>************** void main(void) a int count; outpw(adr+wr0, 0x8000); //Software reset for(count = 0; count<2; ++count); command(0xf, 0xf); outpw(adr+wr1, 0x0000); 00000000 00000000 outpw(adr+wr2, 0x0000); 00000000 00000000 outpw(adr+wr3, 0x0000); 00000000 00000000 outpw(adr+wr4, 0x0000); 00000000 00000000 outpw(adr+wr5, 0x0024); 00000000 00100100 //-----Whole axis mode setting-------//Mode register 1 : //Mode register 2 : //Mode register 3 : //General output register //Interpolation mode register
//-----Initial value settings for whole axis driving accofst(0xf,0); //AO = 0 range(0xf, 800000) //R = 800000 (Multiple = 10) acac(0xf, 1010); //K = 1010 (Jerk = 619 KPPS/SEC2) acc(0xf, 100); //A = 100 (Acceleration/deceleration=125 KPPS/SEC) dec(0xf, 100); //D (Deceleration = 125 KPPS/SEC) startv(0xf, 100); //SV = 100 (Initial Speed = 1000 PPS) speed(0xf, 4000); //V = 40000 (Drive Speed = 40000 PPS) pulse(0xf, 100000); //P = 100000 (output pulse number = 100000) lp(0xf, 0); //LP = 0 (Logical position counter = 0) homesrch( ); //-----Home searching on whole axis-----
//-----Trapezoidal driving at X and Y axes acc(0x3, 200); (Acceleration/deceleration = 250KPPS/SEC) speed(0x3, 4000); //V = 4000(Drive Speed = 4000 PPS)
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pulse(0x1, 8000); //xP = 8000 pulse(0x2, 40000); //yP = 40000 command(0x3, 0x20); //- direction constant drive wait(0x3); //Wait for drive stop wreg3(0x3, 0x0004); //S-curve acceleration/deceleration driving at X and Y axes acac(0x3, 1010); //K = 1010 (S-curve Acceleration = 619 KPPS/SEC2) acc(0x3, 200); //A = 200 (Acceleration/Deceleration = 250 KPPS/SEC) speed(0x3, 4000); //V = 4000 (Drive Speed = 4000 PPS) pulse(0x1, 50000); //xP = 50000 pulse(0x2, 25000); //yP = 25000 command(0x0, 0x21); //- direction constant drive wait(0x3); wreg3(0x3, 0x0000); //S-curve acceleration/deceleration mode clearing //-----Linear interpolation drive at X and Y axis outpw(adr+wr5, 0x0124); //ax1 = x, ax2 = y, ax3 = z, linear speed keeps constant range(0x1, 800000); //ax1/R = 800000 (Multiple = 10) range(0x2, 1131371); //ax1/R = 800000 x 1.414 speed(0x1, 100); //Drive Speed = 1000 PPS constant speed pulse(0x1, 5000); //xP = +5000 (Finish point X = +5000) pulse(0x2, -2000); //yP = -2000 (Finish point Y = -2000) command90x0, 0x30); // 2-axis linear interpolation wait(0x3) //-----Circular interpolation drive at X and Y axes ----outpw(adr+wr5, 0x0124); //ax1 = x, ax2 = y, ax3 = z, linear speed keeps constant range(0x1, 800000); //ax1/R = 800000 (Multiple = 10) range(0x2, 1131371); //ax2/R = 800000 x 1.414 speed(0x1, 100); //Drive Speed = 1000 PPS constant speed