voyager live camera

• Object Information
• Planetarium

Voyager 1 live position and data

This page shows Voyager 1 location and other relevant astronomical data in real time. The celestial coordinates, magnitude, distances and speed are updated in real time and are computed using high quality data sets provided by the JPL Horizons ephemeris service (see acknowledgements for details). The sky map shown in the background represents a rectangular portion of the sky 60x40 arcminutes wide. By comparison the diameter of the full Moon is about 30 arcmins, so the full horizontal extent of the map is approximately 2 full Moons wide. Depending on the device you are using, the map can be dragged horizondally or vertically using the mouse or touchscreen. The deep sky image in the background is provided by the Digitized Sky Survey ( acknowledgements ).

Current close conjunctions

List of bright objects (stars brighter than magnitude 9.0 and galaxies brighter than magmitude 14.0) close to Voyager 1 (less than 1.5 degrees):

Additional resources

• 15 Days Ephemerides
• Interactive Sky Map (Planetarium)
• Rise & Set Times
• Distance from Earth

Astronomy databases

• The Digitized Sky Survey, a photographic survey of the whole sky created using images from different telescopes, including the Oschin Schmidt Telescope on Palomar Mountain
• The Hipparcos Star Catalogue, containing more than 100.000 bright stars
• The PGC 2003 Catalogue, containing information about 1 million galaxies
• The GSC 2.3 Catalogue, containing information about more than 2 billion stars and galaxies

Voyager 1 and 2: The Interstellar Mission

An image of Neptune taken by the Voyager 2 spacecraft. Image credit: NASA

NASA has beautiful photos of every planet in our solar system. We even have images of faraway Neptune , as you can see in the photo above.

Neptune is much too distant for an astronaut to travel there with a camera. So, how do we have pictures from distant locations in our solar system? Our photographers were two spacecraft, called Voyager 1 and Voyager 2!

An artist’s rendering of one of the Voyager spacecraft. Image credit: NASA

The Voyager 1 and 2 spacecraft launched from Earth in 1977. Their mission was to explore Jupiter and Saturn —and beyond to the outer planets of our solar system. This was a big task. No human-made object had ever attempted a journey like that before.

The two spacecraft took tens of thousands of pictures of Jupiter and Saturn and their moons. The pictures from Voyager 1 and 2 allowed us to see lots of things for the first time. For example, they captured detailed photos of Jupiter's clouds and storms, and the structure of Saturn's rings .

Image of storms on Jupiter taken by the Voyager 1 spacecraft. Image credit: NASA

Voyager 1 and 2 also discovered active volcanoes on Jupiter's moon Io , and much more. Voyager 2 also took pictures of Uranus and Neptune. Together, the Voyager missions discovered 22 moons.

Since then, these spacecraft have continued to travel farther away from us. Voyager 1 and 2 are now so far away that they are in interstellar space —the region between the stars. No other spacecraft have ever flown this far away.

Where will Voyager go next?

Watch this video to find out what's beyond our solar system!

Both spacecraft are still sending information back to Earth. This data will help us learn about conditions in the distant solar system and interstellar space.

The Voyagers have enough fuel and power to operate until 2025 and beyond. Sometime after this they will not be able to communicate with Earth anymore. Unless something stops them, they will continue to travel on and on, passing other stars after many thousands of years.

Each Voyager spacecraft also carries a message. Both spacecraft carry a golden record with scenes and sounds from Earth. The records also contain music and greetings in different languages. So, if intelligent life ever find these spacecraft, they may learn something about Earth and us as well!

A photo of the golden record that was sent into space on both Voyager 1 and Voyager 2. Image credit: NASA/JPL-Caltech

More about our universe!

Where does interstellar space begin?

Searching for other planets like ours

Play Galactic Explorer!

If you liked this, you may like:

Call: 1-808-214-9444

Prince Resort Ocean Front

JW Marriott Marco Island Beach Resort

Inside NASA's 5-month fight to save the Voyager 1 mission in interstellar space

After working for five months to re-establish communication with the farthest-flung human-made object in existence, NASA announced this week that the Voyager 1 probe had finally phoned home.

