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Trigger Digits 100%

Hand Upper Limb Orthopaedic Trauma Your Guide to Trigger Digits (Stenosing Tenovaginitis) The fingers can be moved immediately following the procedure and heavy work may not be possible until the wound has healed.

https://www.pdf-archive.com/2015/11/30/trigger-digits/

30/11/2015 www.pdf-archive.com

official street fighter® v season 2 99%

Increased recovery on-hit by 8F  Reduced stun damage from 170 to 120  Reduced CA gauge accrual  Increased distance from opponent after hit  Standing LP (Normal/V-Trigger):

https://www.pdf-archive.com/2016/12/20/official-street-fighter-v-season-2/

20/12/2016 www.pdf-archive.com

Cavalier Wiring 99%

1991 Chevy Cavalier WIRE 12V CONSTANT WIRE STARTER WIRE IGNITION WIRE ACCESSORY WIRE POWER DOOR LOCK (5-wire reverse polarity) POWER DOOR UNLOCK (5-wire reverse polarity) PARKING LIGHTS (+) DRIVER DOOR TRIGGER (-) PASSENGER DOOR TRIGGER (-) DOME LIGHT SUPERVISION (-) TRUNK TRIGGER (-) TRUNK RELEASE (+) TACHOMETER BRAKE WIRE (+) HORN TRIGGER (-) LEFT FRONT WINDOW UP LEFT FRONT WINDOW DOWN RIGHT FRONT WINDOW UP WIRE COLOR RED YELLOW PINK ORANGE LT.

https://www.pdf-archive.com/2011/12/18/cavalier-wiring/

18/12/2011 www.pdf-archive.com

InstekGOS 635G 622G 620.specsheet 98%

Coupled with various trigger functions (Auto, Norm, TV), complex waveforms can be easily triggered for use in diverse applications.

https://www.pdf-archive.com/2015/04/01/instekgos-635g-622g-620-specsheet/

01/04/2015 www.pdf-archive.com

IRITS-0516-053-Pneumatic Assembly Tools For General Industry 97%

055 150 S06 = 3/8” Square D = PFCS 35 = 35 mm Head M = Numeric LED 008 035 150 315 B = Transfer Key S08 = 1/2” Square Motor 1 = 115 VAC US W = Wall Mount S = Small Anglehead A = 8 I/O 08 = 850 C =200 Cushion A = Angle 1M = 1= Spindle = 1/2” Square M =S08 Plus 43 = 43 mmLHead 012 050 190 435 = 3/4”Mount Square Z = Offset 2 = 220 CS12 = Cabinet = Large Anglehead B = 24 I/O 10 = 1000 Clutch VAC US 225 S12 = 3/4” Square 48 = 50 mm Head 016 055 220 450 S16 = 1” Square X = High Torque 12A==Inline 1270 = Stall W = Wall Mount 8 I/ODInline 3 = 230 VAC European 1 = 1 Spindle 1 = 115 VAC US Inline 1 = Serial, Ethernet 56 = 60 mm Head 020 090 520 62 = 150 mm Spindle, 50 mm float 15B==1500 C == 1/4” Cabinet Mount 24 I/O 040 2 P= =220 VACtoUS 1 Quick Change 012 025 Push Start 1 = Reversible 3 = PROFIBUS, Serial, Ethernet 650 92 = 225 mm Spindle, 50 mm float Inline 3 S= =230 VAC European S = Single 3 = 1/4” Bit Finder 01517 = 1750 030 1 = Serial, 055 Ethernet Trigger T = Top 4 = DeviceNet, Serial, Ethernet 01K = 1000 22 = 300 mm Spindle, 50 mm float 20 25 mm Spindle, no float Transducer 4 ==Serial, 1/4” Square 02020 = 2000 040 3 = PROFIBUS, 070 L = Lever Blank = Bottom 5 = Interbus-S, Serial, Ethernet Ethernet 15C = 1500 28 = 2800 21 50 mm Spindle, 19 mm float 6 ==Serial, 3/8” Square 027 055 4 = DeviceNet, 090 T = Trigger/ 6 = EtherNet/IP, Modbus-TCP, Serial, Ethernet Ethernet 18C = 1750 41 = 100 mm Spindle, 19 mm float L = Light 9 = 1/4” Hex Detent 046 115 Lever + Push 5 = Interbus-S, Serial, Ethernet 20C = 2000 61 = 150 mm Spindle, 38 mm float H = Heavy 150 6 = EtherNet/IP, Modbus-TCP, Serial, Ethernet 22C = 2200 81 = 200 mm Spindle, 38 mm float S = Solid 180 25C = 2500 Series S06 = 3/8” Square S08 = 1/2” Square S12 = 3/4” Square QM S16 = 1” Square 2 = 150 mm Spindle, 50 mm float 2 = 225 mm Spindle, 50 mm float 2 = 300 mm Spindle, 50 mm float R B N S A A G L R Q S Model Identification Guide 1 Series Air Screwdrivers / Nutrunners Fixtured Fastening 1 R AHandles N () QMMH C 1 B T D A T = Trigger Blank = No Trigger D = Detent Blank = No Slide 20 &

https://www.pdf-archive.com/2017/03/24/irits-0516-053-pneumatic-assembly-tools-for-general-industry/

