Difference between revisions of "Understanding HyperSync and High Speed Sync"

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{{recommended reading|HyperSync|}}
 
{{recommended reading|HyperSync|}}
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'''This section describes how HyperSync and High Speed Sync work at a basic level. Read the [[HyperSync Setup]] page for more detailed information on how to adjust HyperSync for your configuration.'''
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When shooting with flash, there are different methods of synchronizing the flash with a camera’s shutter. These methods depend primarily on the shutter speed and flashes you use.
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While the flash appears instantaneous to our eyes, it actually has duration and variance. These are important to the camera’s sensor, especially at faster shutter speeds.
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At shutter speeds slower than X-sync, usually 1/200 or slower, a normal flash of light is all that is required; the first curtain of the shutter opens, the flash fires for its flash duration, and the second curtain of the shutter closes.
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At shutter speeds faster than X-sync (usually 1/250 through 1/8000) the time between the shutter’s first curtain opening and second curtain closing is not long enough for a normal flash of light to complete its duration. At the fastest shutter speeds, the shutter’s curtains are moving at the same time, exposing a moving slit of light across the sensor.  At these shutter speeds, other flash techniques must be used.
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High Speed Sync (HSS or Auto-FP sync) begins pulsing the flash before the first curtain opens and continues to pulse it until after the second curtain closes. From the camera’s perspective this pulsed light appears as continuous light during the exposure. HSS uses a lot of energy, however, which means there is less light available for the image, and is usually only available in lower powered Speedlites/Speedlights. Syncing up to 1/8000 is possible, but the flash must be very close to the subject.
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HyperSync uses a normal flash of light, which has much more energy in it compared to pulsed HSS. HyperSync also uses precision timing to align the flash’s duration and output curve with the moving shutter curtains. This allows more light in the image than HSS can provide, and works with higher powered flashes like studio flash packs and monolights. Different flash and camera combinations yield different shutter speed and light output performance, but most combinations will get worthwhile benefits using HyperSync.
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Other techniques, like the "HSS Hack" (with or without a manually dialed in delay), can sometimes get a normal flash of light from a studio pack into an exposure taken at faster shutter speeds, but these methods are less precise than HyperSync, lack automation, and are more limited to which camera and flash combinations yield usable results.
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=== What HyperSync results can I get with my camera and flash? ===
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Thankfully, we have done a lot of the work for you by sharing images that we have captured using as many combinations of camera and flash model as possible. Our examples are available below. Simply click on your camera and find the flash that you wish to use with HyperSync. There are countless combinations of flashes and cameras in the world, and we will add more cameras and flashes as time goes by. If you don't see your equipment, feel free to contact us directly: http://www.pocketwizard.com/contact/inquiry/
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{{C HATT}}
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'''''Read the [[HyperSync Setup]] page for more detailed information on how to adjust HyperSync.'''''
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{{Fast Page}}
 
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'''This section discusses HyperSync and High Speed Sync at a basic level.  Read the [[HyperSync]] section for more detailed information on how to adjust HyperSync for your configuration.'''
 
  
This page details how flashes function when triggered with HyperSync, High Speed Sync (or Auto FP), and at your camera's sync limit, or its x-sync speed. HyperSync and High Speed Sync/Auto-FP are not the same thing, and it's important to understand the differences as to how each method relates to your setup.
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{{Don't see your gear?}}
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== How Does a Flash Work? ==
 
== How Does a Flash Work? ==
  
  
A flash is designed to emit a very intense light for a short duration of time. This is done by filling a flashtube with xenon gas, and then using a charged capacitor to energize the xenon with a very high amount of electrical current. The peak has the highest amount of energy emitted (hence the name, "peak") but energy continues to be emitted at a decreasing rate so long as the xenon gas is energized.
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A flash is designed to emit a very intense light for a short duration of time. This is done by filling a flashtube with xenon gas, and then using a charged capacitor to energize the xenon with a very high amount of electrical current. This produces the light that flashes use to illuminate a scene. You can visualize a single flash event as “light over time,” plotted as a curve. The peak has the highest amount of energy emitted but energy continues to be emitted at a decreasing rate so long as the xenon gas is energized. This drop in energy (and therefore light output) creates the “tail” of the curve.  
  
  
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While appearing to be instantly turned on and instantly turned off again, a flashtube can be excited for anywhere from 1 microsecond to tens of milliseconds. Most consumer flashes usually average around 1 millisecond, with some being longer, and some being shorter.
 
While appearing to be instantly turned on and instantly turned off again, a flashtube can be excited for anywhere from 1 microsecond to tens of milliseconds. Most consumer flashes usually average around 1 millisecond, with some being longer, and some being shorter.
  
== X-Sync - Flash behavior with normal sync limits ==
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== How Does a Shutter Work? ==
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A camera’s shutter has two curtains that cover the sensor. When you press the shutter button, the first curtain moves, exposing the sensor. Next, the second curtain moves, finishing the exposure. Your first curtain opens all the way before the second curtain starts to move. This fully exposes the camera’s sensor. Your camera has a limit where it can fully open its shutter and capture a normal flash duration across the entire exposure all at once. This is your camera’s X-sync limit.
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[[File:X-SyncShutter.gif|center]]
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<center>A simulated shutter at X-sync</center>
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Shutter speeds above X-sync act differently. The first curtain begins to move downwards. Before they reach the bottom, the second curtain begins to move. This creates a moving slit.
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[[File:MediumShuttersAboveX-Sync.gif|center]]
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<center>A simulated shutter above X-sync]</center>
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The faster the shutter speed, the smaller the slit:
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[[File:FastestShuttersAboveX-Sync.gif|center]]
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<center>Faster shutter speeds have smaller slits</center>
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== X-sync - Flash behavior with normal sync limits ==
  
 
=== A flash directly connected to a camera ===
 
=== A flash directly connected to a camera ===
  
  
X-Sync is typically the fastest shutter speed at which your camera can trigger a flash. For most Canon cameras, this is 1/200th. For most Nikon cameras, this is 1/250th, except for a few exceptions like the D600.  
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Your camera has a limit where it can fully open its shutter and capture flash across the entire sensor all at once. This is your camera’s X-sync limit.
  
  
 
A camera triggering a flash at X-sync follows this timeline:
 
A camera triggering a flash at X-sync follows this timeline:
#The camera is triggered by the photographer.  Several milliseconds of Lag Time pass. The amount of lag time varies from camera to camera.
 