center(0x1, -5000); //xC = 5000 (Center of X = -5000) center(0x2, 0); //yC = 0 (Center of Y = 0) pulse(0x1, 0); //xP = 0 (Finish point of X = 0) Circle pulse(0x2, 0); //yP = 0 (Finish point of Y = 0) command(0x0, 0x33); //CCW circular interpolation wait(0x3); //----- Bit pattern interpolation at X and Y axes-----//(Example of figure 2.24) speed(0x1,1); //Drive Speed = 10 PPS constant speed command(0, 0x36); //Bit pattern data writing permission outpw(adr+bp1p, 0x0000); //0 ~ 15 bits data writing outpw(adr+bp1m, 0x2bff); outpw(adr+bp2p, 0xffd4); outpw(adr+bp2m, 0x0000); command(0, 0x38); //Stack outpw(adr+bp1p, 0xf6fe); //16 ~ 31 bits data writing outpw(adr+bp1m, 0x0000); outpw(adr+bp2p, 0x000f); outpw(adr+bp2m, 0x3fc0); command(0, 0x38); outpw(adr+bp1p, 0x1fdb); //32 ~ 47 bits data writing outpw(adr+bp1m, 0x0000); outpw(adr+bp2p, 0x00ff); outpw(adr+bp2m, 0xfc00); command(0, 0x38); command(0, 0x38); bp_wait( ); //2-axis BP interpolation drive starting //Wait for data writing command(0,0x37); wait(0x3); // Bits pattern data writing inhibition //Wait for drive stop
//----- Continuous interpolation at X and Y axes (Example of figure 2.29) speed(0x1, 100); //Drive Speed = 10 PPS constant speed pulse(0x1, 4500); pulse(0x2, 0); command(0, 0x30); next_wait(); center(0x1,0); center(0x2, 1500); pulse(0x1, 1500); pulse(0x2, 1500); command(0, 0x33); next_wait(); pulse(0x1, 0); pulse(0x2, 1500); command(0, 0x30); next_wait(); center(0x1, -1500); center(0x2, 0); pulse(0x1, -1500); pulse(0x2, 1500); command(0, 0x33); next_wait(); pulse(0x1, -4500); pulse(0x2, 0); command(0, 0x30); next_wait(); center(0x1, 0); center(0x2, -1500); pulse(0x1, -1500); pulse(0x2, -1500); command(0, 0x33); next_wait(); pulse(0x1, 0); pulse(0x2, -1500); command(0, 0x30); next_wait(); center(0x1, 1500); center(0x2, 0); pulse(0x1, 1500); pulse(0x2, -1500); command(0, 0x33); wait(0x3); b // node 1
//Wait for next data setting // node 2
wat wtm w. D S .h a 4 U c o e
// node 3
// node 4
// node 5
// node 6
//node 7
//node 8
outpw(adr+bp1p, 0x1fdb); //48 ~ 63 bit3 data writing outpw(adr+bp1m, 0x0000); outpw(adr+bp2p, 0x00ff); outpw(adr+bp2m, 0xfc00); command(0, 0x38);
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12. Electrical Characteristics
12.1 DC Characteristics
n Absolute Maximum Rated Item Symbol Value Power Voltage VDD -0.3 ~ +7.0 Input voltage Input Current Reservation Temperature VIN IIN TSTG -0.3 ~ VDD+0.3 10 -40 ~ +125 Unit V V mA C n Recommend Operation Environment Item Symbol Value Power Voltage VDD 4.75 ~ 5.25
Ambient Temperature
Unit V C
Ta
0 ~ +85
If the user wishes to operate the IC below 0C, please make contact with our R&D engineer.
