В таблицата по-долу ще намерите пълен списък на конфигурационни променливи (CV) на декодиращото Lokommander Mini DCC. Ние препоръчваме да се променят стойностите по подразбиране, само ако знаете тяхната функция. Грешни настройки могат да имат негативен ефект цвете изпълнението на декодера, или може да предизвика не-очакваните действия на декодера към командите DCC, изпратени от командния станция. CV No. колона съдържа номера на конфигурационните променливи, а диапазонът Value съдържа валиден диапазон от стойности за всеки от автобиографиите. Колоната Default Value съдържа стойностите на фабричните настройки за всяка CV (след извършване на нулиране декодер всяка CV ще съдържа тази стойност). Описание Колоната ще ви даде кратко описание на всеки от автобиографиите. За да извършите нулиране декодер (в случай на грешни настройки CV), моля пишете на CV8 всяка числова стойност. NMRA 19x14x2 mm
CV Default Value Description
Value Range
1 3 0-127 Decoder Adresse Short, 7 bits
2 2 1-127 Vstart
3 5 0-63 Acceleration Rate 0=Fastest acceleration
4 7 0-63 Deceleration Rate 0=Fastest deceleration
5 100 1-127 Vhigh
6 60 0-127 Vmid, recommended value = [25%-75%] Vhigh
7 105 - Software Version (only readable)
8 78 - Manufactured ID/RESET (readable 78 = train-O-matic, any written value
will reset the decoder to the factory default values
9 3 0-9 Motor Control Algorithm, 0-8
User defined = 9 (see CV 60)
13 0 0-255 Analog Mode, Alternate Mode Function Status F1-F8
Bit 0 = 0(0): F1 not active in Analog mode
= 1(1): F1 active in Analog mode
Bit 1 = 0(0): F2 not active in Analog mode
= 1(2): F2 active in Analog mode
Bit 2 = 0(0): F3 not active in Analog mode
= 1(4): F3 active in Analog mode
Bit 3 = 0(0): F4 not active in Analog mode
= 1(: F4 active in Analog mode
Bit 4 = 0(0): F5 not active in Analog mode
= 1(16): F5 active in Analog mode
Bit 5 = 0(0): F6 not active in Analog mode
= 1(32): F6 active in Analog mode
Bit 6 = 0(0): F7 not active in Analog mode
= 1(64) F7 active in Analog mode
Bit 7 = 0(0): F8 not active in Analog mode
= 1(255): F8 active in Analog mode
143= 0-255 Analog Mode, Alternate Mode Function. Status F0f,F0r, F9-F14,
Bit 0 = 0(0): F0f not active in Analog mode
1+ = 1(1): F0f active in Analog mode
Bit 1 = 0(0): F0r not active in Analog mode
2 = 1(2): F0r active in Analog mode
Bit 2 = 0(0): F9 not active in Analog mode
= 1(4): F9 active in Analog mode
Bit 3 = 0(0): F10 not active in Analog mode
= 1(: F10 active in Analog mode
Bit 4 = 0(0): F11 not active in Analog mode
= 1(16): F11 active in Analog mode
Bit 5 = 0(0): F12 not active in Analog mode
= 1(32): F12 active in Analog mode
Bit 6 = 0(0): F13 not active in Analog mode
= 1(64) F13 active in Analog mode
Bit 7 = 0(0): F14 not active in Analog mode = 1(255): F14 active in Analog mode
150 0-7 LockValue: Enter the value to match Lock ID in CV16 to unlock CV
programming. No action and ACK will be performed by the decoder when
LockValue is different from LockID. In this situation only CV15 write is
allowed.
16 0 0-7 LockID: To prevent accidental programming use unique ID number for
decoders with same address (0..7) For example: 1-loco decoder, 2-sound
decoder, 3-function decoder, …
17 192 192-255 Extended Address, Address High
18 3 0-255 Extended Address, Address Low
19 0 0-127 Consist Address
If CV #19 > 0: Speed and direction is governed by this
consist address (not the individual address in CV #1 or
#17+18); functions are controlled by either the consist
address or individual address, see CV’s #21 + 22.
21 0 0-255 Functions defined here will be controlled by the consist address.
Bit 0 = 0(0): F1 controlled by individual address
= 1(1): …. by consist address
Bit 1 = 0(0): F2 controlled by individual address
= 1(2): …. by consist address
Bit 2 = 0(0): F3 controlled by individual address
= 1(4): …. by consist address
Bit 3 = 0(0): F4 controlled by individual address
= 1(: …. by consist address
Bit 4 = 0(0): F5 controlled by individual address
= 1(16): …. by consist address
Bit 5 = 0(0): F6 controlled by individual address
= 1(32): …. by consist address
Bit 6 = 0(0): F7 controlled by individual address
= 1(64): …. by consist address
Bit 7 = 0(0): F8 controlled by individual address
= 1(255): …. by consist address
22 0 0-63 Functions defined here will be controlled by the consist address.