#The first shutter opens, exposing the digital sensor.  Some microseconds of time pass.  This shutter will stay open for the length of your selected shutter speed time (exposure time.)
 
#The camera triggers its PC terminal and the center sync pin on the hot shoe.
 
#The flash emits light for the its flash duration.  This can be any amount of time, up to a few milliseconds.
 
#The second curtain begins to move downwards across the sensor, closing the exposure "slit."
 
#The second shutter in the camera closes and both shutters reset.
 
  
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# The shutter button is pressed.
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#Several milliseconds of time pass. This is called lag time. The amount of lag time varies from camera to camera.
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#The first curtain moves from the top of the sensor to the bottom. The camera’s sensor is exposed.
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#Some microseconds of time pass. The camera triggers its PC terminal and the center sync pin on the hot shoe.
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#The flash emits light for its flash duration. The time this happens can be any amount of time up to a few milliseconds.
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#The second curtain moves from the top of the sensor to the bottom.
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#The second curtain in the camera closes and both curtains reset to the top of the sensor
  
<center><gallery perrow=2 widths=300px caption="Timing Sequence at X-Sync">
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<center><gallery perrow=2 widths=300px caption="Timing Sequence at X-sync">
 
File:X-sync_shutter_sequence.JPG|Shutter Sequence at X-sync
 
File:X-sync_shutter_sequence.JPG|Shutter Sequence at X-sync
 
File:5DMarkII_1.200.JPG|Ranger RX (S Head) at full power, 5D Mark II 1/200th f/22. This is a photo of a white wall to demonstrate no clipping or gradation.
 
File:5DMarkII_1.200.JPG|Ranger RX (S Head) at full power, 5D Mark II 1/200th f/22. This is a photo of a white wall to demonstrate no clipping or gradation.
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Shutter speeds above X-sync work differently.  A camera triggering a flash above X-sync follows this timeline:
  
Shutter speeds faster than X-Sync typically have the first and second shutters moving at the same time, or with no delay between the first shutter fully opening and the second shutter beginning to close. This does not work with normal flash triggering because the second shutter can be moving when the flash is generating light which yields a clipped exposure.
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#The shutter button is pressed.
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#Several milliseconds of time pass. This is called lag time. The amount of lag time varies from camera to camera.
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#The first curtain begins expose the sensor as it moves from top to bottom.
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#Before the first curtain reaches the bottom of the sensor, the second curtain begins to move. The space between the first and second curtain is a small slit that moves across the sensor. The faster your shutter speed, the smaller the slit becomes.
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#The first curtain reaches the bottom of the sensor.
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#The camera triggers its PC terminal and the center sync pin on the hot shoe. (Many cameras do not provide this sync output above X-sync.)
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#The flash emits light for its flash duration. The time this happens can be any amount of time up to a few milliseconds.
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#The moving slit is exposed to the flash.
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#The second curtain in the camera closes and both curtains reset to the top of the sensor
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When a camera connected directly to a flash via sync cable is used above X-sync the second curtain blocks part of the sensor from being exposed to light. This shows up as a black band, or clipping.
  
  
 
<center><gallery perrow=2 widths=300px caption="Timing Sequence at 1/8000th With a Sync Cord">
 
<center><gallery perrow=2 widths=300px caption="Timing Sequence at 1/8000th With a Sync Cord">
File:Non-hypersync_1.8000.JPG|Sync Cord Timing Sequence at 1/8000th
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File:Non-hypersync_1.8000.JPG|border|Sync Cord Timing Sequence at 1/8000th
 
File:IMG 4812.JPG|Ranger RX (S Head) at full power, 5D Mark II 1/8000th f/22. This photo shows a tiny sliver of white flash exposure at the top, while the rest of the sensor has been blocked by the second curtain.
 
File:IMG 4812.JPG|Ranger RX (S Head) at full power, 5D Mark II 1/8000th f/22. This photo shows a tiny sliver of white flash exposure at the top, while the rest of the sensor has been blocked by the second curtain.
 
</gallery></center>
 
</gallery></center>
  
  
If your flash has a very long duration, or your shutter is very slow moving, you can get clipping even at X-sync.
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The timing sequence has tighter tolerances at X-sync compared to slower speeds. This tighter tolerance and the radio processing delay moves the moment the sensor sees the flash. Since the second curtain has started to move a small bit, on a very small number of cameras you get shadowing or clipping in your exposure. Flashes with long durations can show clipping at X-sync. Cameras with slow shutters can show clipping at X-sync. To get rid of clipping, you may have to use a slower shutter speed.
  
=== A Flash Triggered Remotely by a Typical Radio Trigger  ===
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The PlusX, Plus III, or MultiMAX have a mode to reduce this delay, called [[Transmit Only]]. A receiving Plus III can use [[FAST mode]] to reduce processing time.
[[File:5D.1.200.jpg|thumb|Standard radio triggers can introduce bottom-frame shutter shadowing, or "clipping" in your image even at your camera's sync limit. 5D Classic 1/200th, Plus II radios]]
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== [[High Speed Sync]] ==
  
Typical radio triggers right off the center x-sync pin of your camera. Adding a typical radio trigger to the above timeline adds additional microseconds between steps 3 and 4. This additional delay moves the flash triggering moment towards the time when the second shutter will be moving. If your flash has a very long duration, or your shutter is very slow moving, you can get clipping when using a standard radio slave even at X-sync. You may have to use a slower shutter speed.
 
  
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High Speed Sync (HSS) is a Canon technique for syncing flash above X-sync. HSS is called Auto-FP in the Nikon system. This is a speedlight-only technique that pulses light above X-sync. This appears to the camera as a continuous light at faster shutter speeds.
  
Users of the 5D series of cameras have especially noticed this, as evidenced by the example to the right.
 
  
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A camera and flash using HSS/Auto-FP follow this timeline:
  
Users of the [[PlusX]], [[Plus III]], or [[MultiMAX]] can select [[Transmit Only]] on their transmitter to use a smaller delay, as well as using [[Plus_III#Modes_of_Operation|Receive Only]] on a receiving [[Plus III]] to have the fastest transmission possible.
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#The shutter button is pressed.
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#Several milliseconds of time pass. This is called lag time. The amount of lag time varies from camera to camera.
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#The speedlight begins to pulse light just before the first curtain begins to move.
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#The first curtain begins to move from the top of the sensor to the bottom.
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#The camera’s sensor is exposed.
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#Before the first curtain reaches the bottom of the sensor, the second curtain begins to move. The space between the first and second curtain is a small slit that moves across the sensor. The faster your shutter speed, the smaller the slit becomes.
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#The speedlight continues to pulse.
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#The first curtain reaches the bottom of the sensor.
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#The second curtain in the camera closes and both curtains reset to the top of the sensor.
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#The speedlight stops pulsing.
  
