The L6472 device, realized in analog mixed
signal technology, is an advanced fully integrated
solution suitable for driving two-phase bipolar
stepper motors with microstepping. It integrates
a dual low R
power switches equipped with an accurate onchip current sensing circuitry suitable for non
dissipative current control and overcurrent
protection. Thanks to a new current control,
a 1/16 microstepping is achieved through an
adaptive decay mode which outperforms
traditional implementations. The digital control
core can generate user defined motion profiles
with acceleration, deceleration, speed or target
position, easily programmed through a dedicated
register set.
All application commands and data registers,
including those used to set analog values
(i.e.: current control value, current protection trip
point, deadtime, etc.) are sent through a standard
5-Mbit/s SPI.
A very rich set of protections (thermal, low bus
voltage, overcurrent) makes the L6472 device
“bullet proof”, as required by the most demanding
motor control applications.
DMOS full bridge with all of the
DS(on)
March 2015DocID022729 Rev 51/70
This is information on a product in full production.
1. Maximum output current limit is related to metal connection and bonding characteristics. Actual limit must satisfy maximum
2. HTSSOP28 mounted on the EVAL6472H.
Differential voltage between AGND, PGND and DGND ±0.3 V
GND, diff
V
Bootstrap peak voltage 55 V
boot
Internal voltage regulator output pin and logic supply voltage 3.6 V
V
REG
Integrated ADC input voltage range (ADCIN pin) -0.3 to +3.6 V
ADCIN
V
OSC
out_diff
LOGIC
I
out
T
T
P
thermal dissipation constraints.
OSCIN and OSCOUT pin voltage range -0.3 to +3.6 V
Differential voltage between V
, OUT1B, OUT2B, PGND pins
V
SB
, OUT1A, OUT2A, PGND and
SA
= VSB = VS 48 V
V
SA
Logic inputs voltage range -0.3 to +5.5 V
(1)
R.m.s. output current 3 A
(1)
Pulsed output current T
Operating junction temperature -40 to 150 °C
OP
Storage temperature range -55 to 150 °C
s
Total power dissipation (TA = 25 °C)
tot
< 1 ms 7 A
PULSE
(2)
5W
2.2 Recommended operating conditions
Symbol Parameter Test condition Value Unit
V
V
V
out_diff
V
REG,in
V
ADC
Logic interface supply voltage
DD
Motor supply voltage VSA = VSB = VS 8 45 V
S
Differential voltage between VSA, OUT1A, OUT2A,
PGND and VSB, OUT1B, OUT2B, PGND pins
Logic supply voltage
Integrated ADC input voltage (ADCIN pin) 0 V
Table 3. Recommended operating conditions
3.3 V logic outputs 3.3 V
5 V logic outputs 5
V
= V
SA
V
voltage imposed by
REG
external source
DocID022729 Rev 59/70
= VS 45 V
SB
3.2 3.3 V
V
REG
70
Page 10
Electrical dataL6472
2.3 Thermal data
Table 4. Thermal data
SymbolParameterPackageTyp.Unit
R
thJA
1. HTSSOP28 mounted on the EVAL6472H Rev 1.0 board: four-layer FR4 PCB with a dissipating copper surface of about 40
cm2 on each layer and 15 via holes below the IC.
2. POWERSO36 mounted on the EVAL6472PD Rev 1.0 board: four-layer FR4 PCB with a dissipating copper surface of about
40 cm
Thermal resistance junction ambient
2
on each layer and 22 via holes below the IC.
POWERSO36
HTSSOP28
(1)
(2)
22
°C/W
12
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L6472Electrical characteristics
3 Electrical characteristics
VSA = VSB = 36 V; VDD = 3.3 V; internal 3 V regulator; TJ = 25 °C, unless otherwise
specified.