Bit 0 = 0(0): F0 (forw.) controlled by individual address
= 1(1): …. by consist address
Bit 1 = 0 (0): F0 (rev.) controlled by individual address
= 1(2): …. by consist address
Bit 2 = 0(0): F9 controlled by individual address
= 1(4): …. by consist address
Bit 3 = 0(0): F10 controlled by individual address
= 1(: …. by consist address
Bit 4 = 0(0): F11 controlled by individual address
= 1(16): …. by consist address
Bit 5 = 0(0): F12 controlled by individual address
= 1(32): …. by consist address
27 0 0-7 Decoder Automatic Stopping Configuration
Bit 0 = 0(0): STOP/Zerospeed constant braking distance disabled
= 1(1): STOP/Zerospeed constant braking distance enabled
Bit 1 = 0 (0): IR sensor for constant braking distance disabled
= 1(2): IR sensor for constant braking distance enabled
Bit 2 = 0(0): DC Braking disabled
= 1(4): DC Braking enabled
29 6= 0-63 Configuration Data
Bit 0 = 0(0): Locomotive Direction normal
= 1(1): Locomotive Direction reversed
Bit 1 = 0(0): 14 speed steps
2+ = 1(2): 28 /128 speed steps
Bit 2 = 0(0): Power Source Conversion NMRA Digital Only (only DCC)
4 = 1(4): Power Source Conversion Enabled (DC + DCC)
Bit 3-Not available
Bit 4 = 0(0): speed table set by configuration variables #2,#5, and #6
= 1(32): Speed Table set by configuration variables #66-#95
Bit 5 = 0(0): one byte addressing (short addressing)
= 1(64): two byte addressing (extended/long addressing)
Bit 6 -Not available
Bit 7 -Not available
30 0 0-7 Error CV. If the read out value is “1”, an overcurrent event occurred since
the last reset. The value can be cleared with programming “0” to CV30
Error Information (combination of each case is possible):
0-No error
1-Motor Short Protection
2-Aux Output Short Protection
4-Overtemperature
33 1= 0-15 F0, Forward move mapping
Bit 0 = 0(0): Out1 not active on F0 forward
1 = 1(1): Out1 active on F0 forward
Bit 1 = 0(0): Out2 not active on F0 forward
= 1(2): Out2 active on F0 forward
Bit 2 = 0(0): Out3 not active on F0 forward
= 1(4): Out3 active on F0 forward
Bit 3 = 0(0): Out4 not active on F0 forward
= 1(: Out4 active on F0 forward
34 2= 0-15 F0, Backward move mapping
Bit 0 = 0(0): Out1 not active on F0 backward
= 1(1): Out1 active on F0 backward
Bit 1 = 0(0): Out2 not active on F0 backward
2 = 1(2): Out2 active on F0 backward
Bit 2 = 0(0): Out3 not active on F0 backward
= 1(4): Out3 active on F0 backward
Bit 3 = 0(0): Out4 not active on F0 backward
= 1(: Out4 active on F0 backward
35 4= 0-15 F1, Forward move mapping
Bit 0 = 0(0): Out1 not active on F1 forward
= 1(1): Out1 active on F1 forward
Bit 1 = 0(0): Out2 not active on F1 forward
= 1(2): Out2 active on F1 forward
Bit 2 = 0(0): Out3 not active on F1 forward
4 = 1(4): Out3 active on F1 forward
Bit 3 = 0(0): Out4 not active on F1 forward
= 1(: Out4 active on F1 forward
36 4= 0-255 F1, Backward move mapping
Bit 0 = 0(0): Out1 not active on F1 backward
= 1(1): Out1 active on F1 backward
Bit 1 = 0(0): Out2 not active on F1 backward
= 1(2): Out2 active on F1 backward
Bit 2 = 0(0): Out3 not active on F1 backward
4 = 1(4): Out3 active on F1 backward
Bit 3 = 0(0): Out4 not active on F1 backward
= 1(: Out4 active on F1 backward
37 8= 0-255 F2 mapping
Bit 0 = 0(0): Out1 not active on F2
= 1(1): Out1 active on F2
Bit 1 = 0(0): Out2 not active on F2
= 1(2): Out2 active on F2
Bit 2 = 0(0): Out3 not active on F2
= 1(4): Out3 active on F2
Bit 3 = 0(0): Out4 not active on F2
8 = 1(: Out4 active on F2
38 0 0-255 F3 mapping
Bit 0 = 0(0): Out1 not active on F3
= 1(1): Out1 active on F3
Bit 1 = 0(0): Out2 not active on F3
= 1(2): Out2 active on F3