24/03/2017 www.pdf-archive.com

BF375M 24V 1A PSU Insts DFU3750100 rev3 (2) 96%

Two inputs are provided (trigger and hold off).

https://www.pdf-archive.com/2017/08/23/bf375m-24v-1a-psu-insts-dfu3750100-rev3-2/

23/08/2017 www.pdf-archive.com

CreditUnion-universal-Flat 12 96%

Delivers CREDIT UNION TRIGGERS “From Conversation to Conversion” FROM CONVERSATION TO CONVERSION A TRIGGER LEADS TO A CHAIN OF DESIRED BEHAVIORS.

https://www.pdf-archive.com/2016/02/02/creditunion-universal-flat-12/

02/02/2016 www.pdf-archive.com

Aurons Day 96%

The below example is just a regular 5 trigger day/night cycle which doesnt require much skill to work it out.

https://www.pdf-archive.com/2011/12/25/aurons-day/

25/12/2011 www.pdf-archive.com

TurnCounterHowto 94%

Setting up the turn counter    Analog triggers  Analog triggers convert analog signals into digital signals using the cRIO’s FPGA. In order to  make the turn counter work, we use an analog trigger to create a digital signal when the  potentiometer “wraps around” from 0° to 360° or 360° to 0°.     Code sample (creating an analog trigger):     AnalogTrigger​  _analogTrigger ​ =​  ​ new​  ​ AnalogTrigger​ (​ channel​ );    Analog trigger outputs  The analog trigger can send outputs in a number of different modes. The two most useful to us  here are Rising Pulse and Falling Pulse. Rising Pulse sends a pulse of digital signal when the  analog signal changes from a value below the minimum voltage you’ve set (hereafter called the  “lower threshold”) to a value above the maximum voltage you’ve set (the “upper threshold”).  Falling Pulse sends a pulse when the signal changes from a value above the upper threshold to  one below the lower threshold. One of these should pulse whenever you hit the potentiometer’s  discontinuity; which one indicates the direction the wheel pod is turning.    Code sample (creating analog trigger outputs):    AnalogTriggerOutput​  _analogTriggerFalling ​ =​  ​ new​  ​ AnalogTriggerOutput​ (​ _analogTrigger​ ,  AnalogTriggerOutput​ .​ Type​ .​ kFallingPulse​ );    AnalogTriggerOutput​  _analogTriggerRising ​ =​  ​ new​  ​ AnalogTriggerOutput​ (​ _analogTrigger​ ,  AnalogTriggerOutput​ .​ Type​ .​ kRisingPulse​ );    Creating the counter  To create a turn counter, we need to count the digital pulses of the analog trigger outputs. When  one pulses, we should increment the counter; when the other pulses, we should decrement it.  Which is which depends on your setup.     Code sample (creating the turn counter):    Counter​  _turnCounter ​ =​  ​ new​  ​ Counter​ ();  _turnCounter​ .​ setUpDownCounterMode​ ();  _turnCounter​ .​ setUpSource​ (​ _analogTriggerRising​ );  _turnCounter​ .​ setDownSource​ (​ _analogTriggerFalling​ );  _turnCounter​ .​ start​ ();    The filter, setting the sample rate and threshold voltages  Although the potentiometer’s discontinuity normally looks like a straight vertical line of voltage, it  isn’t; it’s a very steep, not­quite­vertical line. Thus, when crossing it, there’s a chance that one of  the voltages sampled by the analog trigger will be on that line, which really messes things up.  Luckily, you can enable a filter on the analog trigger’s input that samples three points and  rejects the one closest to average. In this way, so long as no more than one sampled point in a  row lies on the discontinuity and the surrounding points are below / above the lower / upper  threshold voltages, the crossing will still be detected. We need to set the sample rate low  enough that no more than one point can lie on the line.     