n DC Characteristics www..com
Item Mark High level input voltage VIH Low level input voltage VIL High level input current IIH Low level input current High level output voltage IIL Condition
(Ta = 0 ~ +85C, VDD = 5V O 5%)
Min. 22 -10 -10 -200 VDD-0.05 2.4 2.4 0.05 0.4 0.4 10 0.3 52 90 Typ. Max. 0.8 10 10 -10 Unit V V A A A V V V V V V A V mA D15~D0 Input signal Input signal besides D15~D0 Note 1 Output Signal besides D15~D0 D15~D0 Output signal Output signal besides D15~D0 D15~D0 output signal D15~D0, BUSYN, INTN Remark
VIN=VDD VIN=0V VIN=0V IOH=-1A IOH=-4 mA
VOH IOH=-8 mA IOL=1A IOL=4 mA IOL=8 mA VOUT=VDD or 0V IIO=0 mA, CLK=16 MHz
Low level output voltage Output leakage current
VOL
IOZ Smith hysteresis voltage VH Consuming current IDD
-10
Note1 : BUSYN and INTN output signals have no items for high level output voltage due to the open drain output. n Pin Capacity
Item Input/ Output capacity Input capacity Mark CIO CI Condition Ta=25C f=1 MHz Min. Typ. Max. 10 10 Unit Remark pF D15 ~ D0 pF Other input pins
12.2 AC Characteristics
12.2.1 Clock
n CLK Input Pulse
(Ta = 0 ~ +85C, VDD = 5V 5%, Output load condition: 85 pF + 1 TTL )
n SCLK Output Signal
CLK
CLK
tWH tCYC
tWL
SCLK tDR tDF
SCLK will not be output during reset. Symbol tCYC tWH tWL tDR tDF Item CLK Cycle CLK Hi Level Wavelength CLK Low Level Wavelength CLK SCLK Delay Time CLK SCLK Delay Time Min. 62.5 20 20 Max. Unit nS nS nS nS nS
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12.2.2 Read / Write Cycle
Read cycle
Valid Address
Write cycle
Valid Address
Data output. tCR
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Data input. tCW tAW tWW tDW tDH tWC tWA
tRD
tDF tRC tRA
tAR
The figure shown above is used for 16-bit data bus accessing (H16L8 = Hi). For 8-bit data bus (H16L8 = Low), the address signals shown in the figure become A3~A0, and data signals become D7~D0.
Symbol tAR tCR tRD tDF tRC tRA tAW tCW tWW tDW tDH tWC tWA
Item Address SETUP Time CSN SETUP Time Output Data Delay Time Output Data Reservation Time CSN Reservation Time Address Reservation Time Address SETUP Time Established Time for CSN (to RDN ) (to RDN ) (from RDN ) (from RDN ) (from RDN ) (from RDN ) (to WRN )
Min. 0 0
Max.
Unit nS nS nS nS nS nS nS nS nS nS nS nS nS
29 0 0 0 0 0 50 30 10 5 5 30
(to WRN ) WRN Low Level Wavelength Established Time for Input Data (to WRN ) Reservation Time for Input Data (from WRN ) CSN Reservation Time Address Reservation Time (from WRN ) (from WRN )
12.2.3 BUSYN Signal
tDF
tWL
It is low when BUSYN is active. And BUSYN is low after 2 SCLK cycles when WRN active.
Mark tDF tWL Item WRN BUSYN Delay Time BUSYN Low Level Wavelength Min. Max. 32 tCYC x 4+30 tCYC is a cycle of CLK. Unit nS nS
12.2.4 SCLK/Output Signal Timing
The following output single is synchronized with SCLK output signal. The level at ACLK will be changed. Output signals : nPP/PLS, nPM/DIR, nDRIVE, nASND, nDSND, nCMPP, and nCMPM.
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SCLK Output signal tDI
Mark tDD
Item SCLK Output Signal Delay Time
Min. 0
Max. 20
Unit nS
12.2.5 Input Pulses
n Quadrature Pulses Input Mode (A/B phases)
Counting up nECA nECB
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tDE tDE tDE tDE tDE tDE tDE tDE
Counting down
n Up/Down Pules Input Mode
nPPIN nPMIN
tDE tICYC tDE tIB tDE tICYC tDE
l In A/B quadrature pulse input mode, when nECA and nECB input pulses are changed, the value of real position counter will be changed to the value of those input pulses changed after the period of longest SCLK4 is passed. l In UP/DOWN pulse input mode, the real position counter will become the value of those input pulses changed, after the period between the beginning of nPPIN, nPMIN and the time of SCLK 4 cycle is passed.