Bit 2 = 0(0): Out3 not active on F3
= 1(4): Out3 active on F3
Bit 3 = 0(0): Out4 not active on F3
= 1(: Out4 active on F3
39 0 0-255 F4 mapping
Bit 0 = 0(0): Out1 not active on F4
= 1(1): Out1 active on F4
Bit 1 = 0(0): Out2 not active on F4
= 1(2): Out2 active on F4
Bit 2 = 0(0): Out3 not active on F4
= 1(4): Out3 active on F4
Bit 3 = 0(0): Out4 not active on F4
= 1(: Out4 active on F4
40 0 0-255 F5 mapping
Bit 0 = 0(0): Out1 not active on F5
= 1(1): Out1 active on F5
Bit 1 = 0(0): Out2 not active on F5
= 1(2): Out2 active on F5
Bit 2 = 0(0): Out3 not active on F5
= 1(4): Out3 active on F5
Bit 3 = 0(0): Out4 not active on F5
= 1(: Out4 active on F5
41 0 0-255 F6 mapping
Bit 0 = 0(0): Out1 not active on F6
= 1(1): Out1 active on F6
Bit 1 = 0(0): Out2 not active on F6
= 1(2): Out2 active on F6
Bit 2 = 0(0): Out3 not active on F6
= 1(4): Out3 active on F6
Bit 3 = 0(0): Out4 not active on F6
= 1(: Out4 active on F6
42 0 0-255 F7 mapping
Bit 0 = 0(0): Out1 not active on F7
= 1(1): Out1 active on F7
Bit 1 = 0(0): Out2 not active on F7
= 1(2): Out2 active on F7
Bit 2 = 0(0): Out3 not active on F7
= 1(4): Out3 active on F7
Bit 3 = 0(0): Out4 not active on F7
= 1(: Out4 active on F7
43 0 0-255 F8 mapping
Bit 0 = 0(0): Out1 not active on F8
= 1(1): Out1 active on F8
Bit 1 = 0(0): Out2 not active on F8
= 1(2): Out2 active on F8
Bit 2 = 0(0): Out3 not active on F8
= 1(4): Out3 active on F8
Bit 3 = 0(0): Out4 not active on F8
= 1(: Out4 active on F8
44 0 0-255 F9 / F13 mapping
Bit 0 = 0(0): Out1 not active on F9
= 1(1): Out1 active on F9
Bit 1 = 0(0): Out2 not active on F9
= 1(2): Out2 active on F9
Bit 2 = 0(0): Out3 not active on F9
= 1(4): Out3 active on F9
Bit 3 = 0(0): Out4 not active on F9
= 1(: Out4 active on F9
Bit 4 = 0(0): Out1 not active on F13
= 1(16): Out1 active on F13
Bit 5 = 0(0): Out2 not active on F13
= 1(32): Out2 active on F13
Bit 6 = 0(0): Out3 not active on F13
= 1(64): Out3 active on F13
Bit 7 = 0(0): Out4 not active on F13
= 1(128): Out4 active on F13
45 0 0-255 F10 / F14 mapping
Bit 0 = 0(0): Out1 not active on F10
1(1): Out1 active on F10
Bit 1 = 0(0): Out2 not active on F10
= 1(2): Out2 active on F10
Bit 2 = 0(0): Out3 not active on F10
= 1(4): Out3 active on F10
Bit 3 = 0(0): Out4 not active on F10
= 1(: Out4 active on F10
Bit 4 = 0(0): Out1 not active on F14
= 1(16):Out1 active on F14
Bit 5 = 0(0): Out2 not active on F14
= 1(32):Out2 active on F14
Bit 6 = 0(0): Out3 not active on F14
= 1(64):Out3 active on F14
Bit 7 = 0(0): Out4 not active on F14
= 1(128): Out4 active on F14
46 0 0-255 F11 / F15 mapping
Bit 0 = 0(0): Out1 not active on F11
= 1(1): Out1 active on F11
Bit 1 = 0(0): Out2 not active on F11
= 1(2): Out2 active on F11
Bit 2 = 0(0): Out3 not active on F11
= 1(4): Out3 active on F11
Bit 3 = 0(0): Out4 not active on F11
= 1(: Out4 active on F11
Bit 4 = 0(0): Out1 not active on F15
= 1(16):Out1 active on F15
Bit 5 = 0(0): Out2 not active on F15
= 1(32):Out2 active on F15
Bit 6 = 0(0): Out3 not active on F15
= 1(64):Out3 active on F15
Bit 7 = 0(0): Out4 not active on F15
= 1(128): Out4 active on F15
47 0 0-255 F12 / F16 mapping
Bit 0 = 0(0): Out1 not active on F12
= 1(1): Out1 active on F12
Bit 1 = 0(0): Out2 not active on F12
= 1(2): Out2 active on F12
Bit 2 = 0(0): Out3 not active on F12
= 1(4): Out3 active on F12
Bit 3 = 0(0): Out4 not active on F12
= 1(: Out4 active on F12
Bit 4 = 0(0): Out1 not active on F16
= 1(16):Out1 active on F16 Bit 5 = 0(0): Out2 not active on F16
= 1(32):Out2 active on F16 Bit 6 = 0(0): Out3 not active on F16
= 1(64):Out3 active on F16 Bit 7 = 0(0): Out4 not active on F16