For the engineers and scientists who work on NASA’s longest-operating mission in space, it was a moment of joy and intense relief.

“That Saturday morning, we all came in, we’re sitting around boxes of doughnuts and waiting for the data to come back from Voyager,” said Linda Spilker, the project scientist for the Voyager 1 mission at NASA’s Jet Propulsion Laboratory in Pasadena, California. “We knew exactly what time it was going to happen, and it got really quiet and everybody just sat there and they’re looking at the screen.”

When at long last the spacecraft returned the agency’s call, Spilker said the room erupted in celebration.

“There were cheers, people raising their hands,” she said. “And a sense of relief, too — that OK, after all this hard work and going from barely being able to have a signal coming from Voyager to being in communication again, that was a tremendous relief and a great feeling.”

The problem with Voyager 1 was first detected in November . At the time, NASA said it was still in contact with the spacecraft and could see that it was receiving signals from Earth. But what was being relayed back to mission controllers — including science data and information about the health of the probe and its various systems — was garbled and unreadable.

That kicked off a monthslong push to identify what had gone wrong and try to save the Voyager 1 mission.

Spilker said she and her colleagues stayed hopeful and optimistic, but the team faced enormous challenges. For one, engineers were trying to troubleshoot a spacecraft traveling in interstellar space , more than 15 billion miles away — the ultimate long-distance call.

“With Voyager 1, it takes 22 1/2 hours to get the signal up and 22 1/2 hours to get the signal back, so we’d get the commands ready, send them up, and then like two days later, you’d get the answer if it had worked or not,” Spilker said.

The team eventually determined that the issue stemmed from one of the spacecraft’s three onboard computers. Spilker said a hardware failure, perhaps as a result of age or because it was hit by radiation, likely messed up a small section of code in the memory of the computer. The glitch meant Voyager 1 was unable to send coherent updates about its health and science observations.

NASA engineers determined that they would not be able to repair the chip where the mangled software is stored. And the bad code was also too large for Voyager 1's computer to store both it and any newly uploaded instructions. Because the technology aboard Voyager 1 dates back to the 1960s and 1970s, the computer’s memory pales in comparison to any modern smartphone. Spilker said it’s roughly equivalent to the amount of memory in an electronic car key.

The team found a workaround, however: They could divide up the code into smaller parts and store them in different areas of the computer’s memory. Then, they could reprogram the section that needed fixing while ensuring that the entire system still worked cohesively.

That was a feat, because the longevity of the Voyager mission means there are no working test beds or simulators here on Earth to test the new bits of code before they are sent to the spacecraft.

“There were three different people looking through line by line of the patch of the code we were going to send up, looking for anything that they had missed,” Spilker said. “And so it was sort of an eyes-only check of the software that we sent up.”

The hard work paid off.

NASA reported the happy development Monday, writing in a post on X : “Sounding a little more like yourself, #Voyager1.” The spacecraft’s own social media account responded , saying, “Hi, it’s me.”

So far, the team has determined that Voyager 1 is healthy and operating normally. Spilker said the probe’s scientific instruments are on and appear to be working, but it will take some time for Voyager 1 to resume sending back science data.

Voyager 1 and its twin, the Voyager 2 probe, each launched in 1977 on missions to study the outer solar system. As it sped through the cosmos, Voyager 1 flew by Jupiter and Saturn, studying the planets’ moons up close and snapping images along the way.

Voyager 2, which is 12.6 billion miles away, had close encounters with Jupiter, Saturn, Uranus and Neptune and continues to operate as normal.

In 2012, Voyager 1 ventured beyond the solar system , becoming the first human-made object to enter interstellar space, or the space between stars. Voyager 2 followed suit in 2018.

Spilker, who first began working on the Voyager missions when she graduated college in 1977, said the missions could last into the 2030s. Eventually, though, the probes will run out of power or their components will simply be too old to continue operating.

Spilker said it will be tough to finally close out the missions someday, but Voyager 1 and 2 will live on as “our silent ambassadors.”