This graph shows a closeup of the potentiometer’s discontinuity. In theory, so long as the  sample rate is slower than the 520 Hz displayed, no more than one point should lie along the  line. In practice, I found a huge margin of error beneficial; I went with 50 Hz. However, set the  sample rate too low and you run into another problem: the time between samples may be so  great that the times when the signal is above the upper threshold or below the lower threshold  are missed completely. When you lower the sample rate, you need to lower your upper  threshold and raise your lower threshold; doing this too much can result in false positives from  things like signal noise. In order to ensure that the value above the upper threshold isn’t missed,  the difference between the potentiometer’s real maximum voltage and the upper threshold must  be at least equal to the time between samples (in my case, 0.02 seconds) times the maximum  rate of change of the voltage. The same must be true of the difference between the  potentiometer’s real minimum voltage and the lower threshold. I wound up using a  “real­threshold” voltage difference of 0.6V. To get false positives, the two thresholds have to be  pretty close; once again, big safety margins are your friend.    Code sample (enabling input filtering):    _analogTrigger​ .​ setFiltered​ (​ true​ );    Code sample (setting the thresholds):    double​  _sensingVoltageDifference ​ =​  ​ 0.6;  _analogTrigger​ .​ setLimitsVoltage​ (​ minVoltage ​ +​  _sensingVoltageDifference​ ,​  maxVoltage ​ ­  _sensingVoltageDifference​ );    Code sample (setting the sample rate):    int​  DEFAULT_ANALOG_MODULE ​ =​  ​ 1;  int​  ANALOG_SAMPLE_RATE ​ =​  ​ 50​ ;​  ​ //Hz  AnalogModule​  ​ module​  ​ =​  ​ (​ AnalogModule​ )​  ​ Module​ .​ getModule​ (​ ModulePresence​ .​ ModuleType​ .​ kAnalog​ ,  DEFAULT_ANALOG_MODULE​ );  module​ .​ setSampleRate​ (​ ANALOG_SAMPLE_RATE​ );    Computing the new degree measurement  The end goal of this is to create a potentiometer that reads beyond 360°. To get this reading,  simply multiply the turn count by 360° and add the wheel’s current heading.    Code sample (reading the new degree measurement):    double​  heading ​ =​  ​ (((​ voltage ​ ­​  _minVoltage​ )​  ​ *​  ​ (​ 360.0​  ​ /​  _maxVoltage​ )))​  ​ %​  ​ 360.0;  double​  degrees ​ =​  heading ​ +​  ​ (​ _turnCounter​ .​ get​ ()​  ​ *​  ​ 360.0​ );      Putting it all together  Here’s my final code. I don’t know if things need to be in this order (as opposed to the order  presented above) but it certainly works for me.         // Constants //  private​  ​ static​  ​ final​  ​ int​  ANALOG_SAMPLE_RATE ​ =​  ​ 50;  private​  ​ static​  ​ final​  ​ int​  DEFAULT_ANALOG_MODULE ​ =​  ​ 1​ ;    private​  ​ static​  ​ final​  ​ double​  _sensingVoltageDifference ​ =​  ​ 0.6;    // Global fields //  private​  ​ AnalogTrigger​  _analogTrigger;  private​  ​ Counter​  _turnCounter;  private​  ​ AnalogTriggerOutput​  _analogTriggerFalling;  private​  ​ AnalogTriggerOutput​  _analogTriggerRising;    // In potentiometer's constructor //  _analogTrigger ​ =​  ​ new​  ​ AnalogTrigger​ (​ channel​ );  _analogTrigger​ .​ setFiltered​ (​ true​ );  _analogTrigger​ .​ setLimitsVoltage​ (​ minVoltage ​ +​  _sensingVoltageDifference​ ,​  maxVoltage ​ ­  _sensingVoltageDifference​ );  _analogTriggerFalling ​ =​  ​ new​  ​ AnalogTriggerOutput​ (​ _analogTrigger​ ,  AnalogTriggerOutput​ .​ Type​ .​ kFallingPulse​ );  _analogTriggerRising ​ =​  ​ new​  ​ AnalogTriggerOutput​ (​ _analogTrigger​ ,  AnalogTriggerOutput​ .​ Type​ .​ kRisingPulse​ );    AnalogModule​  ​ module​  ​ =​  ​ (​ AnalogModule​ )​  ​ Module​ .​ getModule​ (​ ModulePresence​ .​ ModuleType​ .​ kAnalog​ ,  DEFAULT_ANALOG_MODULE​ );  module​ .​ setSampleRate​ (​ ANALOG_SAMPLE_RATE​ );      _turnCounter ​ =​  ​ new​  ​ Counter​ ();  _turnCounter​ .​ setUpDownCounterMode​ ();  _turnCounter​ .​ setUpSource​ (​ _analogTriggerRising​ );  _turnCounter​ .​ setDownSource​ (​ _analogTriggerFalling​ );  _turnCounter​ .​ start​ ();    // getDegrees() function //  double​  heading ​ =​  ​ (((​ voltage ​ ­​  _minVoltage​ )​  ​ *​  ​ (​ 360.0​  ​ /​  _maxVoltage​ )))​  ​ %​  ​ 360.0;  double​  degrees ​ =​  heading ​ +​  _offsetDegrees ​ +​  ​ (​ _turnCounter​ .​ get​ ()​  ​ *​  ​ 360.0​ );​  ​ //I have an  "offset" that allows me to compensate for potentiometers that aren't installed exactly  straight   