= 1(128): Out4 active on F16
48 255 0-255 Out 1 Light intensity, [1-255] , 0-continous
49 255 0-255 Out 2 Light intensity, [1-255] , 0-continous
50 255 0-255 Out 3 Light intensity, [1-255] , 0-continous
51 255 0-255 Out 4 Light intensity, [1-255] , 0-continous
60 3 0-7 and Motor, Back EMF measurement Delay
128-135 value of 0 or 128 swithes BackEMF Off, value>0 or > 128 changes the
BEMF measurement Delay. Delay(ms)=0.75+CV Value*0.25
Bit7=0 uses 32kHz PWM (CV range 0-7)
Bit7=1 uses 16kHz PWM ( CV range 128-135)
61 80 0-255 PID P constant
62 120 0-255 PID I constant
63 40 0-255 PID D constant
64 0 0-15 Brake Distance configuration
0-No brake
1-15 Braking rate, the CV value influences the Constant Braking Distance,
CV64=1 means the Shortest Braking Distance from maximum Speed to
STOP. Increase the CV value to increase the braking distance.
Distance=Value * Shortest Breaking Distance
65 25 0-255 Brake Delay
CV65= 0 means no Brake Delay. To increase breaking distance above the
value configured in CV64, increase in small amounts the value of CV65,
which will delay the start of the braking, resulting in a longer braking path.
Brake Delay = CV65 Value * 8ms (ms)
Extra Distance = MaxSpeed * BrakeDelay
Ex: 200ms(delay)=8(ms)*25(CV value)
67 2 1-127 Speed Table 1-28 ST[1] 1 position speed value
….. Throttle position speed mapping values, ex. 1 position=2 speed, 28
position=120 speed
94 120 1-127 ST[28], 28 position speed value
105 0 0-255 USER data, freely configurable. It is not cleared after a decoder reset
106 0 0-255 USER data, freely configurable. It is not cleared after a decoder reset
112 15 1-127 Fade ON effect on outputs, ex.:1=8ms, 15=120ms 125=1000ms
113 3 1-127 Fade OFF effect on outputs, ex.:1=8ms, 15=120ms 125=1000ms
114 4 0-255 Shunting speed, Function mapping F1-F8, F3 default (bit 0 is mapping F1,
bit 7 is mapping F8). Mapping is possible only for F1-F8
115 8 0-255 Switch Off Acceleration Deceleration, Function mapping, F4 default (bit 0
is mapping F1, bit 7 is mapping F8). Mapping is possible only for F1-F8
116 16 0-255 Disable Constant Braking, Function mapping, F5 default (bit 0 is mapping
F1, bit 7 is mapping F8). Mapping is possible only for F1-F8
117 0 0-15 Bit 0 = 0(0): Out1 could be dimmed and faded
= 1(1): continues signal with no fading on Out1
Bit 1 = 0(0): Out2 could be dimmed and faded
= 1(2): continues signal with no fading on Out2
Bit 2 = 0(0): Out3 could be dimmed and faded
= 1(4): continues signal with no fading on Out3
Bit 3 = 0(0): Out4 could be dimmed and faded
= 1(: continues signal with no fading on Out4
118 0 0-4 Electrical Coupler Output mapping for AUX 1-4 outputs. Only one of the
AUX outputs can be configured as ECoupler Output
CV118 = 0, None of the AUX selected for ECoupler operation
CV118 = 1, AUX1 selected for ECoupler operation
CV118 = 2, AUX2 selected for ECoupler operation
CV118 = 3, AUX3 selected for ECoupler operation
CV118 = 4, AUX4 selected for ECoupler operation
119 50 0-255 Electrical Coupler, Kick_time = Val*8ms, ex: 400ms=50*8ms
120 50 0-255 Decoupling, Locomotive move Time=Val*8ms, ex: 400ms=50*8ms
121 50 0-255 Decoupling Locomotive moving speed
122 0 0-1 Second Config, bit 0 0-LocoWire, 1-SUSI
123 16 0-255 SPP (Smart Power Pack) Timeout=16ms*Value Ex: =16ms*16=256ms
124 0 0-1 ECoupler Mode
CV124 = 0, PWM Output
CV124 = 1, Full Output on selected AUX in CV118
126 102 0-255 SUSI CV transport, SUSI CV=800+Value
127 0 0-255 SUSI DATA transport, Data write to CV=800+cv126
133 Chip temperature read out (the value is expressed in degrees Celsius. The