Both probes carry time capsules with them — messages on gold-plated copper disks that are collectively known as The Golden Record . The disks contain images and sounds that represent life on Earth and humanity’s culture, including snippets of music, animal sounds, laughter and recorded greetings in different languages. The idea is for the probes to carry the messages until they are possibly found by spacefarers in the distant future.

“Maybe in 40,000 years or so, they will be getting relatively close to another star,” Spilker said, “and they could be found at that point.”

Denise Chow is a reporter for NBC News Science focused on general science and climate change.

Interstellar Mission

The Voyager 2 spacecraft, which has been in operation since 1977 and is the only spacecraft to have ever visited Uranus and Neptune, has made its way to interstellar space, where its twin spacecraft, Voyager 1, has resided since August 2012.

Mission Statistics

Launch Date

Aug. 20, 1977

About the mission

The Voyager 2 spacecraft, which has been in operation since 1977 and is the only spacecraft to have ever visited Uranus and Neptune, has made its way to interstellar space, where its twin spacecraft, Voyager 1, has resided since August 2012. During its travels through the outer solar system, Voyager 2 visited all four gas giant planets, and also discovered and photographed many of the planets' moons.

The spacecraft's flyby of Neptune in 1989 set it on a course below the elliptic plane that eventually took it to interstellar space on November 5, 2018. In 1998, engineers switched off the spacecraft's nonessential instruments to conserve power. Data from at least some of the six instruments still in operation should be received until at least 2025.

Instruments

• Imaging system
• Infrared interferometer spectrometer
• Ultraviolet spectrometer
• Triaxial fluxgate magnetometer
• Plasma spectrometer
• Low-energy charged particles detectors
• Cosmic Ray System (CRS)
• Photopolarimeter System (PPS)
• Plasma Wave System (PWS)

Mission Highlights

Nov. 5, 2018

Interactive 3D model of Voyager 2.View the full interactive experience at Eyes on the Solar System .

LOG IN TO MAKE A PASS RESERVATION

View account, livestream jellies, help us name our jellies.

What’s in a name? Guests that name a Moon Jelly receive an official certificate, and support goes toward Georgia Aquarium and our preservation efforts.

Tour the Virtual World of the Tropics

Explore a flurry of activity and color as you learn about the 90+ species of fish and 200 species of coral with the Tropical Diver virtual tour.

Brush up on Your Jelly Facts

Learn all about these fascinating, other-worldly creatures and the beautiful tropical waters they inhabit.

Dive Into More Aquarium Experiences

Set sail on a virtual field trip.

Georgia Aquarium offers educational virtual programs for grades K-12. Educators can immerse their classrooms in the Aquarium today.

Color the Oceans With This Free Download

Download the Aquarium coloring book and watch the pages swim with life. Perfect for all ages.

Bring Home a Glowing Jelly Lamp

Enjoy the mesmerizing dance of the jellies right at home. Each lamp’s LEDs cast a soothing glow over two “swimming” synthetic jellyfish.

Support Georgia Aquarium

Please consider supporting the Aquarium today so we can continue delivering amazing animal experiences for everyone.

More Webcams

Experience More Wonders

Need a moment of zen or just a daily dose of cuteness? See what our animals are up to in real-time, from anywhere when you live stream Georgia Aquarium galleries.

Livestream Sharks! Predators of the Deep®

Sit back and watch as sharks swim through the shadowy depths in one of the largest and most dynamic shark exhibits in North America.

Livestream Southern Sea Otters

Check in on our sea otters as they dip and dive in their rocky, cold water alcove at Georgia Aquarium.

Livestream Beluga Whales

Watch these playful beauties in the frigid depths as you dive beneath the waves of the Cold Water Quest Gallery.

Livestream California Sea Lions

If you can’t make it to the Aquarium or the Pacific Coast, check out our California sea lion webcam to enjoy some of Georgia Aquarium’s most charismatic characters.

