca de este análisis

The accuracy, range and field-of-view figures in this lidar vs radar comparison come from QJKH’s published specifications across our LiDAR, radar, ultrasonic and infrared product lines, plus field results from AGV, gantry-crane and cobot deployments. Where data is open-market (unit pricing, market forecasts) we say so and qualify it. Reviewed by the QJKH technical team.