precision of the readout is +/- 2 degrees). Prior to the readout the F5
function must be switched On and Off
134 100 60-120 Temperature Limit for the temperature protection (value in degrees
Celsius)
CV Default Value Description
Value Range
1 3 0-127 Decoder Adresse Short, 7 bits
2 2 1-127 Vstart
3 5 0-63 Acceleration Rate 0=Fastest acceleration
4 7 0-63 Deceleration Rate 0=Fastest deceleration
5 100 1-127 Vhigh
6 60 0-127 Vmid, recommended value = [25%-75%] Vhigh
7 105 - Software Version (only readable)
8 78 - Manufactured ID/RESET (readable 78 = train-O-matic, any written value
will reset the decoder to the factory default values
9 3 0-9 Motor Control Algorithm, 0-8
User defined = 9 (see CV 60)
13 0 0-255 Analog Mode, Alternate Mode Function Status F1-F8
Bit 0 = 0(0): F1 not active in Analog mode
= 1(1): F1 active in Analog mode
Bit 1 = 0(0): F2 not active in Analog mode
= 1(2): F2 active in Analog mode
Bit 2 = 0(0): F3 not active in Analog mode
= 1(4): F3 active in Analog mode
Bit 3 = 0(0): F4 not active in Analog mode
= 1(: F4 active in Analog mode
Bit 4 = 0(0): F5 not active in Analog mode
= 1(16): F5 active in Analog mode
Bit 5 = 0(0): F6 not active in Analog mode
= 1(32): F6 active in Analog mode
Bit 6 = 0(0): F7 not active in Analog mode
= 1(64) F7 active in Analog mode
Bit 7 = 0(0): F8 not active in Analog mode
= 1(255): F8 active in Analog mode
143= 0-255 Analog Mode, Alternate Mode Function. Status F0f,F0r, F9-F14,
Bit 0 = 0(0): F0f not active in Analog mode
1+ = 1(1): F0f active in Analog mode
Bit 1 = 0(0): F0r not active in Analog mode
2 = 1(2): F0r active in Analog mode
Bit 2 = 0(0): F9 not active in Analog mode
= 1(4): F9 active in Analog mode
Bit 3 = 0(0): F10 not active in Analog mode
= 1(: F10 active in Analog mode
Bit 4 = 0(0): F11 not active in Analog mode
= 1(16): F11 active in Analog mode
Bit 5 = 0(0): F12 not active in Analog mode
= 1(32): F12 active in Analog mode
Bit 6 = 0(0): F13 not active in Analog mode
= 1(64) F13 active in Analog mode
Bit 7 = 0(0): F14 not active in Analog mode = 1(255): F14 active in Analog mode
150 0-7 LockValue: Enter the value to match Lock ID in CV16 to unlock CV
programming. No action and ACK will be performed by the decoder when
LockValue is different from LockID. In this situation only CV15 write is
allowed.
16 0 0-7 LockID: To prevent accidental programming use unique ID number for
decoders with same address (0..7) For example: 1-loco decoder, 2-sound
decoder, 3-function decoder, …
17 192 192-255 Extended Address, Address High
18 3 0-255 Extended Address, Address Low
19 0 0-127 Consist Address
If CV #19 > 0: Speed and direction is governed by this
consist address (not the individual address in CV #1 or
#17+18); functions are controlled by either the consist
address or individual address, see CV’s #21 + 22.
21 0 0-255 Functions defined here will be controlled by the consist address.
Bit 0 = 0(0): F1 controlled by individual address
= 1(1): …. by consist address
Bit 1 = 0(0): F2 controlled by individual address
= 1(2): …. by consist address
Bit 2 = 0(0): F3 controlled by individual address
= 1(4): …. by consist address
Bit 3 = 0(0): F4 controlled by individual address
= 1(: …. by consist address
Bit 4 = 0(0): F5 controlled by individual address
= 1(16): …. by consist address
Bit 5 = 0(0): F6 controlled by individual address
= 1(32): …. by consist address
Bit 6 = 0(0): F7 controlled by individual address
= 1(64): …. by consist address
Bit 7 = 0(0): F8 controlled by individual address
= 1(255): …. by consist address
22 0 0-63 Functions defined here will be controlled by the consist address.