Livestream the Indo-Pacific Barrier Reef

Peer beneath the surface into one of the largest living reef exhibits in the world, home to thousands of colorful fish, coral, and curious garden eels.

NASA's Voyager 1 spacecraft finally phones home after 5 months of no contact

On Saturday, April 5, Voyager 1 finally "phoned home" and updated its NASA operating team about its health.

NASA's interstellar explorer Voyager 1 is finally communicating with ground control in an understandable way again. On Saturday (April 20), Voyager 1 updated ground control about its health status for the first time in 5 months. While the Voyager 1 spacecraft still isn't sending valid science data back to Earth, it is now returning usable information about the health and operating status of its onboard engineering systems. 

Thirty-five years after its launch in 1977, Voyager 1 became the first human-made object to leave the solar system and enter interstellar space . It was followed out of our cosmic quarters by its space-faring sibling, Voyager 2 , six years later in 2018. Voyager 2, thankfully, is still operational and communicating well with Earth. 

The two spacecraft remain the only human-made objects exploring space beyond the influence of the sun. However, on Nov. 14, 2023, after 11 years of exploring interstellar space and while sitting a staggering 15 billion miles (24 billion kilometers) from Earth, Voyager 1's binary code — computer language composed of 0s and 1s that it uses to communicate with its flight team at NASA — stopped making sense.

Related: We finally know why NASA's Voyager 1 spacecraft stopped communicating — scientists are working on a fix

In March, NASA's Voyager 1 operating team sent a digital "poke" to the spacecraft, prompting its flight data subsystem (FDS) to send a full memory readout back home.

This memory dump revealed to scientists and engineers that the "glitch" is the result of a corrupted code contained on a single chip representing around 3% of the FDS memory. The loss of this code rendered Voyager 1's science and engineering data unusable.

The NASA team can't physically repair or replace this chip, of course, but what they can do is remotely place the affected code elsewhere in the FDS memory. Though no single section of the memory is large enough to hold this code entirely, the team can slice it into sections and store these chunks separately. To do this, they will also have to adjust the relevant storage sections to ensure the addition of this corrupted code won't cause those areas to stop operating individually, or working together as a whole. In addition to this, NASA staff will also have to ensure any references to the corrupted code's location are updated.

Get the Space.com Newsletter

Breaking space news, the latest updates on rocket launches, skywatching events and more!

—  Voyager 2: An iconic spacecraft that's still exploring 45 years on

—  NASA's interstellar Voyager probes get software updates beamed from 12 billion miles away

—  NASA Voyager 2 spacecraft extends its interstellar science mission for 3 more years

On April 18, 2024, the team began sending the code to its new location in the FDS memory. This was a painstaking process, as a radio signal takes 22.5 hours to traverse the distance between Earth and Voyager 1, and it then takes another 22.5 hours to get a signal back from the craft. 

By Saturday (April 20), however, the team confirmed their modification had worked. For the first time in five months, the scientists were able to communicate with Voyager 1 and check its health. Over the next few weeks, the team will work on adjusting the rest of the FDS software and aim to recover the regions of the system that are responsible for packaging and returning vital science data from beyond the limits of the solar system.

Join our Space Forums to keep talking space on the latest missions, night sky and more! And if you have a news tip, correction or comment, let us know at: [email protected].

Robert Lea is a science journalist in the U.K. whose articles have been published in Physics World, New Scientist, Astronomy Magazine, All About Space, Newsweek and ZME Science. He also writes about science communication for Elsevier and the European Journal of Physics. Rob holds a bachelor of science degree in physics and astronomy from the U.K.’s Open University. Follow him on Twitter @sciencef1rst.

