Ad t pulse

REQ to new output data (with REQ-edge latching disabled) Output data valid to ACK (with REQ-edge latching disabled) (min) = 25 + programmable delay DIO 6533 User Manual t r*a* t ar t r*r t rr* t aa*... Page 78: Long-Pulse Mode Figures 5-16 Programmable Delay Send ACK Pulse Programmable Delay Wait Figure 5-16. Long-Pulse Mode Input 5-19 Chapter 5 Signal Timing 5-17 show long-pulse mode input Wait Space When 6533 Device Has Space For Data, Input Data* DIO 6533 User Manual... Page 79: Long-Pulse Mode Timing Specifications Pulse When REQ Unasserted * With REQ-edge latching enabled, the data written is delayed until the next inactive-going REQ edge. Long-Pulse Mode Timing Specifications Figures 5-18 DIO 6533 User Manual Initial State ACK Cleared Programmable Delay Send ACK Pulse Programmable... Page 80: Figure 5-18. Long-Pulse Mode Input Timing Description All timing values are in nanoseconds. Figure 5-18. Long-Pulse Mode Input Timing 5-21 Chapter 5 Signal Timing t adi Minimum Maximum — — — — — — — — — DIO 6533 User Manual... Page 81: Figure 5-19. Long-Pulse Mode Output Timing (with REQ-edge latching) REQ to new output data (with REQ-edge latching disabled) Output data valid to ACK (with REQ-edge latching disabled) (min) = 125 + programmable delay DIO 6533 User Manual t ar t r*r t rr* t aa* t doa Description All timing values are in nanoseconds. Page 82: Trailing-Edge Mode To slow down the handshake, you can specify a data-settling delay to increase the ACK pulse width and, therefore,

Of T (Time High). Page 158 LOGO! functions View in parameter assignment mode (example): TL =02:00s TH =03:00s Current pulse width T or T Ta =01:15s LOGO! Manual A5E00380835-01... Page 159: Asynchronous Pulse Generator LOGO! functions 4.4.7 Asynchronous pulse generator Short description The output pulse shape can be modified by reconfiguring the pulse/pause ratio. Symbol in Wiring Description LOGO! Input En You can use input EN to set and reset the asynchronous pulse generator. Input INV Input INV can be used to in- vert the output signal of the... Page 160 LOGO! functions Functional description You can configure the pulse/interpulse width at the T (Time High) and T (Time Low) parameters . Input Inv can be used to invert the output signal, provided the block is enabled with a signal at input EN. If retentivity is not set, output Q and the expired time are reset after a power failure. Page 161: Random Generator LOGO! functions 4.4.8 Random generator Short description The output of the random generator is set or reset within a configured time. Symbol in Wiring Description LOGO! Input En A positive edge ( 0 to 1 tran- sition) at input En (Enable) triggers the on-delay time of the random generator. Page 162 LOGO! functions Timing diagram The bold section of the timing diagram also appears in the symbol of the random generator. T is busy Functional description The 0 to 1 transition at input En triggers a random on-delay time between 0 s and T . Page 163: Stairway Lighting Switch LOGO! functions 4.4.9 Stairway lighting switch Short description An input edge triggers a configurable and retriggerable time. The output is reset after this time has expired. A warning signal can be output before this time has expired to warn of the impending shutdown. Symbol in Wiring

Jk = 0 if d jk ≤ T d jk if d jk 〉 T (13) Soft thresholding provides smoother results in comparison with the hard thresholding whereas thresholding technique provides better edge preservation in comparison with the soft thresholding technique.Soft thresholding and hard thresholding have some limitations in denoising of signal[29, 30]. The Equation 12 indicates that the reconstructed signal faces oscillation, since the estimated wavelet coefficients are not continuous at position ± T[31]. Although the estimated wavelet coefficients of Equation 13 have good continuity, these coefficients include constant errors[31], which directly influence the accuracy of the reconstructed signal.3.4 An improved threshold functionTo overcome the limitations of hard thresholding and soft thresholding denoising methods, an improved thresholding is proposed as follows: d ˜ jk = 0 if d jk 〈 T d jk + T e - t - 1 2 e - t + 1 if d jk ≥ T (14) Equation 14 improves the reconstruction precision, since it reduces the constant errors. Hence, it enhances the denoising effect. This thresholding function also assures the continuity of estimated wavelet coefficients.4 Simulation and performance assessmentThe denoising of the received radar signal is simulated in the presence of white Gaussian noise. The effect of signal parameter changes on the algorithm has been investigated. These parameters include the SNR of the signal. The SNR is defined as the ratio of the signal power to the noise power in the entire period. The following parameters are assumed: sampling frequency = 10 GHz, pulse duration = 8 ns, pulse repetition frequency = 0.24 GHz for the pulse radar (Figure 2) and transmitted frequency = 10 GHz for the continuous wave radar (Figure 3) The receiver receives the return from the targets in the present of AWGN.Figure 2The effect of pulse repetition frequency for the pulse radar. (a) Pulse radar transmitted signal. (b) Received signal (echo + noise), no attenuation. (c) Recovery signal from received signal by matched filter.Full size imageFigure 3The effect of pulse repetition frequency for the continuous wave radar. (a) Continuous wave radar transmitted signal. (b) Received signal (echo + noise),