Bit 0 = 0(0): F0 (forw.) controlled by individual address
= 1(1): …. by consist address
Bit 1 = 0 (0): F0 (rev.) controlled by individual address
= 1(2): …. by consist address
Bit 2 = 0(0): F9 controlled by individual address
= 1(4): …. by consist address
Bit 3 = 0(0): F10 controlled by individual address
= 1(: …. by consist address
Bit 4 = 0(0): F11 controlled by individual address
= 1(16): …. by consist address
Bit 5 = 0(0): F12 controlled by individual address
= 1(32): …. by consist address
27 0 0-7 Decoder Automatic Stopping Configuration
Bit 0 = 0(0): STOP/Zerospeed constant braking distance disabled
= 1(1): STOP/Zerospeed constant braking distance enabled
Bit 1 = 0 (0): IR sensor for constant braking distance disabled
= 1(2): IR sensor for constant braking distance enabled
Bit 2 = 0(0): DC Braking disabled
= 1(4): DC Braking enabled
29 6= 0-63 Configuration Data
Bit 0 = 0(0): Locomotive Direction normal
= 1(1): Locomotive Direction reversed
Bit 1 = 0(0): 14 speed steps
2+ = 1(2): 28 /128 speed steps
Bit 2 = 0(0): Power Source Conversion NMRA Digital Only (only DCC)
4 = 1(4): Power Source Conversion Enabled (DC + DCC)
Bit 3-Not available
Bit 4 = 0(0): speed table set by configuration variables #2,#5, and #6
= 1(32): Speed Table set by configuration variables #66-#95
Bit 5 = 0(0): one byte addressing (short addressing)
= 1(64): two byte addressing (extended/long addressing)
Bit 6 -Not available
Bit 7 -Not available
30 0 0-7 Error CV. If the read out value is “1”, an overcurrent event occurred since
the last reset. The value can be cleared with programming “0” to CV30
Error Information (combination of each case is possible):
0-No error
1-Motor Short Protection
2-Aux Output Short Protection
4-Overtemperature
33 1= 0-15 F0, Forward move mapping
Bit 0 = 0(0): Out1 not active on F0 forward
1 = 1(1): Out1 active on F0 forward
Bit 1 = 0(0): Out2 not active on F0 forward
= 1(2): Out2 active on F0 forward
Bit 2 = 0(0): Out3 not active on F0 forward
= 1(4): Out3 active on F0 forward
Bit 3 = 0(0): Out4 not active on F0 forward
= 1(: Out4 active on F0 forward
34 2= 0-15 F0, Backward move mapping
Bit 0 = 0(0): Out1 not active on F0 backward
= 1(1): Out1 active on F0 backward
Bit 1 = 0(0): Out2 not active on F0 backward
2 = 1(2): Out2 active on F0 backward
Bit 2 = 0(0): Out3 not active on F0 backward
= 1(4): Out3 active on F0 backward
Bit 3 = 0(0): Out4 not active on F0 backward
= 1(: Out4 active on F0 backward
35 4= 0-15 F1, Forward move mapping
Bit 0 = 0(0): Out1 not active on F1 forward
= 1(1): Out1 active on F1 forward
Bit 1 = 0(0): Out2 not active on F1 forward
= 1(2): Out2 active on F1 forward
Bit 2 = 0(0): Out3 not active on F1 forward
4 = 1(4): Out3 active on F1 forward
Bit 3 = 0(0): Out4 not active on F1 forward
= 1(: Out4 active on F1 forward
36 4= 0-255 F1, Backward move mapping
Bit 0 = 0(0): Out1 not active on F1 backward
= 1(1): Out1 active on F1 backward
Bit 1 = 0(0): Out2 not active on F1 backward
= 1(2): Out2 active on F1 backward
Bit 2 = 0(0): Out3 not active on F1 backward
4 = 1(4): Out3 active on F1 backward
Bit 3 = 0(0): Out4 not active on F1 backward
= 1(: Out4 active on F1 backward
37 8= 0-255 F2 mapping
Bit 0 = 0(0): Out1 not active on F2
= 1(1): Out1 active on F2
Bit 1 = 0(0): Out2 not active on F2
= 1(2): Out2 active on F2
Bit 2 = 0(0): Out3 not active on F2
= 1(4): Out3 active on F2
Bit 3 = 0(0): Out4 not active on F2
8 = 1(: Out4 active on F2
38 0 0-255 F3 mapping
Bit 0 = 0(0): Out1 not active on F3
= 1(1): Out1 active on F3
Bit 1 = 0(0): Out2 not active on F3
= 1(2): Out2 active on F3
Bit 2 = 0(0): Out3 not active on F3
= 1(4): Out3 active on F3
Bit 3 = 0(0): Out4 not active on F3
= 1(: Out4 active on F3
39 0 0-255 F4 mapping
Bit 0 = 0(0): Out1 not active on F4
= 1(1): Out1 active on F4
Bit 1 = 0(0): Out2 not active on F4
= 1(2): Out2 active on F4
Bit 2 = 0(0): Out3 not active on F4
= 1(4): Out3 active on F4
Bit 3 = 0(0): Out4 not active on F4
= 1(: Out4 active on F4
40 0 0-255 F5 mapping
Bit 0 = 0(0): Out1 not active on F5