Symbol Parameter Test condition Min. Typ. Max. Unit
General
Table 5. Electrical characteristics
V
SthOn VS
V
SthOff
V
SthHyst VS
UVLO turn-on threshold 7.5 8.2 8.9 V
VS UVLO turn-off threshold 6.6 7.2 7.8 V
UVLO threshold hysteresis 0.7 1 1.3 V
Iq Quiescent motor supply current
T
Thermal warning temperature 130 °C
j(WRN)
T
j(SD)
Thermal shutdown temperature 160 °C
Charge pump
V
pump
f
pump,min
f
pump,max
I
boot
Voltage swing for charge pump
oscillator
Minimum charge pump oscillator
frequency
Maximum charge pump oscillator
frequency
(1)
(1)
Average boot current
Output DMOS transistor
High-side switch on-resistance
R
DS(on)
Low-side switch on-resistance
I
DSS
Leakage current
Rise time
t
r
(3)
Internal oscillator selected;
= 3.3 V ext; CP floating
V
REG
f
= f
sw,A
= 15.6 kHz
sw,B
POW_SR = ‘10’
T
= 25 °C, I
j
T
= 125 °C,
j
T
= 25 °C, I
j
= 125 °C,
T
j
OUT = V
= 3 A 0.37
out
(2)
I
= 3 A 0.51
out
= 3 A 0.18
out
(2)
I
= 3 A 0.23
out
S
OUT = GND -0.3
POW_SR = '00', I
POW_SR = '00', I
POW_SR = ‘11’, I
POW_SR = ‘10’, I
POW_SR = ‘01’, I
= +1 A 100
out
= -1 A 80
out
= ±1 A 100
out
= ±1 A 200
out
= ±1 A 300
out
0.5 0.65 mA
10 V
660 kHz
800 kHz
1.1 1.4 mA
3.1
mA
ns
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Electrical characteristicsL6472
Table 5. Electrical characteristics (continued)
Symbol Parameter Test condition Min. Typ. Max. Unit
(3)
SR
SR
t
Fall time
f
Output rising slew rate
out_r
Output falling slew rate
out_f
Deadtime and blanking
t
DT
Deadtime
(1)
tblank Blanking time
(1)
POW_SR = '00'; I
POW_SR = '00'; I
POW_SR = ‘11’, I
POW_SR = ‘10’, I
POW_SR = ‘01’, I
POW_SR = '00', I
POW_SR = '00', I
POW_SR = ‘11’, I
POW_SR = ‘10’, I
POW_SR = ‘01’, I
POW_SR = '00', I
POW_SR = '00', I
POW_SR = ‘11’, I
POW_SR = ‘10’, I
POW_SR = ‘01’, I
= +1 A 90
out
= -1 A 110
out
= ±1 A 110
out
= ±1 A 260
out
= ±1 A 375
load
= +1 A 285
out
= -1 A 360
out
= ±1 A 285
out
= ±1 A 150
out
= ±1 A 95
out
= +1 A 320
out
= -1 A 260
out
= ±1 A 260
out
= ±1 A 110
out
= ±1 A 75
out
POW_SR = '00' 250
POW_SR = ‘11’, f
POW_SR = ‘10’, f
POW_SR = ‘01’, f
= 16 MHz 375
OSC
= 16 MHz 625
OSC
= 16 MHz 875
OSC
POW_SR = '00' 250
POW_SR = ‘11’, f
POW_SR = ‘10’, f
POW_SR = ‘01’, f
= 16 MHz 375
OSC
= 16 MHz 625
OSC
= 16 MHz 875
OSC
ns
V/µs
V/µs
ns
ns
Source-drain diodes
High-side diode forward ON voltage I
V
SD,HS
V
Low-side diode forward ON voltage I
SD,LS
t
rrHS
t
rrLS
High-side diode reverse recovery
time
Low-side diode reverse recovery time I
= 1 A 1 1.1 V
out
= 1 A 1 1.1 V
out
I
= 1 A 30 ns
out
= 1 A 100 ns
out
Logic inputs and outputs
V
Low logic level input voltage 0.8 V
IL
High logic level input voltage 2 V
V
IH
I
High logic level input current
IH
(4)
V
= 5 V 1 µA
IN
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L6472Electrical characteristics
Table 5. Electrical characteristics (continued)
Symbol Parameter Test condition Min. Typ. Max. Unit
IIL Low logic level input current
V
Low logic level output voltage
OL
V
High logic level output voltage
OH
RPU RPD
CS pull-up and STBY pull-down
resistors
(5)
(6)
V
= 0 V -1 µA
IN
VDD = 3.3 V, IOL = 4 mA 0.3
V
= 5 V, IOL = 4 mA 0.3
V
DD
V
= 3.3 V, IOH = 4 mA 2.4
DD
= 5 V, IOH = 4 mA 4.7
V
DD
V
CS = GND; STBY/RST = 5 V 335 430 565 k
Internal logic supply current
I
logic
I
logic,STBY
f
STCK
Standby mode internal logic supply
current
Step-clock input frequency 2 MHz