== [[High Speed Sync]] ==
 
 
High Speed Sync (HSS), also known as Auto FP Sync, is the camera manufacturer's speedlight-only technique allows for triggering at shutter speeds faster than X-Sync. "FP" stands for "Focal Plane." When the first shutter starts to open, it is exposing the digital sensor, which is the Focal Plane. FP Sync means triggering the flash just before the focal plane is exposed rather than waiting until shutter is fully open.
 
  
  
 
[[File:FP_Sync_Optical.jpg|400px|center|frameless|HSS Pulses at various shutter speeds within the Canon Optical communications system]]
 
[[File:FP_Sync_Optical.jpg|400px|center|frameless|HSS Pulses at various shutter speeds within the Canon Optical communications system]]
  
<center>HSS Pulses at various shutter speeds within the Canon Optical communications system</center>
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<center>600EX-RT's HSS Performance at 1/8000th in a 1D Mark III's shoe without any radios</center>
 
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HSS/Auto FP uses a pulsed light technique (instead of a normal single burst) that generates continuous light from before the first shutter begins to move until after the second shutter closes. At faster shutter speeds, both the first and second shutters are moving simultaneously, creating a moving slit across the digital sensor. Since the light appears continuous to the digital sensor, there is no clipping even at the fastest shutter speeds. 
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HSS/Auto FP requires a special flash like a Canon Speedlite or Nikon speedlight that is capable of performing this pulsed light technique. Studio strobes are not capable of pulsing light, a requirement for HSS/Auto FP. This method also requires special timing information from the camera that happens between the user pressing the shutter button and the camera's sensor opening. This information is communicated through the TTL pins of a camera's hot shoe. A normal studio flash or standard non-TTL flash cannot perform the light pulse technique, nor does it have the electrical connections required to use the pre-sync information from the camera's TTL hot shoe pins.
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The HSS/Auto FP timeline would look like this:
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HSS/Auto FP requires a speedlight. Studio strobes are not capable of pulsing light. HSS requires special timing information from the camera. This information is communicated through the TTL pins of a camera's hot shoe. A normal studio flash cannot perform the light pulse technique.
#The camera is triggered by the photographer. Several milliseconds of [[Lag Time]] pass.
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#Just before the first shutter would open, the camera sends signals through its hot shoe to the attached flash. This tells the Speedlight when to begin generating pulsed light as ...
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#The first shutter opens, exposing the digital sensor while the flash continuously pulses throughout the exposure.
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#Shortly after the first shutter moves, the second shutter begins to move. The pulsed light continues.
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#The second shutter in the camera closes and both shutters reset. The flash stops pulsing.
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The pulsed light technique cannot emit as much light as a normal flash pulse as it uses a lot of energy to make the light continuous. This means that your flash must be much closer to the subject to be effective.
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HSS exposures will not be as bright as standard single-pop flashes, because the available energy is divided among all the pulses over exposure time. The pulsed light requires more energy than non-pulsed flash. Flashes using HSS may need to be positioned closer to a subject.
  
 
== [[HyperSync]] ==
 
== [[HyperSync]] ==
  
A normal, single flash pop is much more efficient at delivering light to a subject than an HSS/Auto-FP (pulsed) flash. You can have your flash farther from a subject, or deliver more light to the scene when using a normal flash, as well as use flashes that aren't even capable of pulsing light as required for HSS/Auto-FP.
 
  
HyperSync uses special information available in the TTL shoe pins to trigger a normal flash ''before'' X-Sync would occur. It does this by knowing how much time passes from these communications until X-sync. It can also eliminate the delay introduced by a typical radio trigger. This is different from the "HSS hack" in that the timing is both adjustable, and can be optimized for some flashes.  
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A normal, non-HSS flash is more efficient at delivering light to a subject than an HSS (pulsed) flash. As a result, flashes may be positioned farther from a subject.
  
  
[[File:HyperSync-Reduced_Clipping.JPG|550px|center|HyperSync - The flash fires before the camera sends the "sync" signal]]
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HyperSync uses special camera communication to trigger a normal flash before the first curtain opens. It can also eliminate the delay introduced by a typical radio trigger. The timing can be optimized for some flashes based on the user’s wishes.
  
  
<center>HyperSync - The flash fires before the camera sends the "sync" signal</center>
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A camera triggering a flash with HyperSync follows this timeline:
  
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#The shutter button is pressed.
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#Several milliseconds of time pass. This is called lag time. The amount of lag time varies from camera to camera.
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#The attached MiniTT1 or FlexTT5 senses exactly when the shutter will fire, and then fires the flash early.
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#The first curtain begins to move from the top of the sensor to the bottom.
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#The camera’s sensor is exposed.
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#Before the first curtain reaches the bottom of the sensor, the second curtain begins to move. The space between the first and second curtain is a small slit. The faster the shutter speed is set the smaller the slit will become.
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#The first curtain reaches the bottom of the sensor.
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#The camera triggers its PC terminal and the center sync pin on the hot shoe.
  
HyperSync requires a ControlTL transmitter like the [[Nikon MiniTT1 and FlexTT5]] or [[Canon MiniTT1 and FlexTT5]]. Optimizing HyperSync Automation require a ControlTL receiver like the [[PowerMC2]], [[PowerST4]], or [[AC9 AlienBees Adapter]]. All transmitter HyperSync adjustments are made in the [[PocketWizard Utility]] on the [[HyperSync/HSS Tab]].  Any PocketWizard radio can be used as a receiver and be triggered from the ControlTL transmitter's HyperSync timing, but you will see the best results using a ControlTL receiver.
 
  
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HyperSync requires a ControlTL transmitter like the [[Nikon MiniTT1 and FlexTT5]] or [[Canon MiniTT1 and FlexTT5]]. Optimizing HyperSync Automation require a ControlTL receiver like the [[PowerMC2]], [[PowerST4]], or [[AC9 AlienBees Adapter]]. All transmitter HyperSync adjustments are made in the [[PocketWizard Utility]] on the [[HyperSync/HSS Tab]].  Any PocketWizard radio can be used as a receiver and be triggered from the ControlTL transmitter's HyperSync timing. You will see the best results using a ControlTL receiver.
  