https://www.pdf-archive.com/2016/05/25/turncounterhowto/

25/05/2016 www.pdf-archive.com

CF 001 Tri-LFO 91%

SEGMENT PARAMETERS TIME TIME TIME 0.250s 0.250s +5.000v ABS MODE RANDOM SHAPE +- 0.00v LIN SHAPE 0 - LINEAR ABS +- --- ABS +- 0.00v LIN SHAPE 0 - LINEAR 0.00v LIN SHAPE 0 - LINEAR JUMP JUMP TARGET LEVEL REL TIME 0.000s ABS +- 0.00v LIN SHAPE 0 - LINEAR JUMP ABS +- 0.00v LIN SHAPE 0 - LINEAR JUMP ABS +- SHAPE 0 - LINEAR JUMP LEVEL +0.000v REL 0.00v LIN 0.000s LEVEL +0.000v REL TIME 0.000s LEVEL +0.000v REL TIME 0.000s LEVEL +0.000v REL TIME 0.000s LEVEL +0.000v -5.000v REL TIME 0.000s LEVEL LEVEL LEVEL TIME ABS +- 0.00v LIN SHAPE 0 - LINEAR JUMP +0.000v REL ABS +- REL 0.00v LIN SHAPE 0 - LINEAR JUMP JUMP TO S-1 --- --- --- --- --- --- CONDITION NEVER ALWAYS AT END NEVER NEVER NEVER NEVER NEVER NEVER CONDITION VALUE --- --- --- --- --- --- --- --- +5 +4 +3 +2 +1 0 -1 -2 S-1 S-2 S-3 S-4 S-5 S-6 S-7 S-8 -3 -4 -5 TRIGGER ASSIGNMENTS GLOBAL PRESETS GATE RISE START/RESET TRIGGER 1 OFF START LEVEL RESET TRIGGER 1 WIDTH --- RESET LEVEL -5.000v TRIGGER 2 OFF TRIGGER 2 WIDTH --- RESET RANDOM LEVEL +- 0.00v RESET RANDOM SHAPE LINEAR GATE FALL JUMP OFF FREE RUN ON CONTROL FORGE PRESET TEMPLATE NOTES FREE RUNNING TRIANGLE LFO Gate/Trig = Reset

https://www.pdf-archive.com/2017/01/17/cf-001-tri-lfo/

17/01/2017 www.pdf-archive.com

CF 002 ADSR 91%

SEGMENT PARAMETERS TIME TIME TIME 0.100s 0.050s +5.000v ABS MODE RANDOM SHAPE +- 0.00v LIN SHAPE 4 - EXPO 4 ABS +- --- ABS +- 0.00v LIN SHAPE 4 - EXPO 4 0.00v LIN SHAPE 0 - LINEAR JUMP JUMP TARGET LEVEL REL TIME 0.250s ABS +- 0.00v LIN SHAPE 4 - EXPO 4 JUMP ABS +- 0.00v LIN SHAPE 0 - LINEAR JUMP ABS +- LEVEL +0.000v REL 0.00v LIN SHAPE 0 - LINEAR JUMP 0.000s LEVEL +0.000v REL TIME 0.000s LEVEL +0.000v REL TIME 0.000s LEVEL +0.000v REL TIME 0.000s LEVEL +0.000v +2.500v REL TIME 0.000s LEVEL LEVEL LEVEL TIME ABS +- +0.000v REL 0.00v LIN SHAPE 0 - LINEAR JUMP ABS +- REL 0.00v LIN SHAPE 0 - LINEAR JUMP JUMP --- TO S-3 TO STOPPED --- --- --- --- CONDITION NEVER NEVER IF@END GATE HI ALWAYS AT END NEVER NEVER NEVER NEVER CONDITION VALUE --- --- --- --- --- --- --- --- +5 +4 +3 +2 +1 0 -1 -2 S-1 S-2 S-3 S-4 S-5 S-6 S-7 S-8 -3 -4 -5 TRIGGER ASSIGNMENTS GLOBAL PRESETS GATE RISE START/RESET TRIGGER 1 OFF START LEVEL RESET TRIGGER 1 WIDTH --- RESET LEVEL +0.000v TRIGGER 2 OFF TRIGGER 2 WIDTH --- RESET RANDOM LEVEL +- 0.00v RESET RANDOM SHAPE LINEAR GATE FALL JUMP S-4 FREE RUN OFF CONTROL FORGE PRESET TEMPLATE NOTES ADSR S-1 Time = Attack S-2 Time = Decay S-2 Level = Sustain S-4 Time = Release Adjust Envelope Peak with S-1 Level