= 1(1): Out1 active on F5
Bit 1 = 0(0): Out2 not active on F5
= 1(2): Out2 active on F5
Bit 2 = 0(0): Out3 not active on F5
= 1(4): Out3 active on F5
Bit 3 = 0(0): Out4 not active on F5
= 1(: Out4 active on F5
41 0 0-255 F6 mapping
Bit 0 = 0(0): Out1 not active on F6
= 1(1): Out1 active on F6
Bit 1 = 0(0): Out2 not active on F6
= 1(2): Out2 active on F6
Bit 2 = 0(0): Out3 not active on F6
= 1(4): Out3 active on F6
Bit 3 = 0(0): Out4 not active on F6
= 1(: Out4 active on F6
42 0 0-255 F7 mapping
Bit 0 = 0(0): Out1 not active on F7
= 1(1): Out1 active on F7
Bit 1 = 0(0): Out2 not active on F7
= 1(2): Out2 active on F7
Bit 2 = 0(0): Out3 not active on F7
= 1(4): Out3 active on F7
Bit 3 = 0(0): Out4 not active on F7
= 1(: Out4 active on F7
43 0 0-255 F8 mapping
Bit 0 = 0(0): Out1 not active on F8
= 1(1): Out1 active on F8
Bit 1 = 0(0): Out2 not active on F8
= 1(2): Out2 active on F8
Bit 2 = 0(0): Out3 not active on F8
= 1(4): Out3 active on F8
Bit 3 = 0(0): Out4 not active on F8
= 1(: Out4 active on F8
44 0 0-255 F9 / F13 mapping
Bit 0 = 0(0): Out1 not active on F9
= 1(1): Out1 active on F9
Bit 1 = 0(0): Out2 not active on F9
= 1(2): Out2 active on F9
Bit 2 = 0(0): Out3 not active on F9
= 1(4): Out3 active on F9
Bit 3 = 0(0): Out4 not active on F9
= 1(: Out4 active on F9
Bit 4 = 0(0): Out1 not active on F13
= 1(16): Out1 active on F13
Bit 5 = 0(0): Out2 not active on F13
= 1(32): Out2 active on F13
Bit 6 = 0(0): Out3 not active on F13
= 1(64): Out3 active on F13
Bit 7 = 0(0): Out4 not active on F13
= 1(128): Out4 active on F13
45 0 0-255 F10 / F14 mapping
Bit 0 = 0(0): Out1 not active on F10
1(1): Out1 active on F10
Bit 1 = 0(0): Out2 not active on F10
= 1(2): Out2 active on F10
Bit 2 = 0(0): Out3 not active on F10
= 1(4): Out3 active on F10
Bit 3 = 0(0): Out4 not active on F10
= 1(: Out4 active on F10
Bit 4 = 0(0): Out1 not active on F14
= 1(16):Out1 active on F14
Bit 5 = 0(0): Out2 not active on F14
= 1(32):Out2 active on F14
Bit 6 = 0(0): Out3 not active on F14
= 1(64):Out3 active on F14
Bit 7 = 0(0): Out4 not active on F14
= 1(128): Out4 active on F14
46 0 0-255 F11 / F15 mapping
Bit 0 = 0(0): Out1 not active on F11
= 1(1): Out1 active on F11
Bit 1 = 0(0): Out2 not active on F11
= 1(2): Out2 active on F11
Bit 2 = 0(0): Out3 not active on F11
= 1(4): Out3 active on F11
Bit 3 = 0(0): Out4 not active on F11
= 1(: Out4 active on F11
Bit 4 = 0(0): Out1 not active on F15
= 1(16):Out1 active on F15
Bit 5 = 0(0): Out2 not active on F15
= 1(32):Out2 active on F15
Bit 6 = 0(0): Out3 not active on F15
= 1(64):Out3 active on F15
Bit 7 = 0(0): Out4 not active on F15
= 1(128): Out4 active on F15
47 0 0-255 F12 / F16 mapping
Bit 0 = 0(0): Out1 not active on F12
= 1(1): Out1 active on F12
Bit 1 = 0(0): Out2 not active on F12
= 1(2): Out2 active on F12
Bit 2 = 0(0): Out3 not active on F12
= 1(4): Out3 active on F12
Bit 3 = 0(0): Out4 not active on F12
= 1(: Out4 active on F12
Bit 4 = 0(0): Out1 not active on F16
= 1(16):Out1 active on F16 Bit 5 = 0(0): Out2 not active on F16
= 1(32):Out2 active on F16 Bit 6 = 0(0): Out3 not active on F16
= 1(64):Out3 active on F16 Bit 7 = 0(0): Out4 not active on F16
= 1(128): Out4 active on F16
48 255 0-255 Out 1 Light intensity, [1-255] , 0-continous
49 255 0-255 Out 2 Light intensity, [1-255] , 0-continous
50 255 0-255 Out 3 Light intensity, [1-255] , 0-continous
51 255 0-255 Out 4 Light intensity, [1-255] , 0-continous
60 3 0-7 and Motor, Back EMF measurement Delay
128-135 value of 0 or 128 swithes BackEMF Off, value>0 or > 128 changes the
BEMF measurement Delay. Delay(ms)=0.75+CV Value*0.25
Bit7=0 uses 32kHz PWM (CV range 0-7)
Bit7=1 uses 16kHz PWM ( CV range 128-135)
61 80 0-255 PID P constant
62 120 0-255 PID I constant
63 40 0-255 PID D constant
64 0 0-15 Brake Distance configuration
0-No brake
1-15 Braking rate, the CV value influences the Constant Braking Distance,
CV64=1 means the Shortest Braking Distance from maximum Speed to
STOP. Increase the CV value to increase the braking distance.