Mars exploration, new rockets and more: Interview with ESA chief Josef Aschbacher

SpaceX launches 23 Starlink satellites from Florida (video)

'Traffic jams' in the hearts of galaxies can force black holes to collide

• Robb62 'V'ger must contact the creator. Reply
• Holy HannaH! Couldn't help but think that "repair" sounded extremely similar to the mechanics of DNA and the evolution of life. Reply
• Torbjorn Larsson *Applause* indeed, thanks to the Voyager teams for the hard work! Reply
• SpaceSpinner I notice that the article says that it has been in space for 35 years. Either I have gone back in time 10 years, or their AI is off by 10 years. V-*ger has been captured! Reply

Admin said: On Saturday, April 5, Voyager 1 finally "phoned home" and updated its NASA operating team about its health. The interstellar explorer is back in touch after five months of sending back nonsense data. NASA's Voyager 1 spacecraft finally phones home after 5 months of no contact : Read more

evw said: I'm incredibly grateful for the persistence and dedication of the Voyagers' teams and for the amazing accomplishments that have kept these two spacecrafts operational so many years beyond their expected lifetimes. V-1 was launched when I was 25 years young; I was nearly delirious with joy. Exploring the physical universe captivated my attention while I was in elementary school and has kept me mesmerized since. I'm very emotional writing this note, thinking about what amounts to a miracle of technology and longevity in my eyes. BRAVO!!! THANK YOU EVERYONE PAST & PRESENT!!!

• EBairead I presume it's Fortran. Well done all. Reply

SpaceSpinner said: I notice that the article says that it has been in space for 35 years. Either I have gone back in time 10 years, or their AI is off by 10 years. V-*ger has been captured!

EBairead said: I presume it's Fortran. Well done all.

• View All 13 Comments

Most Popular

• 2 Highly precise atomic clocks could soon get even better. Here's how
• 3 Mars exploration, new rockets and more: Interview with ESA chief Josef Aschbacher
• 4 Everything we know about James Gunn's Superman
• 5 Sneak peek: Browncoats grab victory in Boom! Studios' upcoming 'Firefly: 'Verses' comic (exclusive)

NASA hears from Voyager 1, the most distant spacecraft from Earth, after months of quiet

NASA has finally heard back from Voyager 1 in a way that makes sense

CAPE CANAVERAL, Fla. -- NASA has finally heard back from Voyager 1 again in a way that makes sense.

The most distant spacecraft from Earth stopped sending back understandable data last November. Flight controllers traced the blank communication to a bad computer chip and rearranged the spacecraft’s coding to work around the trouble.

NASA’s Jet Propulsion Laboratory in Southern California declared success after receiving good engineering updates late last week. The team is still working to restore transmission of the science data.

It takes 22 1/2 hours to send a signal to Voyager 1, more than 15 billion miles (24 billion kilometers) away in interstellar space. The signal travel time is double that for a round trip.

Contact was never lost, rather it was like making a phone call where you can’t hear the person on the other end, a JPL spokeswoman said Tuesday.

Launched in 1977 to study Jupiter and Saturn, Voyager 1 has been exploring interstellar space — the space between star systems — since 2012. Its twin, Voyager 2, is 12.6 billion miles (20 billion kilometers) away and still working fine.

The Associated Press Health and Science Department receives support from the Howard Hughes Medical Institute’s Science and Educational Media Group. The AP is solely responsible for all content.

Top Stories

5 killed, including baby, as tornadoes slam the heartland

• Apr 28, 8:47 PM

College protests live updates: Columbia asks protesters to voluntarily disperse

• 42 minutes ago

Severe thunderstorm watch in effect in parts of Texas, Louisiana

• 3 hours ago

Brittney Griner reflects on moment she was detained in Russia in '20/20' special

Trump and DeSantis meet to 'bury the hatchet' after 2024 primary fight: Sources

• Apr 28, 5:06 PM

ABC News Live

24/7 coverage of breaking news and live events

• The Contents
• The Making of
• Where Are They Now
• Frequently Asked Questions
• Q & A with Ed Stone

golden record

Where are they now.

• frequently asked questions
• Q&A with Ed Stone

mission  /  spacecraft  /  instruments

Imaging science subsystem (iss).

The ISS is a modified version of the slow scan vidicon camera designs that were used in the earlier Mariner flights. The ISS consists of two television-type cameras, each with 8 filters in a commandable Filter Wheel mounted in front of the vidicons. One has a low resolution 200 mm wide-angle lens with an aperture of f/3, while the other uses a higher resolution 1500 mm narrow-angle f/8.5 lens.