When using a ControlTL receiver there are two methods of using HyperSync Automation to get flash sync at faster than X-Sync shutter speeds, [[Understanding HyperSync and High Speed Sync#Highest Energy|Highest Energy]] and [[Understanding HyperSync and High Speed Sync#Reduced Clipping|Reduced Clipping]].  Most flashes generate a tall peak of light when first triggered, then that light fades down to a long tail. The two methods choose when to start the flash in relation to the camera's shutters opening.
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There are two methods of using HyperSync Automation available on a ControlTL receiver: [[Understanding HyperSync and High Speed Sync#Reduced Clipping|Reduced Clipping]] and [[Understanding HyperSync and High Speed Sync#Highest Energy|Highest Energy]]. The two methods choose different flash firing times relative to the camera's shutters opening.
  
  
 
===Reduced Clipping===  
 
===Reduced Clipping===  
  
Reduced Clipping uses precision timing to keep hard black bars out of your images. This method may result in a gradation across the image (lighter at the bottom and darker at the top), but for many situations, the results are quite acceptable and usable.
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Reduced Clipping attempts to keep bottom frame clipping out of your images. Reduced Clipping may result in a gradient across the image. Gradation means the photo is lighter at the bottom and darker at the top.  The results are very usable in many situations.
  
 
<center><gallery perrow=2 widths=300px caption="Reduced Clipping">
 
<center><gallery perrow=2 widths=300px caption="Reduced Clipping">
File:IMG_0282.JPG|Ranger RX (S Head) at full power, 5D Mark II 1/8000th f/22
 
 
File:Reduced_clipping_offset.JPG|HyperSync Offset for "Reduced Clipping"
 
File:Reduced_clipping_offset.JPG|HyperSync Offset for "Reduced Clipping"
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File:IMG_0282.JPG|Ranger RX (S Head) at full power, 5D Mark II 1/8000th f/22
 
</gallery></center>
 
</gallery></center>
  
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"Reduced Clipping" is selected on the ControlTL receiver, as shown in the section [[HyperSync#Configuring HyperSync|Configuring HyperSync]].
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"Reduced Clipping" is selected on the ControlTL receiver, as shown in on the [[HyperSync Setup#All ControlTL Radios – HyperSync Automation|All ControlTL Radios – HyperSync Automation]] page. This is the factory default setting.
  
  
* You would be using this optimized tail HyperSync '''Automation''' by choosing [[Understanding HyperSync and High Speed Sync#Reduced Clipping|Reduced Clipping]] if you chose this option on the [[HyperSync/HSS Tab]] using a ControlTL receiver. This is the factory default setting.
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*You can achieve similar results to [[Understanding HyperSync and High Speed Sync#Reduced Clipping|Reduced Clipping]] '''manually''' with a non-ControlTL compatible flash by following the directions for the [[HyperSync Setup#How to Configure the Receiving FlexTT5 P2 Port|FlexTT5 P2 Port]] and trying to eliminate clipping at your '''highest''' shutter speeds.
* You would be able to use [[Understanding HyperSync and High Speed Sync#Reduced Clipping|Reduced Clipping]]-style HyperSync '''manually''' with a FlexTT5 connected to your flash as a receiver by following the directions for the [[HyperSync#FlexTT5 - Flash Connected to P2 Port|FlexTT5 P2 Port]] and trying to eliminate clipping at your '''highest''' shutter speeds.
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* You can achieve similar results to [[Understanding HyperSync and High Speed Sync#Reduced Clipping|Reduced Clipping]] '''manually''' with a radio receiving on a [[Channels#Standard Channels|Standard Channel]] (meaning a ([[Plus II]], [[Plus III]], [[PlusX]], [[MultiMAX]], [[Misc_Tab#Basic_Trigger|FlexTT5 in Basic Trigger Mode]]), or internal PocketWizard receiver built in to your flash.) This is done by following the directions for the [[HyperSync Setup#How to Configure the ControlTL Transmitter - HyperSync Flash Duration For Standard Channels|How to Configure the ControlTL Transmitter - HyperSync Flash Duration For Standard Channels]] section, and trying to eliminate clipping at your '''highest''' shutter speeds.
* You can attempt to use [[Understanding HyperSync and High Speed Sync#Reduced Clipping|Reduced Clipping]]-style HyperSync '''manually''' with a radio receiving on a [[Channels#Standard Channels|Standard Channel]] (meaning a ([[Plus II]], [[Plus III]], [[PlusX]], [[MultiMAX]], [[Misc_Tab#Basic_Trigger|FlexTT5 in Basic Trigger Mode]]), or internal PocketWizard receiver built in to your flash.) This is done by following the directions for the [[HyperSync#PocketWizard Radio Receiving on a Standard Channel|PocketWizard Radio Receiving on a Standard Channel]] section, and trying to eliminate clipping at your '''highest''' shutter speeds.
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Note: We do not recommend using Speedlites for HyperSync due to both their short flash durations, and their IGBT design, which makes HyperSync feasible only at full power. HSS/Auto-FP may return more desirable results for users shooting above x-sync with Speedlites.
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Note: Using Speedlites or the Einstein E-640 for HyperSync with HyperSync is most effective at full power with these flashes because of their IGBT design. HSS/Auto-FP is suggested for users shooting above X-sync with Speedlites. You can read more about IGBT designed flashes here: http://www.paulcbuff.com/sfe-flashduration.php
  
  
'''''Read the [[HyperSync]] section for more detailed information on how to adjust HyperSync.'''''
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'''''Read the [[HyperSync Setup]] page for more detailed information on how to adjust HyperSync.'''''
  
 
=== Highest Energy ===
 
=== Highest Energy ===
  
Highest Energy uses precision timing to get as much flash energy into the image as possible above X-sync. This will reduce gradation, but can result in black bars or clipping in the frame.   For many photographic situations this can yield acceptable or useful results as clipping can be cropped out of the image.
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Highest Energy attempts to get as much flash energy into the image as possible. This will reduce gradation at lower HyperSync speeds, however it can result in black bars or clipping in the frame at the highest shutter speeds. For many situations this can yield useful results as clipping can be cropped out of the image, or the clipping area is exposed by ambient light primiarily.
  