https://www.pdf-archive.com/2017/01/17/cf-002-adsr/

17/01/2017 www.pdf-archive.com

CF 003 ADSR Fluctuating Sustain 91%

SEGMENT PARAMETERS TIME TIME TIME 0.100s 0.050s +5.000v ABS MODE RANDOM SHAPE +- 0.00v LIN SHAPE 4 - EXPO 4 ABS +- --- +- 0.00v LIN SHAPE 4 - EXPO 4 0.50v GAU SHAPE 0 - LINEAR JUMP JUMP TARGET ABS LEVEL REL ABS +- LEVEL REL 0.00v LIN SHAPE ABS +- LEVEL SHAPE 0 - LINEAR JUMP ABS +- 0.000s LEVEL LEVEL +0.000v REL 0.00v LIN SHAPE 0 - LINEAR JUMP TIME 0.000s +0.000v REL 0.00v LIN TIME 0.000s +0.000v 4 - EXPO 4 JUMP TIME 0.000s +0.000v +2.500v REL TIME 0.250s LEVEL +2.500v REL TIME 0.025s LEVEL LEVEL LEVEL TIME ABS +- 0.00v LIN SHAPE 0 - LINEAR JUMP +0.000v REL ABS +- REL 0.00v LIN SHAPE 0 - LINEAR JUMP JUMP --- TO S-3 TO STOPPED --- --- --- --- CONDITION NEVER NEVER IF@END GATE HI ALWAYS AT END NEVER NEVER NEVER NEVER CONDITION VALUE --- --- --- --- --- --- --- --- +5 +4 +3 +2 +1 0 -1 -2 S-1 S-2 S-3 S-4 S-5 S-6 S-7 S-8 -3 -4 -5 TRIGGER ASSIGNMENTS GLOBAL PRESETS GATE RISE START/RESET TRIGGER 1 OFF START LEVEL RESET TRIGGER 1 WIDTH --- RESET LEVEL +0.000v TRIGGER 2 OFF TRIGGER 2 WIDTH --- RESET RANDOM LEVEL +- 0.00v RESET RANDOM SHAPE LINEAR GATE FALL JUMP S-4 FREE RUN OFF CONTROL FORGE PRESET TEMPLATE NOTES ADSR S-1 Time = Attack S-2 Time = Decay S-2 Level, S-3 Level = Sustain S-3 Time = Fluctuation Frequency S-4 Time = Release Adjust Envelope Peak with S-1 Level

https://www.pdf-archive.com/2017/01/17/cf-003-adsr-fluctuating-sustain/

17/01/2017 www.pdf-archive.com

CF 004 S+H 91%

SEGMENT PARAMETERS TIME TIME TIME 0.000s 0.000s +0.000v ABS MODE RANDOM SHAPE +- 0.00v LIN SHAPE 63 - CV1 PASS ABS +- --- +- 0.00v LIN SHAPE 0.00v LIN SHAPE 0 - LINEAR 0 - LINEAR JUMP JUMP TARGET ABS ABS +- 0.00v LIN SHAPE 0 - LINEAR JUMP ABS +- 0.00v LIN SHAPE 0 - LINEAR JUMP ABS +- SHAPE 0 - LINEAR JUMP LEVEL +0.000v REL 0.00v LIN 0.000s LEVEL +0.000v REL TIME 0.000s LEVEL +0.000v REL TIME 0.000s LEVEL +0.000v REL TIME 0.000s LEVEL +0.000v REL TIME 0.000s LEVEL +0.000v REL TIME 0.000s LEVEL LEVEL LEVEL TIME ABS +- +0.000v REL 0.00v LIN SHAPE 0 - LINEAR JUMP ABS +- REL 0.00v LIN SHAPE 0 - LINEAR JUMP JUMP TO S-1 --- --- --- --- --- --- CONDITION NEVER WAIT 4 GATE RISE NEVER NEVER NEVER NEVER NEVER NEVER CONDITION VALUE --- --- --- --- --- --- --- --- +5 +4 +3 +2 +1 0 -1 -2 CV-1 S-1 S-2 S-3 S-4 S-5 S-6 S-7 S-8 PASSTHROUGH -3 -4 -5 TRIGGER ASSIGNMENTS GLOBAL PRESETS GATE RISE START/RESET TRIGGER 1 OFF START LEVEL RESET TRIGGER 1 WIDTH --- RESET LEVEL +0.000v TRIGGER 2 OFF TRIGGER 2 WIDTH --- RESET RANDOM LEVEL +- 0.00v RESET RANDOM SHAPE LINEAR GATE FALL JUMP OFF FREE RUN OFF CONTROL FORGE PRESET TEMPLATE NOTES SAMPLE and HOLD CV1 Input - Sample Source Gate/Trig - Trig