Unlike the other onboard instruments, operation of the cameras is not autonomous, but is controlled by an imaging parameter table residing in one of the spacecraft computers, the Flight Data Subsystem (FDS).

Imaging Science Subsystem Objective

• Observe and characterize the circulation of the planetary atmosphere, provide limits on atmospheric composition, and determine the wind velocities in the regions observed.
• Map the radial and azimuthal distribution of material in the ring plane; search for new rings.
• Obtain global multi-spectral coverage of all satellites; establish rotation rates and spin axis orientations, study the surface morphology of Triton at spatial resolutions less than 2 km; search for undiscovered satellites.
• Provide support images to assist other onboard investigations in their data reduction.

Wireless Camera Systems

Outfit your vehicle with a full observation system without running wiring. Our patented WiSight Technology allows the camera to transmit to a wireless Voyager monitor up to 60 feet away in real time, even at freeway speeds.

System includes WiSight receiver (WVRX1AP) and wireless camera (WVCMS130AP).

• Wireless camera system includes one WVOM541AP monitor, one WVCMS130AP rear camera, one suction cup monitor mount, and 12 volt DC accessory plug

• WiSight transmitter with protective housing
• WiSight digital signal transmits through and around objects up to 60 feet away
• Compatible with any Voyager wired camera for instant WiSight signal capability
• Single camera input
• 2-wire power
• Universal installation with AMPS mounting provisions
• Compatible with any Voyager wired monitor for instant WiSight signal capability
• Adjustable antenna
• LED power indicator

• Power harness for WVOM541AP monitor
• CA2-to-monitor power cable

© Copyright Voyager. All Rights Reserved. | Privacy Policy

Receiver Features

Camera features.

• Rear wireless camera with WiSight technology
• High performance color optics
• 1/3-inch CMOS sensor
• Mirror image orientation
• 380 TV line resolution
• 0 Lux sensitivity
• 122° diagonal, 91° horizontal, 65° vertical viewing angles
• LEDs for low light assistance

Wireless camera system includes one WVOM541AP monitor, one WVCMS130AP rear camera, one suction cup monitor mount, and 12 volt DC accessory plug.

Monitor Features

• Supports up to 4 wireless cameras 
• Auto-Pairing button instantly pairs (up to) 4 wireless cameras
• 5.6-inch color TFT LCD panel display with LED backlight
• Built-in speaker
• Suction cup mount and 12 volt DC plug included
• 12 volt DC power
• NTSC video signal compatible
• 960 W x 234 H screen resolution
• 100° H and 80° V viewing angles
• 500 nit brightness
• 250:1 contrast ratio
• 4:3 aspect ratio

Wired Systems

Wireless systems, sensor systems, accessories.

• Blind spot detection system
• Two side-body mount sensors
• Radar based waterproof sensors
• Provides warning lights while sensor detects vehicle in blind zone with audible beep warning while turn signal is activated
• 1T2R antenna technology detects the vehicle in blind zone from both directions (vehicle approaching or passing the target vehicle)
• Self diagnostic mode
• Rear Cross Traffic Alert (RCTA) System – the sensors monitor the target object in the monitored area. System will give out a beep alert for potential risk while vehicle is in reverse mode
• Proximity detection/warning system with four bumper/body-mount sensors
• Four detection zones with progressive beep tone
• Audio speaker/buzzer with High/Low/Off volume settings
• Plastic bumper installation
• Built-in sensor isolators for metal bumper application
• Sensor sensitivity adjustment with rear step avoidance option
• No calibration, no on-screen display
• Proximity detection/warning system with four bumper/body mount sensors
• Seamlessly integrates into any Voyager rear camera system
• Easy-to-read, on-screen display overlays that do not obstruct camera view
• Audio fed through monitor speaker
• Engineered for commercial vehicle environments
• Compatible with JENSEN® touchscreen stereo (with camera input)
• Compatible cameras: VCAHD140i, VCMS20, VCMS20B, VCMS17, VCMS17B

The WVSXS70 single-camera system includes a 7-inch wireless LCD monitor, wireless rear camera, 12-volt accessory plug, suction cup monitor mount, non-corrosive camera mounting bracket, and stainless steel hardware.