  
 
<center><gallery perrow=2 widths=300px caption="Highest Energy">
 
<center><gallery perrow=2 widths=300px caption="Highest Energy">
File:IMG 4015.JPG|Ranger RX (S Head) at full power, 5D Mark II 1/8000th f/22
 
 
File:Highest energy offset.JPG|HyperSync Offset for "Highest Energy"
 
File:Highest energy offset.JPG|HyperSync Offset for "Highest Energy"
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File:IMG 4015.JPG|Ranger RX (S Head) at full power, 5D Mark II 1/8000th f/22
 
</gallery></center>
 
</gallery></center>
  
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Highest Energy benefits photographers:
 
Highest Energy benefits photographers:
  
*Using HyperSync speeds just above your camera's x-sync speed, such at 1/500th or 1/1000th. This may not be the best choice at 1/8000th or the highest limit of your camera.
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*Using HyperSync speeds just above X-sync  
*Needing as much action stopping flash power in the image as possible (remember that for HyperSync, '''longer''' flash durations are better)
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*Who need as much action stopping flash power in the image as possible (remember that for HyperSync, longer flash durations are better)
*Gathering images where gradation is not acceptable
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*Where gradation is not acceptable
 
*In any situation where cropping is an option
 
*In any situation where cropping is an option
  
  
"Highest Energy" is selected on the ControlTL receiver, as shown in the section [[HyperSync#Configuring HyperSync|Configuring HyperSync]].
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"Highest Energy" is selected on the ControlTL receiver, as shown on the [[HyperSync Setup#All ControlTL Radios – HyperSync Automation|All ControlTL Radios – HyperSync Automation]] page.
  
  
* You would be using this optimized [[Understanding HyperSync and High Speed Sync#Highest Energy|Highest Energy]] HyperSync '''Automation''' by choosing [[Understanding HyperSync and High Speed Sync#Highest Energy|Highest Energy]] if you chose this option on the [[HyperSync/HSS Tab]] using a ControlTL receiver.
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*You can achieve similar results to [[Understanding HyperSync and High Speed Sync#Highest Energy|Highest Energy]] '''manually''' with a non-ControlTL compatible flash by following the directions for the [[HyperSync Setup#How to Configure the Receiving FlexTT5 P2 Port|FlexTT5 P2 Port]] and trying to eliminate clipping at '''lower''' HyperSync speeds without "clipping" visible at the bottom of your frame.
* You can use [[Understanding HyperSync and High Speed Sync#Highest Energy|Highest Energy]]-style HyperSync '''manually''' with a non-ControlTL compatible flash by using a FlexTT5 connected to your flash as a receiver by following the directions for the [[HyperSync#FlexTT5 - FlexTT5 - Flash Connected to P2 Port|FlexTT5 P2 Port]] and trying to put the most flash energy in the frame at '''lower''' HyperSync speeds without "clipping" visible at the bottom of your frame.
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* You can achieve similar results to [[Understanding HyperSync and High Speed Sync#Highest Energy|Highest Energy]] HyperSync '''manually''' with a radio receiving on a [[Channels#Standard Channels|Standard Channel]] (meaning a ([[Plus II]], [[Plus III]], [[PlusX]], [[MultiMAX]], [[Misc_Tab#Basic_Trigger|FlexTT5 in Basic Trigger Mode]]), or internal PocketWizard receiver built in to your flash.) This is done by following the directions for the [[HyperSync Setup#How to Configure the ControlTL Transmitter - HyperSync Flash Duration For Standard Channels|How to Configure the ControlTL Transmitter - HyperSync Flash Duration For Standard Channels]] section, and trying to eliminate clipping at your '''lower''' HyperSync speeds without "clipping" visible at the bottom of your frame.
* You can attempt to use [[Understanding HyperSync and High Speed Sync#Highest Energy|Highest Energy]]-style HyperSync '''manually''' with a radio receiving on a [[Channels#Standard Channels|Standard Channel]] (meaning a [[Plus II]], [[Plus III]], [[PlusX]], [[MultiMAX]], [[Misc_Tab#Basic_Trigger|FlexTT5 in Basic Trigger Mode]]), or internal PocketWizard receiver built in to your flash.) This is done by following the directions for the [[HyperSync#PocketWizard Radio Receiving on a Standard Channel|PocketWizard Radio Receiving on a Standard Channel]] section, and trying to put the most flash energy in the frame at '''lower''' HyperSync speeds without "clipping" visible at the bottom of your frame.
+
  
  
Note: We do not recommend using Speedlites for HyperSync due to both their short flash durations, and their IGBT design, which makes HyperSync feasible only at full power. HSS/Auto-FP may return more desirable results for users shooting above x-sync with Speedlites.
+
Note: Using Speedlites or the Einstein E-640 for HyperSync with HyperSync is most effective at full power with these flashes because of their IGBT design. HSS/Auto-FP is suggested for users shooting above X-sync with Speedlites. You can read more about IGBT designed flashes here: http://www.paulcbuff.com/sfe-flashduration.php
  
  
'''''Read the [[HyperSync]] section for more detailed information on how to adjust HyperSync.'''''
+
'''''Read the [[HyperSync Setup]] page for more detailed information on how to adjust HyperSync.'''''
  
 
=== Factors to consider ===
 
=== Factors to consider ===
  
There are many factors that change from flash to flash that affect the success of HyperSync.
+
 
 +
There are many factors that may impact HyperSync performance.
 +
 
  
 
==== Flash Duration ====
 
==== Flash Duration ====
  
  
* Flash duration is a critical factor. The flash duration is the length of time from when your flashtube is initially energized to when it is no longer emitting energy. Longer flash durations are better. You may want to compare and contrast flash t.5 times from the flash's manufacturer directly to see how long or short your flash is. The t.5 times listed below come from the Ranger RX manual, for example.
+
*Flash duration is a critical factor in HyperSync performance. The flash duration is the length of time from when your flashtube is first energized to when it is no longer emitting energy. Longer flash durations are better. You may want to compare t.5 times from flash manufacturers to see how long or short your flash is compared to others.  
 +
 
  
 
<center><gallery perrow=2 widths=300px caption="Difference Flash Duration Makes With Otherwise Matching Equipment">
 
<center><gallery perrow=2 widths=300px caption="Difference Flash Duration Makes With Otherwise Matching Equipment">
Line 194: Line 273:
  
  
* Flash duration often changes with power level. When you are fine-tuning HyperSync, make sure to test across the flash power levels you intend to use so you can see if certain flash durations will cause clipping at any shutter speed you intend to use. For a great comparison of how important flash duration is, see the 5D Mark II results below for HyperSync with a Ranger RX Pack with an S head, and the results with a Ranger RX Pack with an A head. Both image were generated with the same pack and the same camera, but the flash duration is much, much shorter with the A head, and has a very noticeable visual effect. You can see these images and more on our [[HyperSync#White Wall vs. Real World|Camera HyperSync results page]].
+
*Flash duration is a critical factor in HyperSync performance. The flash duration is the length of time from when your flashtube is first energized to when it is no longer emitting energy. Longer flash durations are better. You may want to compare t.5 times from flash manufacturers to see how long or short your flash is compared to others.  
  