https://www.pdf-archive.com/2017/01/17/cf-004-s-h/

17/01/2017 www.pdf-archive.com

CF 005 HarmMinArp 91%

SEGMENT PARAMETERS TIME TIME TIME 0.000s 0.000s +0o +00s MODE ABS RANDOM SHAPE +- 0.00v LIN SHAPE 65 - CV3 PASS ABS +- ABS +- 0.00v LIN SHAPE 0 - LINEAR 0.00v LIN 0 - LINEAR JUMP JUMP SHAPE ABS +- 0.00v LIN SHAPE 0 - LINEAR JUMP ABS +- 0.00v LIN SHAPE 0 - LINEAR JUMP ABS +- LEVEL +0o +03s REL 0.00v LIN SHAPE 0 - LINEAR JUMP 0.000s LEVEL +0o +01s REL TIME 0.000s LEVEL +0o +02s REL TIME 0.000s LEVEL +0o +02s REL TIME 0.000s LEVEL +0o +01s REL TIME 0.000s LEVEL +0o +02s REL TIME 0.000s LEVEL LEVEL LEVEL TIME ABS +- +0o +01s REL 0.00v LIN SHAPE 0 - LINEAR JUMP ABS +- REL 0.00v LIN SHAPE 0 - LINEAR JUMP JUMP TO S-2 TO S-3 TO S-4 TO S-5 TO S-6 TO S-7 TO S-8 TO S-1 CONDITION WAIT 4 GATE RISE WAIT 4 GATE RISE WAIT 4 GATE RISE WAIT 4 GATE RISE WAIT 4 GATE RISE WAIT 4 GATE RISE WAIT 4 GATE RISE WAIT 4 LOGIC RISE CONDITION VALUE --- --- --- --- --- --- --- --- TARGET +1o 0 CV-3 PASSTHROUGH -1o TRIGGER ASSIGNMENTS GLOBAL PRESETS GATE RISE START/RESET TRIGGER 1 OFF START LEVEL RESET TRIGGER 1 WIDTH --- RESET LEVEL +0.000v TRIGGER 2 OFF TRIGGER 2 WIDTH --- RESET RANDOM LEVEL +- 0.00v RESET RANDOM SHAPE LINEAR GATE FALL JUMP OFF FREE RUN OFF CONTROL FORGE PRESET TEMPLATE NOTES Harmonic Minor Arp CV3 - Sets Root Note

https://www.pdf-archive.com/2017/01/17/cf-005-harmminarp/

17/01/2017 www.pdf-archive.com

CF Preset Template Blank 91%

SEGMENT PARAMETERS TIME TIME TIME TIME TIME TIME TIME TIME LEVEL LEVEL LEVEL LEVEL LEVEL LEVEL LEVEL LEVEL TIME LEVEL ABS MODE RANDOM +- REL SHAPE ABS +- REL ABS +- SHAPE SHAPE REL ABS +- REL SHAPE ABS +- SHAPE REL ABS +- REL SHAPE ABS +- SHAPE REL ABS +- REL SHAPE SHAPE JUMP JUMP JUMP JUMP JUMP JUMP JUMP JUMP TARGET CONDITION CONDITION VALUE +5 +4 +3 +2 +1 0 -1 -2 S-1 S-2 S-3 S-4 S-5 S-6 S-7 S-8 -3 -4 -5 GLOBAL PRESETS TRIGGER ASSIGNMENTS GATE RISE TRIGGER 1 START LEVEL TRIGGER 1 WIDTH RESET LEVEL TRIGGER 2 RESET RANDOM LEVEL RESET RANDOM SHAPE GATE FALL JUMP FREE RUN +- TRIGGER 2 WIDTH CONTROL FORGE PRESET TEMPLATE NOTES