Mark tDE tIH tIL tiCYC tIB Item nECA and nECB Phase Difference Time nPPIN and nPMIN Hi Level Wavelength nPPIN and nPMIN Low Level Wavelength nPPIN and nPMIN Cycle nPPIN nPMIN Time Min. tCYC x 2+20 30 30 tCYC x 2+20 tCYC x 2+20 Max. Unit nS nS nS nS nS
12.2.6 General Purpose Input / Output Signals
The figure shown at the lower left hand side illustrates the delay time when input signals nIN3 ~ 0, nEXPP, nEXPM, nINPOS, and nALARM are read through RR4 and RR5 registers. The figure shown at the lower right hand side illustrates the delay time when writing general output signal data into nWR3 and nWR4.
Input signal RDN D15~0 tDI WRN D15~0 nOUT7~0 tDO
Mark tDI tDO
Item Input Signal Data Delay Time WRN nOUT7~0 Established Time
Min.
Max. 32 32
Unit nS nS
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13. Timing of Input / Output Signals
13.1 Power-On Reset
VDD CLK RESETN SCLK BUSYN
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nPP/PLS nPP/DIR nDRIVE nOUT7~0
INTN
The reset signal input to pin RESETN will keep on the Low level for at least 4 CLK cycles. - When RESETN is on the Low level for 4 CLK cycles maximum, the output signals of MCX314 are decided. (R) SCLK will be output after 2 CLK cycles when RESTN return to the Hi level. BUSYN keeps on the Low level for 8 CLK cycles when RESTN is on the Hi level.
13.2 Fixed Pulse or Continuous Driving
SCLK WRN BUSYN Drive command write in
nPP, nPM, nPLS
1st pulse
2nd pulse
The final pulse
nDIR nDRIVE nASND, nDSND
Pre-state
valid level
valid level
This first driving pulses (nPP, nPM, and nPLS) will be output after 3 SCLK cycles when BUSYN is . - The nDIR (direction) signal is valid after 1 SCLK cycle when BUSYN is . (R) The dDRIVE becomes Hi level when BUSYN is . The nASND and nDSND are on invalid level after 3 SCLK cycles when BUSYN is .
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13.3 Interpolation
SCLK WRN BUSYN nPP, nPM, nPLS nDIR * 1st pulse valid level invalid 2nd pulse valid level invalid
invalid
nDRIVE
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The first pulses (nPP, nPM, and nPLS) of interpolation driving will be output after 4 SCLK cycles when BUSYN is . - nDRIVE will become Hi level after 1 SCLK cycle when BUSYN is . (R) DIR signal keeps the active level in 1 SCLK cycle before and after the Hi level pulse outputting.
13.4 Start Driving after Hold Command
SCLK WRN BUSYN
nPP, nPM, nPLS
1st pulse
2nd pulse
nDRIVE
The pulses (nPP, nPM, and nPLS) of each axis will start outputting after 3 SCLK cycles when BUSYN is . - nDRIVE will become Hi level when BUSYN is for each axis.
13.5 Sudden Stop
The following figure illustrates the timing of sudden stop. The sudden stop input signals are EMGN, nLMTP/M (When the sudden stop mode is engaged), and nALARM. When sudden stop input signal becomes active, or the sudden stop command is written, it will stop the output of pulses immediately. The width of external signals input for sudden stop must be more than 1 SCLK cycle. The stop function will not be active if the width is less 1 SCLK cycle.
SCLK Decelerating signal Decelerating command write in active
nPP, nPM, nPLS nDSND
13.6 Decelerating Stop
The following figure illustrates the timing of decelerating stop input signal and decelerating commands. The decelerating stop signal are nIN3 ~ 0 and nLMTP/M (When the decelerating mode is engaged) 74
MCX314 When speed decelerating signals become active, or the decelerating stop command is written, the decelerating stop function will be performed.