WiSight® 2.0 technology digitally locks the camera to the monitor and blocks all outside signals.  This eliminates interference and noise typical of analog wireless systems and delivers a sharp, vivid picture of the vehicle’s surroundings to the monitor.

Monitor (WVSXM70) Features

• Supports up to four (4) wireless cameras simultaneously
• Auto-Pairing capability allows the monitor to be paired with any of the wireless cameras with the touch of a button
• Strong signal transmits through and around objects up to 60 feet away
• Bright 7” display
• Supports normal and mirrored camera image
• Supports single, split, and quad view camera views
• Suction cup mount and 12V DC plug included

Camera (WVSXC150) Features

• 12VDC power
• High-performance color optics
• CMOS sensor technology
• IR LED Low-light assist
• Integrated microphone
• Wide viewing angle
• Non-corrosive camera mounting bracket
• Stainless steel hardware

The WVSXP43 single-camera system includes a 4.3-inch wireless LCD monitor, one wireless rear camera, a 12-volt power cord, and a suction cup mount.

Monitor (WVSXM43) Features

• Bright 4.3” display
• Displays graphic overlay that shows real-time distance from objects
• CMOS Sensor technology
• Displays graphic overlay that shows the real-time distance from objects

Camera (WVSXC160) Features

• Mobile digital video recorder
• 8-channel real time video monitoring and recording
• Compatible with any Voyager camera
• Compatible with AHD cameras
• Continuous recording as well as event recording (Sensor, speed, ignition off)
• GPS support for map syncing with Google (GPS antenna included)
• Multitasking function supports live camera monitoring, recording, play, and backing up footage
• 3 wire power system
• 2.5” 256GB SATA SSD Device for continuous recording
• 32GB SD Card for event recording (impact & alarm)
• SSD device lock key
• LED diagnostic indicators
• 3-axis G-sensor
• IR remote control
• Backup USB2 .0
• Multi-use camera
• Available in black (VCMS155B) or white (VCMS155)
• 1/4-inch CMOS sensor
• Electronic Automatic iris
• Selectable mirror or normal image orientation
• 420 TV line resolution
• 140° diagonal, 112° horizontal, 80° vertical angle of view
• 10 LEDs for low light assistance
• Aluminum housing
• Corrosion resistant
• Forward facing camera
• Electronic automatic iris
• 320 TV line resolution
• 1.0 Lux sensitivity
• 131° diagonal, 108° horizontal, 78° vertical angle of view
• Plastic molded housing