https://www.pdf-archive.com/2017/01/17/cf-preset-template-blank/

17/01/2017 www.pdf-archive.com

CF Preset Template Form 91%

SEGMENT PARAMETERS TIME TIME TIME 0.000s 0.000s +0.000v ABS MODE RANDOM SHAPE +- 0.00v LIN SHAPE 0 - LINEAR ABS +- --- +- 0.00v LIN SHAPE 0 - LINEAR 0.00v LIN SHAPE 0 - LINEAR JUMP JUMP TARGET ABS ABS +- 0.00v LIN SHAPE 0 - LINEAR JUMP ABS +- 0.00v LIN SHAPE 0 - LINEAR JUMP ABS +- SHAPE 0 - LINEAR JUMP LEVEL +0.000v REL 0.00v LIN 0.000s LEVEL +0.000v REL TIME 0.000s LEVEL +0.000v REL TIME 0.000s LEVEL +0.000v REL TIME 0.000s LEVEL +0.000v REL TIME 0.000s LEVEL +0.000v REL TIME 0.000s LEVEL LEVEL LEVEL TIME ABS +- 0.00v LIN SHAPE 0 - LINEAR JUMP +0.000v REL ABS +- REL 0.00v LIN SHAPE 0 - LINEAR JUMP JUMP --- --- --- --- --- --- --- CONDITION NEVER NEVER NEVER NEVER NEVER NEVER NEVER NEVER CONDITION VALUE --- --- --- --- --- --- --- --- +5 +4 +3 +2 +1 0 -1 -2 S-1 S-2 S-3 S-4 S-5 S-6 S-7 S-8 -3 -4 -5 TRIGGER ASSIGNMENTS GLOBAL PRESETS GATE RISE START/RESET TRIGGER 1 OFF START LEVEL RESET TRIGGER 1 WIDTH --- RESET LEVEL +0.000v TRIGGER 2 OFF TRIGGER 2 WIDTH --- RESET RANDOM LEVEL +- 0.00v RESET RANDOM SHAPE LINEAR GATE FALL JUMP OFF FREE RUN OFF CONTROL FORGE PRESET TEMPLATE NOTES

https://www.pdf-archive.com/2017/01/17/cf-preset-template-form/

17/01/2017 www.pdf-archive.com

cf-401-CV3 5ths 91%

CONDITION VALUE -3.75v -2.50v -1.25v +0.00v +1.25v +2.50v +3.75v +5.00v TARGET REL +5 +4 +3 +2 +1 0 -1 -2 CV-3 CV-3 S-1 S-2 S-3 S-4 S-5 S-6 S-7 S-8 PASSTHROUGH PASSTHROUGH -3 -4 -5 TRIGGER ASSIGNMENTS GLOBAL PRESETS GATE RISE OFF TRIGGER 1 BEGIN ANY SEG START LEVEL CURRENT TRIGGER 1 WIDTH 10ms RESET LEVEL +0.000v TRIGGER 2 ANY JUMP TRIGGER 2 WIDTH 10ms RESET RANDOM LEVEL +- 0.00v RESET RANDOM SHAPE LINEAR GATE FALL JUMP OFF FREE RUN ON NOTES CF-Preset 401-CV3 5ths CV4 Knob = Sequence Steps 4 5 3 CONTROL FORGE PRESET TEMPLATE 6 2 7 1 8 CV4

https://www.pdf-archive.com/2017/01/24/cf-401-cv3-5ths/

24/01/2017 www.pdf-archive.com

cf-406-CV4 Reverse 91%

CONDITION VALUE +0.00v +0.00v +0.00v +0.00v +0.00v +0.00v +0.00v +0.00v TARGET REL +5 +4 +3 +2 +1 0 -1 -2 CV-3 CV-3 CV-3 CV-3 S-1 S-2 S-3 S-4 S-5 S-6 S-7 S-8 PASSTHROUGH PASSTHROUGH PASSTHROUGH PASSTHROUGH -3 -4 -5 GATE RISE OFF TRIGGER 1 BEGIN ANY SEG START LEVEL RESET TRIGGER 1 WIDTH 10ms RESET LEVEL +0.000v TRIGGER 2 BEGIN S-1 TRIGGER 2 WIDTH 10ms RESET RANDOM LEVEL +- 0.00v RESET RANDOM SHAPE LINEAR OFF FREE RUN ON CONTROL FORGE PRESET TEMPLATE CF-Preset 406-CV4 Reverse CV4 Knob = Sequence Direction FO E AR RW D GATE FALL JUMP NOTES REVERS TRIGGER ASSIGNMENTS GLOBAL PRESETS CV4