Decelerating signal Decelerating command write in active
nPP, nPM, nPLS nDSND
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14. Pinout
Unit: mm
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15. Specifications
n Control Axis n Data Bus 4 axes 16/8 bits selectable
Interpolation Functions
n 2-axes / 3-axes Linear Interpolation Interpolation Range Interpolation Speed Interpolation Accuracy n Circular Interpolation Interpolation Range www..com Interpolation Speed Interpolation Accuracy Each axis -8,388,608 ~ +8,388,607 1 ~ 4 MPPS 0.5 LSB (Within the range of whole interpolation)
Each axis -8,388,608 ~ +8,388,607 1 ~ 4 MPPS 1 LSB (Within the range of whole interpolation)
n 2 axes / 3 axes Bit Pattern Interpolation Interpolation Speed 1 ~ 4 MPPS (Dependent on CPU data writing time) n Related Functions of Interpolation lCan select any axis lConstant vector speed lContinuous interpolation lSingle step interpolation (Command/external signals)
Common Specifications of Each Axis
n Drive Pulses Output (When CLK = 16 MHz) Pulse Output Speed Range 1PPS ~ 4MPPS Pulse Output Accuracy within 0.1% (according to the setting speed) S-curve Jerk 954 ~ 31.25 N 9PPS/S2 10 Accelerating / Decelerating Speed 125 ~ 500 N 6PPS/S 10 Drive Speed 1 ~ 4 N 6 PPS 10 Output-pulse Number 0 ~ 268435455 / unlimited Speed Curve quadrature / trapezoidal / parabolic S-curve Index Drive Deceleration Mode auto / manual Output-pulse numbers and drive speeds changeable during the driving Independent 2-pulse system or 1-pulse 1-direction system selectable Logical levels of pulse selectable n Encoder Input A/B quadrature pulse style or Up/Down pulse style selectable Pulse of 1, 2 and 4 divisions selectable (A/B quadrature pulse style) n Position Counter Logic Position Counter (for output pulse t) range Real Position Counter (for feedback pulse) range Data read and write possible
-2,147,483,648 ~ +2,147,483,647 -2,147,483,648 ~ +2,147,483,647
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MCX314 n Comparison Register COMP + Register Position comparison range -2,147,483,648 ~ +2,147,483,647 COMP - Register Position comparison range -2,147,483,648 ~ +2,147,483,647 Status and signal outputs for the comparisons of position counters Software limit functioned n Interrupt (Interpolations Excluded) The factors of occurring interrupt: ..the drive-pulse outputting ..the start / finish of a constant-speed drive during the acceleration / deceleration driving ..the end of the driving ..the volume of position counter U volume of COMPthe ..the volume of position counter O volume of COMPthe www..com ..the volume of position counter U volume of COMP+ the ..the volume of position counter O volume of COMP+ the Enable / disable for these factors selectable n External Signal for Driving EXPP and EXPM signals for fixed pulse / continuous drive n External Deceleration / Sudden Stop Signal IN0 ~ 3 4 points for each axis Enable / disable and logical levels selectable n Servo Motor Input Signal ALARM (Alarm) INPOS (In Position Check) Enable / disable and logical levels selectable n General Output Signal OUT0 ~ 7 8 points for each axis (wherein 4 points use with drive status output signal pin) n Driving Status Signal Output ASND (speed accelerating), DSND (speed decelerating), CMPP (position U COMP+), CMPM (position O COMP-) Drive status and status registers readable n Limit Signals Input 2 points, for each + and - side Logical levels and decelerating / sudden stop selectable n Emergency Stop Signal Input EMG, 1 point for 4 axes n Electrical Characters Temperature Range for Driving Power Voltage for Driving Input / Output Signal Level Input Clock Pulse n Package
0 ~ +45C (32F ~185F) 5V 5 % (max. power consumption: 90mA) CMOS, TTL connectable 16,000 MHz (Standard) 144-pin plastic QFP, pitch = 0.65mm Dimension : 30.9 x 30.9 x 4.36 mm
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Appendix A: Speed Curve Profile
The following curves are based on the test records from MCX314 output drive pulses and speed curve traces. The complete S-curve acceleration / deceleration is the curve drive, without linear acceleration / deceleration, before the appointed drive speed is reached. Partial S-curve acceleration / deceleration is with a period of linear acceleration / deceleration before the appointed drive speed is reached.