Distance=Value * Shortest Breaking Distance
65 25 0-255 Brake Delay
CV65= 0 means no Brake Delay. To increase breaking distance above the
value configured in CV64, increase in small amounts the value of CV65,
which will delay the start of the braking, resulting in a longer braking path.
Brake Delay = CV65 Value * 8ms (ms)
Extra Distance = MaxSpeed * BrakeDelay
Ex: 200ms(delay)=8(ms)*25(CV value)
67 2 1-127 Speed Table 1-28 ST[1] 1 position speed value
….. Throttle position speed mapping values, ex. 1 position=2 speed, 28
position=120 speed
94 120 1-127 ST[28], 28 position speed value
105 0 0-255 USER data, freely configurable. It is not cleared after a decoder reset
106 0 0-255 USER data, freely configurable. It is not cleared after a decoder reset
112 15 1-127 Fade ON effect on outputs, ex.:1=8ms, 15=120ms 125=1000ms
113 3 1-127 Fade OFF effect on outputs, ex.:1=8ms, 15=120ms 125=1000ms
114 4 0-255 Shunting speed, Function mapping F1-F8, F3 default (bit 0 is mapping F1,
bit 7 is mapping F8). Mapping is possible only for F1-F8
115 8 0-255 Switch Off Acceleration Deceleration, Function mapping, F4 default (bit 0
is mapping F1, bit 7 is mapping F8). Mapping is possible only for F1-F8
116 16 0-255 Disable Constant Braking, Function mapping, F5 default (bit 0 is mapping
F1, bit 7 is mapping F8). Mapping is possible only for F1-F8
117 0 0-15 Bit 0 = 0(0): Out1 could be dimmed and faded
= 1(1): continues signal with no fading on Out1
Bit 1 = 0(0): Out2 could be dimmed and faded
= 1(2): continues signal with no fading on Out2
Bit 2 = 0(0): Out3 could be dimmed and faded
= 1(4): continues signal with no fading on Out3
Bit 3 = 0(0): Out4 could be dimmed and faded
= 1(: continues signal with no fading on Out4
118 0 0-4 Electrical Coupler Output mapping for AUX 1-4 outputs. Only one of the
AUX outputs can be configured as ECoupler Output
CV118 = 0, None of the AUX selected for ECoupler operation
CV118 = 1, AUX1 selected for ECoupler operation
CV118 = 2, AUX2 selected for ECoupler operation
CV118 = 3, AUX3 selected for ECoupler operation
CV118 = 4, AUX4 selected for ECoupler operation
119 50 0-255 Electrical Coupler, Kick_time = Val*8ms, ex: 400ms=50*8ms
120 50 0-255 Decoupling, Locomotive move Time=Val*8ms, ex: 400ms=50*8ms
121 50 0-255 Decoupling Locomotive moving speed
122 0 0-1 Second Config, bit 0 0-LocoWire, 1-SUSI
123 16 0-255 SPP (Smart Power Pack) Timeout=16ms*Value Ex: =16ms*16=256ms
124 0 0-1 ECoupler Mode
CV124 = 0, PWM Output
CV124 = 1, Full Output on selected AUX in CV118
126 102 0-255 SUSI CV transport, SUSI CV=800+Value
127 0 0-255 SUSI DATA transport, Data write to CV=800+cv126
133 Chip temperature read out (the value is expressed in degrees Celsius. The
precision of the readout is +/- 2 degrees). Prior to the readout the F5
function must be switched On and Off
134 100 60-120 Temperature Limit for the temperature protection (value in degrees
Celsius)