  
Line 204: Line 283:
 
</gallery></center>
 
</gallery></center>
  
==== Camera Choice ====
+
==== Use with IGBT-controlled strobes ====
  
* Cameras with larger and slower shutter blades will make HyperSync less likely to work without noticeable gradation. Cameras with faster moving shutters, smaller sensors, or crop mode can often improve HyperSync success by minimizing gradation. This is not the same as your camera's shutter speed setting.
 
  
 +
*A Speedlight, Einstein E640, or other IGBT-controlled flash will need to be used at full power with HyperSync. Power levels less than full will result in clipping at the top and bottom due to the way IGBT-controlled flashes adjust flash duration for power control.
 +
 +
To read more about how IGBT-controlled flashes differ from other types of flashes, see the [[IGBT-controlled flashes vs. Voltage-controlled flashes]] page.
 +
 +
 +
<center><gallery perrow=2 widths=300px caption="IGBT-controlled flash at 1/1 power and 1/2 power">
 +
File:5DMarkIIEinsteinFullPower.JPG|Einstein E640 at full power, 5D Mark II 1/8000th f/11
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File:5D_Mark_II_Einstein-1Stops.JPG|Einstein E640 (with PowerMC2) -1 stop from full, 5D Mark II 1/8000th f/11
 +
File:Einstein_full_timing.JPG|Einstein E640 Flash Duration Shape t.5=1/2000th
 +
File:Einstein_FlashDuration_-1.JPG|Einstein E640 Flash Duration Shape t.5=1/4000th (estimated)
 +
</gallery></center>
 +
 +
==== Camera Choice ====
 +
 +
*Cameras with larger and slower shutters can produce more noticeable gradation. Cameras with faster moving shutters and smaller sensors can improve HyperSync success by minimizing gradation. Faster or slower moving shutters are not the same as your camera's shutter speed setting.
  
 
<center><gallery perrow=2 widths=300px caption="Camera Choice">
 
<center><gallery perrow=2 widths=300px caption="Camera Choice">
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</gallery></center>
 
</gallery></center>
  
==== Camera Communication Time ====
+
*Some cameras allow enough time for HyperSync to fire before the camera moves its first shutter. Some do not. Different combinations yield different results.
 
+
* HyperSync uses communications coming from the camera’s hotshoe to determine how early to fire the flash. Some cameras deliver this critical information earlier than others, providing the radio with more time to adjust the flash pulse in relation to camera sync. Cameras with more communication time are the best HyperSync performers and provide less bottom-frame clipping. Camera with less communication time will show more clipping at the bottom of the frame.
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<center><gallery perrow=2 widths=300px caption="Communication Time Limitation">
 
<center><gallery perrow=2 widths=300px caption="Communication Time Limitation">
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File:D3RangerRXS_RC_+3.JPG|Ranger RX (S Head) at full power, Nikon D3 1/8000th f/22 (HyperSync Only Enabled)''' (Less Communication Time)'''
 
File:D3RangerRXS_RC_+3.JPG|Ranger RX (S Head) at full power, Nikon D3 1/8000th f/22 (HyperSync Only Enabled)''' (Less Communication Time)'''
 
</gallery></center>
 
</gallery></center>
 
=== What HyperSync results can I get with my camera and flash? ===
 
 
Thankfully, we have done a lot of the guess work for by sharing images that we have captured using as many combinations of camera and flash model as possible. Those photographs are available below. Simply click on your camera, then find the flash that you wish to use with HyperSync. There are countless combinations of flashes and cameras in the world, and only so many hours in a day, so we are constantly trying to add more and more flashes as time goes by. If you don't see a flash yet, feel free to contact us directly: http://www.pocketwizard.com/contact/inquiry/
 
 
<center>
 
{{C HATT}}
 
{{N HATT}}
 
</center>
 
 
 
{{Don't see your gear?}}
 

Revision as of 06:30, 6 August 2014

Next recommended reading: HyperSync

This section describes how HyperSync and High Speed Sync work at a basic level. Read the HyperSync Setup page for more detailed information on how to adjust HyperSync for your configuration.


When shooting with flash, there are different methods of synchronizing the flash with a camera’s shutter. These methods depend primarily on the shutter speed and flashes you use.


While the flash appears instantaneous to our eyes, it actually has duration and variance. These are important to the camera’s sensor, especially at faster shutter speeds.


At shutter speeds slower than X-sync, usually 1/200 or slower, a normal flash of light is all that is required; the first curtain of the shutter opens, the flash fires for its flash duration, and the second curtain of the shutter closes.


At shutter speeds faster than X-sync (usually 1/250 through 1/8000) the time between the shutter’s first curtain opening and second curtain closing is not long enough for a normal flash of light to complete its duration. At the fastest shutter speeds, the shutter’s curtains are moving at the same time, exposing a moving slit of light across the sensor. At these shutter speeds, other flash techniques must be used.


High Speed Sync (HSS or Auto-FP sync) begins pulsing the flash before the first curtain opens and continues to pulse it until after the second curtain closes. From the camera’s perspective this pulsed light appears as continuous light during the exposure. HSS uses a lot of energy, however, which means there is less light available for the image, and is usually only available in lower powered Speedlites/Speedlights. Syncing up to 1/8000 is possible, but the flash must be very close to the subject.


HyperSync uses a normal flash of light, which has much more energy in it compared to pulsed HSS. HyperSync also uses precision timing to align the flash’s duration and output curve with the moving shutter curtains. This allows more light in the image than HSS can provide, and works with higher powered flashes like studio flash packs and monolights. Different flash and camera combinations yield different shutter speed and light output performance, but most combinations will get worthwhile benefits using HyperSync.


Other techniques, like the "HSS Hack" (with or without a manually dialed in delay), can sometimes get a normal flash of light from a studio pack into an exposure taken at faster shutter speeds, but these methods are less precise than HyperSync, lack automation, and are more limited to which camera and flash combinations yield usable results.


What HyperSync results can I get with my camera and flash?