n 40KPPS Full S-curve Acceleration / Deceleration R=800000 (Rate:10), K=700, A=D=200, SV=100, V=4000, A0=50 Auto Decelerating Mode 2 Jerk=893KPPS/ SEC Accel. / Decel. =250KPPS/SEC Initial Speed=1000PPS www..com Drive Speed=40KPPS Output Pulse P=50000 n 40KPPS Partial S-curve Acceleration / Deceleration R=800000 (Rate:10), K=300, A=D=150, SV=100, V=4000, A0=20 Auto Decelerating Mode 2 Jerk=2083KPPS/ SEC Accel. / Decel. =188KPPS/SEC Initial Speed=1000PPS Drive Speed=40KPPS Output Pulse P=50000
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n 8000PPS complete S-curve Acceleration / Deceleration R=8000000 (Rate:1), K=2000, A=D=500, SV=100, V=8000, A0=0 Auto Decelerating Mode Jerk=31KPPS/ SEC Accel. / Decel. =62.5KPPS/SEC Initial Speed=100PPS Drive Speed=8000PPS Output Pulse P=20000 Output Pulse P=20000
2
n 8000PPS Partial S-curve Acceleration / Deceleration R=800000 (Rate: 1), K=1000, A=D=100, SV=100, V=8000, A0=0 Auto Decelerating Mode Jerk=62.5KPPS/ SEC Accel. / Decel. =12.5KPPS/SEC Initial Speed=100PPS Drive Speed=8000PPS
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n 400KPPS Full S-curve Acceleration / Deceleration R=80000(Rate:100),K=2000,A=D=100,SV=10,V=4000, A0=1000 Auto Decelerating Mode Jerk=3.13MPPS/SEC Accel. / Decel. =1.25MPPS/SEC Initial Speed=1000PPS Drive Speed=400KPPS Output Pulse P=400000
2
n 400KPPS Partial S-curve Acceleration / Deceleration R=80000 (Rate: 100), K=500, A=D=100, SV=10, V=4000, A0=0 Auto Decelerating Mode Jerk=12.5MPPS/ SEC Accel. / Decel. =1.25MPPS/SEC Initial Speed=1000PPS Drive Speed=400KPPS Output Pulse P=400000
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n Speed Alterations in a Continuous S-curve Acceleration / Deceleration Drive R=800000 (Rate: 10), K=2000, A=D=100, SV=100, V=1000 / 2000 / 4000 / decelerating stop Jerk=312.5KPPS/ SEC Jerk(decel.)=125KPPS/SEC Initial Speed=1000PPS Drive Speed=10K / 20K / 40KPPS
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n 40KPPS Linear Acceleration / Deceleration
n Triangle wave Avoiding during the Linear Acceleration / Deceleration When K=1 (Jerk: Maxium) in the S-curve Accel./ Decel. Mode, " 1/4 output pulses" principle can be engaged. Even the output pulses are few, the drive is a trapezoidal drive. R=800000 (Rate: 10), K=1, A=D=100, SV=100, V=4000 WR3/D2, D1, D0=1, 0, 0 S-curve Mode, Auto Decelerating Mode Jerk =625MPPS/ SEC Accel./ Decel. =125KPPS/SEC Initial Speed=1000PPS Drive Speed=40000PPS Output Pulse P=40000
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R=800000 (Rate: 10), A=D=100, SV=100, V=4000 WR3/D2, D1, D0=0, 0, 0 Trapezoidal Mode, Auto Decelerating Mode Accel./ Decel. =125KPPS/ SEC Initial Speed=100PPS Drive Speed=40000PPS Output Pulse P=40000
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n Initial Speed Trailing during the S-curve Accel./ Decel. fixed pulse drive Try to adjust the volumes of parameters to have a more stable drive. R=800000 (Rate: 10), K=1000, A=D=8000, SV=100, V=2000, P=50000 Auto Decelerating Mode
R=800000 (Rate: 10), K+50, A=D=8000, SV=200, V=4000, A0=0, P=50000 Auto Decelerating Mode
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