https://www.pdf-archive.com/2017/01/24/cf-406-cv4-reverse/

24/01/2017 www.pdf-archive.com

cf-Chaotic Direction 91%

ALWAYS AT END NEVER NEVER NEVER NEVER CONDITION VALUE -0.10v --- +0.10v --- --- --- --- --- TARGET REL +5 +4 +3 +2 +1 0 -1 -2 S-1 S-2 S-3 S-4 S-5 S-6 S-7 S-8 -3 -4 -5 TRIGGER ASSIGNMENTS GLOBAL PRESETS GATE RISE OFF TRIGGER 1 OFF START LEVEL CURRENT TRIGGER 1 WIDTH --- RESET LEVEL +0.000v TRIGGER 2 OFF TRIGGER 2 WIDTH --- RESET RANDOM LEVEL +- 0.00v RESET RANDOM SHAPE LINEAR GATE FALL JUMP OFF FREE RUN ON CONTROL FORGE PRESET TEMPLATE NOTES Chaotic Direction Mult CV2 source into a full wave rectifier and patch back into Time Scale CV.

https://www.pdf-archive.com/2017/01/24/cf-chaotic-direction/

24/01/2017 www.pdf-archive.com

lzxindustries visualcortex basic patches 90%

TRIGGERED TRANSITIONS In this patch, we’ll learn how to trigger automatic translations from Channel A to Channel B, and back again -- as well as vary the speed of the transitions.

https://www.pdf-archive.com/2015/02/20/lzxindustries-visualcortex-basic-patches/

20/02/2015 www.pdf-archive.com

Mueller 1998 90%

In section 3, I will argue that a unified analysis is possible despite these differences if we assume that shape conservation (Williams (1999)) can be a trigger for movement, in addition to feature checking (Chomsky (1995)).

https://www.pdf-archive.com/2011/02/27/mueller-1998/

27/02/2011 www.pdf-archive.com

Lecroy WaveRunner 62Xi.PDF 89%

Enhanced Understanding of Serial Data Signals Trigger on I2C, SPI, UART, or CAN serial data patterns.

https://www.pdf-archive.com/2016/02/15/lecroy-waverunner-62xi/

15/02/2016 www.pdf-archive.com

12Electronic Case Reporting 89%

Certification Criteria (i) Consume and maintain a table of trigger codes to determine which encounters may be reportable.

https://www.pdf-archive.com/2017/01/23/12electronic-case-reporting/

23/01/2017 www.pdf-archive.com

NPL SOP Project 89%

○ How to search for audiograms in the medical records ○ When to do a Stenger - TBI ○ ○ ○ ○ Triggered Exams TBI vs TBI Event Hearing loss due to acoustic trauma vs cranial nerve damage MMSE / MOCA test requirements - Psych ○ Diagnosing multiple conditions (how to complete section) Differentiation of symptoms questions PEP + UFQA Sessions Page 4 ○ ○ ○ ○ ○ Differentiation of symptoms questions Occupational / social impairment questions When / how to trigger PTSD Initial PTSD Diagnostic Criteria ECQ responses PEP + UFQA Sessions Page 5

https://www.pdf-archive.com/2016/09/29/npl-sop-project/

29/09/2016 www.pdf-archive.com

Abigail 88%

KIT INVENTORY Handheld 3d printer Wilderness Survival Kit Scope LANCER HP MAX 12 REPAIR RATE MECH Fomor PLAYER HK CHASIS Everest SIZE 1 3 EP/IP 8/5 STORAGE 3 WEAPONS CURRENT HP 12 HEAT MAX 10 NAME 20mm Hardpoint Anti-Material Rifle TYPE Heavy Rifle LOCATION Held EP/IP 3 DAMAGE 2d6+2 Kinetic RANGE 30 TAGS Ordinance, Loading NOTE NAME MC-BR TYPE Main Battle Rifle LOCATION Integrated (Chest) EP/IP 2/2 DAMAGE 1d6+1 Kinetic RANGE 15 TAGS Unreliable NOTE NAME TYPE LOCATION EP/IP DAMAGE RANGE TAGS NOTE NAME TYPE LOCATION EP/IP DAMAGE RANGE TAGS NOTE CURRENT HEAT 0 AIM ARMOR 0 0 HULL 0 AGILITY 0 SYSTEMS 1 ENGINEERING -1 INVENTORY MELEE +0 EVASION 8 SPEED 5 INVASION SCAN E-DEFENSE LOCK ON SENSOR RANGE 1 1 9 1 16 COOLING RATE REPAIR CAP STABILIZE 5 8 0 REACTIONS NAME NAME TRIGGER TRIGGER EFFECT EFFECT NAME NAME TRIGGER TRIGGER EFFECT EFFECT SYSTEMS &

https://www.pdf-archive.com/2018/04/26/abigail/

26/04/2018 www.pdf-archive.com