Instruction list I00.01 PP00.01 PP00.01 O00.01 Signal course T = 1 cycle Behaviour of the progr. pulses after switching the controller on After switching the controller on (or after a RESET), the pulse has to be passed once at a value of 0 as the function cannot be guaranteed otherwise. Page 120: Pulse With Positive Signal Examples As opposed to the programmable pulses (see above) which are activated by edge reversals, the signal status is evaluated in the following two examples. This causes a different behavior when switching the control on. 6.7.3. Pulse with positive signal Circuit diagram Switching symbol Instruction list... Page 121: Pulse With Negative Signal Examples 6.7.4. Pulse with negative signal Circuit diagram Switching symbol Instruction list I00.03 SM15.14 M00.01 O00.03 SM15.14 M00.01 Signal course T = 1 cycle 6 - 19... Page 122: Software Timers Examples 6.8. Software timers 6.8.1. Impulse at startup Circuit diagram Switching symbol Instruction list L I00.01 = PT00.01:135*10ms:P L PT00.01 = O00.01 Signal course T= Time preselection (here: 1.35s) 6 - 20... Page 123: Impulse With Constant Duration Examples 6.8.2. Impulse with constant duration Circuit diagram Switching symbol Instruction list L I00.02 O PT00.02 = PT00.02:123*100ms:P L PT00.02 = O00.02 Signal course T= Time preselection (here: 12.3s) 6 - 21... Page 124: Raising Delay Examples 6.8.3. Raising delay Switching symbol Instruction list L I00.03 = PT00.03:185*10ms:R L PT00.03 = O00.03 Signal course T= Time preselection (here: 1.85s) 6 - 22... Page 125: Falling Delay Examples 6.8.4. Falling delay Switching symbol Instruction list L I00.04 = PT00.04:35*100ms:F L PT00.04 = O00.04 Signal course T= Time preselection (here: 3.5s) 6 - 23... Page 126: Impulse Generator With Pulse Output Examples 6.8.5. Impulse generator with pulse output Switching symbol Instruction list I00.05 O00.05 PT00.05:55*10ms:R PT00.05 O00.05 Signal course T1= Time preselection (here: 0.55s) T2=

You cannot shoot infinitely but need to replenish ammo at station. Ammo is cheap and usually it's more than enough for many fights. Missile – Missile Rack. There are heat seeking and dumbfire missiles and only defence against them now are Point Defence Turrets that are automated defence systems. The missiles do more damage to hull than shields. If enemy enters silent running mode missiles will fail to track it. Advantages are that heat seeking missiles will search for their target and doesn't require much skill to fire, thus being viable defence strategy for big trade ships. Disadvantage is high price and low total amount – too many enemies can drain your load very fast and leve defenseless. Missiles usually are used more for defence, last resort – when you are close to dying, or when enemy shields are down and you want to finish them fast. 116 Elite: Dangerous Pilot's Guide Weapon damage by distance 90 80 70 60 50 40 30 Time in seconds to take down Anacondas shields Large Beam Laser by distance – 100, 500, 1000, 1500, 2000 and 2500 meters 81 45 30 20 20 20 21 23 10 Distance, meters 0 0 250 500 750 1000 1250 Each test started with full shields and 0 PIPs to SYS 1500 1750 2000 2250 2500 2 Medium Beam lasers are stronger than 1 Large and 2 Small are stronger than 1 Medium, however, 2 weapons will need more power fropm power plant and will drain your capacitors faster. 117 Elite: Dangerous Pilot's Guide Weapon damage by distance 600 500 400 300 Time in seconds to take down Anacondas shields Weapon Damage in seconds by distance (500, 1000, 2000 and 2500 meters) 1000 meters Weapons do 17% less damage compared to 500 m. F – Fixed G – Gimbaled T – Turret 2000 meters Weapons do 129% less damage compared to 500 m. 2500 meters Weapons do 321% less damage compared to 500 m. PulseTC2 PulseTC3 BeamTC2 BeamTC3 PulseGC3 BeamFC2 PulseFC3 BurstFC3 200 BeamFC3 RailGunC2 100 Distance, meters 0 0 500 1000 Each test started with full shields and 0 PIPs to SYS 1500 2000 2500 118 Elite: Dangerous Pilot's Guide Weapon test against A7 Shields Weapons fired from 500m distance at anaconda (A7 Shields, 0 PIPs to SYS) RailGunC2 BeamFC3 BurstFC3 RailGunC1 PulseFC3 BeamFC2 PulseGC3 PulseFC2 BeamTC3 CannonFC4 Dumbfire BeamFC1 FragmentGC3 BurstFC1 PulseFC1 BeamTC2 BeamTC1 PulseTC3