VCAHD140ICV

• Surface mount multi-use camera
• Analog high definition
• 1200 TV line resolution
• 146° diagonal, 129° horizontal, 86° vertical angle of view
• IR low light assistance
• Impact-resistant aluminum housing
• Surface mount light bar with camera
• Single pass wire entry installation
• Automotive exterior lighting-grade polycarbonate
• FMVSS108 compliant
• Available in black (VCMS202B) or white (VCMS202)
• 600 TV line resolution
• 145° diagonal, 109° horizontal, 93° vertical angle of view
• 19 LEDs for low light assistance
• Side body camera
• Available in left and right orientations in chrome (VCMS12LCM, VCMS12RCM), gray primer (VCMS12LGP, VCMS12RGP), and white (VCMS12LWT, VCMS12RWT)
• Zinc alloy housing and injected plastic body
• Available in left and right orientations in chrome (VCMS50LCM, VCMS50RCM), gray primer (VCMS50LGP, VCMS50RGP), and white (VCMS50LWT, VCMS50RWT)
• Available in variable orientation in black (VCMS50TBLK)
• Normal image orientation
• .5 Lux sensitivity
• 78° diagonal, 65° horizontal, 49° vertical angle of view
• Aluminum housing and injected plastic body
• Rear mount camera
• Mirrored image orientation
• 125° diagonal, 85° horizontal, 67° vertical angle of view
• 12 LEDs for IR low light assistance
• Supports 3 cameras with manual or triggered source selection
• Rearview mirror replacement monitor
• 7-inch wide format color TFT LCD display
• On-Screen Display (OSD) for AV source, picture adjustment, and volume control
• Manual and auto-dimming feature with screen saver mode
• Mechanical buttons with white backlit illumination
• Non-volatile memory
• NTSC and PAL video signal compatible
• 800 W x 450 H screen resolution
• 70° top, 50° bottom, 70° left, 70° right viewing angles
• 400 nit brightness
• 500:1 contrast ratio
• Analog 16:9 aspect ratio
• Supports 4 cameras with 6 triggers including Single image, Split-screen, and QuadView display modes
• 7-inch digital wide format color TFT LCD display
• DC auto source for switching triggers (turn signal compatible)
• Manual day/night display brightness controls
• Backlit control buttons
• Heady duty waterproof construction
• Rated and tested to withstand 4G continuous vibration
• AMPS mounting provisions
• Removable sun visor included
• 60° top, 70° bottom, 75° left, 75° right viewing angles
• 16:9 aspect ratio
• Supports three wired cameras with manual (push button) or automatic (trigger) source selection
• 7-inch wide format color LCD panel display with white LED backlight
• Day/night brightness modes
• Rubber keypad with white backlit illumination
• Auto-power on (stand by)
• Multiple mounting options (AMPS) compatible
• 480 W x 234 H screen resolution
• 55° top, 65° bottom, 70° left, 70° right viewing angles
• 450 nit brightness
• 400:1 contrast ratio
• 4.3-inch color TFT LCD panel display with LED backlight
• Anti-glare and anti-scratch protective lens
• Display graphic overlays show distance from objects in real-time
• Heavy duty waterproof metal housing
• Menu-selectable auto power on/off
• AMP mounting pattern
• 480 W x 272 H screen resolution
• 70° top, 70° bottom, 60° left, 60° right viewing angles

The WVSXP70 single-camera system includes a 7-inch wireless LCD monitor, wireless rear camera, 12-volt accessory plug, and suction cup monitor mount.

• Auto-calibrate the images from four cameras to create a 360- degree image
• Walk-in Van 354” L x 118” W
• Bus 551” L x 118” W
• Heavy Duty Vehicles 236” L x 354” W
• Semi Trailer 630” L x 118” W
• Left/Right/Rear trigger function to switch between viewing angles
• Update software and vehicle image via USB
• 1/3-inch high performance color optic cameras
• Waterproof housing
• Plastic camera housing with stainless steel mounting bracket and aluminum
• Powder coated camera cover

VOS74MMCL3B

Wired camera system includes one VOM74MM mirror monitor, one VCMS140IB rear camera, one VCMS50RGP right side camera, one VCMS50LGP left side camera, and proprietary cabling.

Rear Camera Features

• 400 TV line resolution
• 150° diagonal, 120° horizontal, 90° vertical angle of view

Side Camera Features

Vos74mmcl2b.

Wired camera system includes one VOM74MM mirror monitor, one VCMS140IB rear camera, one VCMS50RGP right side camera, and proprietary cabling.

VOS74MMCL1B

Wired camera system includes one VOM74MM mirror monitor, one VCMS140IB rear camera, and proprietary cabling.

VOS719WPLD3B

Wired camera system includes one VOM719WP monitor, one VCMS17B rear camera, one VCMS50RGP right side camera, one VCMS50LGP left side camera, one VOSHD4MNT monitor mount, and proprietary cabling.

VOS719WPLD2B

Wired camera system includes one VOM719WP monitor, one VCMS17B rear camera, one VCMS50RGP right side camera, one VOSHD4MNT monitor mount, and proprietary cabling.

VOS719WPLD1B

Wired camera system includes one VOM719WP monitor, one VCMS17B rear camera, one VOSHD4MNT monitor mount, and proprietary cabling.