Thankfully, we have done a lot of the work for you by sharing images that we have captured using as many combinations of camera and flash model as possible. Our examples are available below. Simply click on your camera and find the flash that you wish to use with HyperSync. There are countless combinations of flashes and cameras in the world, and we will add more cameras and flashes as time goes by. If you don't see your equipment, feel free to contact us directly: http://www.pocketwizard.com/contact/inquiry/

Canon Camera HyperSync Results
Canon 1D X Canon 7D Canon 70D Canon Rebel T5i (700D)
Canon 1D Mark IV Canon 6D Canon 60D Canon Rebel T5 (1200D)
Canon 1Ds Mark III Canon 5D Mark III Canon 50D Canon Rebel SL1 (650D)
Canon 1D Mark III Canon 5D Mark II Canon 40D Canon Rebel T4i (650D)
Canon 1Ds Mark II Canon 5D Canon 30D Canon Rebel T3i (600D)
Canon 1D Mark II N Canon 20D Canon Rebel T3 (110D)
Canon 1D Mark II Canon Rebel T2i (550D)
Canon Rebel T1i (500D)
Canon Rebel XSi (450D)
Canon Rebel XTi (400D)
Canon Rebel XT (350D)
Canon Rebel XS (1000D)
Nikon Camera HyperSync Results
Nikon D4S Nikon D810 Nikon D7100 Nikon Df
Nikon D4 Nikon D800 Nikon D7000
Nikon D3x Nikon D800E Nikon D5300* Nikon D90
Nikon D3s Nikon D700 Nikon D5200* Nikon D80
Nikon D3 Nikon D610 Nikon D5100* Nikon D40x*
Nikon D2x Nikon D600 Nikon D5000* Nikon D40*
Nikon D300s Nikon D3300*
Nikon D300 Nikon D3200*
Nikon D200 Nikon D3100*
Nikon D3000*

* These cameras do not support HyperSync or HSS/FP-Sync operation: D5300, D5200, D5100, D5000, D3300, D3200, D3100, D3000, D40x, D40

Read the HyperSync Setup page for more detailed information on how to adjust HyperSync.


Don't see your gear?
We have paused our HyperSync testing and PDF production for the time being. We may be adding more results to the wiki as they become available. Check back in the future.


How Does a Flash Work?

A flash is designed to emit a very intense light for a short duration of time. This is done by filling a flashtube with xenon gas, and then using a charged capacitor to energize the xenon with a very high amount of electrical current. This produces the light that flashes use to illuminate a scene. You can visualize a single flash event as “light over time,” plotted as a curve. The peak has the highest amount of energy emitted but energy continues to be emitted at a decreasing rate so long as the xenon gas is energized. This drop in energy (and therefore light output) creates the “tail” of the curve.


Typical flash duration simulation - Ranger RX pack with the S head at full power
Typical flash duration simulation - Ranger RX pack with the S head at full power


While appearing to be instantly turned on and instantly turned off again, a flashtube can be excited for anywhere from 1 microsecond to tens of milliseconds. Most consumer flashes usually average around 1 millisecond, with some being longer, and some being shorter.


How Does a Shutter Work?

A camera’s shutter has two curtains that cover the sensor. When you press the shutter button, the first curtain moves, exposing the sensor. Next, the second curtain moves, finishing the exposure. Your first curtain opens all the way before the second curtain starts to move. This fully exposes the camera’s sensor. Your camera has a limit where it can fully open its shutter and capture a normal flash duration across the entire exposure all at once. This is your camera’s X-sync limit.

X-SyncShutter.gif
A simulated shutter at X-sync


Shutter speeds above X-sync act differently. The first curtain begins to move downwards. Before they reach the bottom, the second curtain begins to move. This creates a moving slit.


MediumShuttersAboveX-Sync.gif
A simulated shutter above X-sync]


The faster the shutter speed, the smaller the slit:


FastestShuttersAboveX-Sync.gif
Faster shutter speeds have smaller slits

X-sync - Flash behavior with normal sync limits

A flash directly connected to a camera

Your camera has a limit where it can fully open its shutter and capture flash across the entire sensor all at once. This is your camera’s X-sync limit.


A camera triggering a flash at X-sync follows this timeline:

  1. The shutter button is pressed.
  2. Several milliseconds of time pass. This is called lag time. The amount of lag time varies from camera to camera.
  3. The first curtain moves from the top of the sensor to the bottom. The camera’s sensor is exposed.
  4. Some microseconds of time pass. The camera triggers its PC terminal and the center sync pin on the hot shoe.
  5. The flash emits light for its flash duration. The time this happens can be any amount of time up to a few milliseconds.
  6. The second curtain moves from the top of the sensor to the bottom.
  7. The second curtain in the camera closes and both curtains reset to the top of the sensor



Shutter speeds above X-sync work differently. A camera triggering a flash above X-sync follows this timeline:

  1. The shutter button is pressed.
  2. Several milliseconds of time pass. This is called lag time. The amount of lag time varies from camera to camera.
  3. The first curtain begins expose the sensor as it moves from top to bottom.
  4. Before the first curtain reaches the bottom of the sensor, the second curtain begins to move. The space between the first and second curtain is a small slit that moves across the sensor. The faster your shutter speed, the smaller the slit becomes.
  5. The first curtain reaches the bottom of the sensor.
  6. The camera triggers its PC terminal and the center sync pin on the hot shoe. (Many cameras do not provide this sync output above X-sync.)
  7. The flash emits light for its flash duration. The time this happens can be any amount of time up to a few milliseconds.
  8. The moving slit is exposed to the flash.
  9. The second curtain in the camera closes and both curtains reset to the top of the sensor


When a camera connected directly to a flash via sync cable is used above X-sync the second curtain blocks part of the sensor from being exposed to light. This shows up as a black band, or clipping.



The timing sequence has tighter tolerances at X-sync compared to slower speeds. This tighter tolerance and the radio processing delay moves the moment the sensor sees the flash. Since the second curtain has started to move a small bit, on a very small number of cameras you get shadowing or clipping in your exposure. Flashes with long durations can show clipping at X-sync. Cameras with slow shutters can show clipping at X-sync. To get rid of clipping, you may have to use a slower shutter speed.

The PlusX, Plus III, or MultiMAX have a mode to reduce this delay, called Transmit Only. A receiving Plus III can use FAST mode to reduce processing time.

High Speed Sync

High Speed Sync (HSS) is a Canon technique for syncing flash above X-sync. HSS is called Auto-FP in the Nikon system. This is a speedlight-only technique that pulses light above X-sync. This appears to the camera as a continuous light at faster shutter speeds.


A camera and flash using HSS/Auto-FP follow this timeline:

  1. The shutter button is pressed.
  2. Several milliseconds of time pass. This is called lag time. The amount of lag time varies from camera to camera.
  3. The speedlight begins to pulse light just before the first curtain begins to move.
  4. The first curtain begins to move from the top of the sensor to the bottom.
  5. The camera’s sensor is exposed.
  6. Before the first curtain reaches the bottom of the sensor, the second curtain begins to move. The space between the first and second curtain is a small slit that moves across the sensor. The faster your shutter speed, the smaller the slit becomes.
  7. The speedlight continues to pulse.
  8. The first curtain reaches the bottom of the sensor.
  9. The second curtain in the camera closes and both curtains reset to the top of the sensor.
  10. The speedlight stops pulsing.


HSS Pulses at various shutter speeds within the Canon Optical communications system
600EX-RT's HSS Performance at 1/8000th in a 1D Mark III's shoe without any radios


HSS/Auto FP requires a speedlight. Studio strobes are not capable of pulsing light. HSS requires special timing information from the camera. This information is communicated through the TTL pins of a camera's hot shoe. A normal studio flash cannot perform the light pulse technique.


HSS exposures will not be as bright as standard single-pop flashes, because the available energy is divided among all the pulses over exposure time. The pulsed light requires more energy than non-pulsed flash. Flashes using HSS may need to be positioned closer to a subject.

HyperSync

A normal, non-HSS flash is more efficient at delivering light to a subject than an HSS (pulsed) flash. As a result, flashes may be positioned farther from a subject.


HyperSync uses special camera communication to trigger a normal flash before the first curtain opens. It can also eliminate the delay introduced by a typical radio trigger. The timing can be optimized for some flashes based on the user’s wishes.


A camera triggering a flash with HyperSync follows this timeline:

  1. The shutter button is pressed.
  2. Several milliseconds of time pass. This is called lag time. The amount of lag time varies from camera to camera.
  3. The attached MiniTT1 or FlexTT5 senses exactly when the shutter will fire, and then fires the flash early.
  4. The first curtain begins to move from the top of the sensor to the bottom.
  5. The camera’s sensor is exposed.
  6. Before the first curtain reaches the bottom of the sensor, the second curtain begins to move. The space between the first and second curtain is a small slit. The faster the shutter speed is set the smaller the slit will become.
  7. The first curtain reaches the bottom of the sensor.
  8. The camera triggers its PC terminal and the center sync pin on the hot shoe.


HyperSync requires a ControlTL transmitter like the Nikon MiniTT1 and FlexTT5 or Canon MiniTT1 and FlexTT5. Optimizing HyperSync Automation require a ControlTL receiver like the PowerMC2, PowerST4, or AC9 AlienBees Adapter. All transmitter HyperSync adjustments are made in the PocketWizard Utility on the HyperSync/HSS Tab. Any PocketWizard radio can be used as a receiver and be triggered from the ControlTL transmitter's HyperSync timing. You will see the best results using a ControlTL receiver.


There are two methods of using HyperSync Automation available on a ControlTL receiver: Reduced Clipping and Highest Energy. The two methods choose different flash firing times relative to the camera's shutters opening.


Reduced Clipping

Reduced Clipping attempts to keep bottom frame clipping out of your images. Reduced Clipping may result in a gradient across the image. Gradation means the photo is lighter at the bottom and darker at the top. The results are very usable in many situations.


Reduced Clipping benefits photographers:

  • Shooting outdoors where the sky is a major factor in the top part of the image
  • Using aperture priority in conditions that cause the shutter speed to go above X-sync
  • In any situation where the full frame must be used and cropping is not an option


"Reduced Clipping" is selected on the ControlTL receiver, as shown in on the All ControlTL Radios – HyperSync Automation page. This is the factory default setting.



Note: Using Speedlites or the Einstein E-640 for HyperSync with HyperSync is most effective at full power with these flashes because of their IGBT design. HSS/Auto-FP is suggested for users shooting above X-sync with Speedlites. You can read more about IGBT designed flashes here: http://www.paulcbuff.com/sfe-flashduration.php


Read the HyperSync Setup page for more detailed information on how to adjust HyperSync.

Highest Energy

Highest Energy attempts to get as much flash energy into the image as possible. This will reduce gradation at lower HyperSync speeds, however it can result in black bars or clipping in the frame at the highest shutter speeds. For many situations this can yield useful results as clipping can be cropped out of the image, or the clipping area is exposed by ambient light primiarily.



Highest Energy benefits photographers:

  • Using HyperSync speeds just above X-sync
  • Who need as much action stopping flash power in the image as possible (remember that for HyperSync, longer flash durations are better)
  • Where gradation is not acceptable
  • In any situation where cropping is an option


"Highest Energy" is selected on the ControlTL receiver, as shown on the All ControlTL Radios – HyperSync Automation page.



Note: Using Speedlites or the Einstein E-640 for HyperSync with HyperSync is most effective at full power with these flashes because of their IGBT design. HSS/Auto-FP is suggested for users shooting above X-sync with Speedlites. You can read more about IGBT designed flashes here: http://www.paulcbuff.com/sfe-flashduration.php


Read the HyperSync Setup page for more detailed information on how to adjust HyperSync.

Factors to consider

There are many factors that may impact HyperSync performance.


Flash Duration

  • Flash duration is a critical factor in HyperSync performance. The flash duration is the length of time from when your flashtube is first energized to when it is no longer emitting energy. Longer flash durations are better. You may want to compare t.5 times from flash manufacturers to see how long or short your flash is compared to others.


Power Level

  • Flash duration is a critical factor in HyperSync performance. The flash duration is the length of time from when your flashtube is first energized to when it is no longer emitting energy. Longer flash durations are better. You may want to compare t.5 times from flash manufacturers to see how long or short your flash is compared to others.


Use with IGBT-controlled strobes

  • A Speedlight, Einstein E640, or other IGBT-controlled flash will need to be used at full power with HyperSync. Power levels less than full will result in clipping at the top and bottom due to the way IGBT-controlled flashes adjust flash duration for power control.

To read more about how IGBT-controlled flashes differ from other types of flashes, see the IGBT-controlled flashes vs. Voltage-controlled flashes page.


Camera Choice

  • Cameras with larger and slower shutters can produce more noticeable gradation. Cameras with faster moving shutters and smaller sensors can improve HyperSync success by minimizing gradation. Faster or slower moving shutters are not the same as your camera's shutter speed setting.
  • Some cameras allow enough time for HyperSync to fire before the camera moves its first shutter. Some do not. Different combinations yield different results.