Internal oscillator and external oscillator driver
f
Internal oscillator frequency T
osc,i
f
osc,e
V
OSCOUTH
V
OSCOUTL
t
rOSCOUT
t
fOSCOUT
t
extosc
t
intosc
Programmable external oscillator
frequency
OSCOUT clock source high level
voltage
OSCOUT clock source low level
voltage
OSCOUT clock source rise and fall
time
Internal to external oscillator
switching delay
External to internal oscillator
switching delay
SPI
f
Maximum SPI clock frequency
CK,MAX
t
rCK
t
fCK
t
hCK
t
lCK
t
setCS
t
holCS
t
disCS
t
setSDI
t
holSDI
t
enSDO
SPI clock rise and fall time
SPI clock high and low time
Chip select setup time
Chip select hold time
De-select time
Data input setup time
Data input hold time
Data output enable time
(7)
(7)
(7)
(7)
(7)
(7)
(7)
(7)
(7)
3.3 V V
internal oscillator
3.3 V V
= 25 °C, V
j
externally supplied,
REG
externally supplied 2 2.5 µA
REG
= 3.3 V -3% 16 +3% MHz
REG
3.7 4.3 mA
8 32 MHz
Internal oscillator 3.3 V V
externally supplied; I
OSCOUT
Internal oscillator 3.3 V V
externally supplied; I
OSCOUT
REG
REG
= 4 mA
= 4 mA
2.4 V
0.3 V
Internal oscillator 20 ns
3 ms
1.5 µs
5 MHz
CL = 30 pF 25 ns
75 ns
350 ns
10 ns
800 ns
25 ns
20 ns
38 ns
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Electrical characteristicsL6472
Table 5. Electrical characteristics (continued)
Symbol Parameter Test condition Min. Typ. Max. Unit
t
disSDO
t
vSDO
t
holSDO
Data output disable time
Data output valid time
Data output hold time
Switch input (SW)
(7)
(7)
(7)
37 ns
47 ns
57 ns
R
PUSW
SW input pull-up resistance SW = GND 60 85 110 k
Current control
I
STEP,max
I
STEP,min
Max. programmable reference
current
Min. programmable reference current 31 mA
Overcurrent protection
I
OCD,MAX
I
OCD,MIN
I
OCD,RES
t
OCD,Flag
t
OCD,SD
Maximum programmable overcurrent
detection threshold
Standby and reset pin. LOW logic level resets the
logic and puts the device into standby mode. If not
used, it should be connected to VDD
Internally connected to PGND, AGND and DGND
pins
18/70DocID022729 Rev 5
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L6472Typical applications
5 Typical applications
Table 7. Typical application values
Name Value
220 nF
C
VS
C
C
C
100 µF
VSPOL
100 nF
C
REG
REGPOL
47 µF
C
100 nF
DD
10 µF
DDPOL
D1 Charge pump diodes
C
220 nF
BOOT
10 nF
C
FLY
R
39 k
PU
100
R
SW
10 nF
C
SW
Figure 4. Bipolar stepper motor control application using the L6472
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Functional descriptionL6472
6 Functional description
6.1 Device power-up
At the end of power-up, the device state is the following:
Registers are set to default
Internal logic is driven by the internal oscillator and a 2 MHz clock is provided by the
OSCOUT pin
Bridges are disabled (High Z)
UVLO bit in the STATUS register is forced low (fail condition)
FLAG output is forced low.
During power-up the device is under reset (all logic IO disabled and power bridges in highimpedance state) until the following conditions are satisfied:
V
V
Internal oscillator is operative.
Any motion command causes the device to exit from High Z state (HardStop and SoftStop
included).
is greater than V
S
is greater than V
REG
SthOn
REGth
= 2.8 V (typ.)
6.2 Logic I/O
Pins CS, CK, SDI, STCK, SW and STBY\RST are TTL/CMOS 3.3 V - 5 V compatible logic
inputs.
Pin SDO is a TTL/CMOS compatible logic output. The VDD pin voltage sets the logic output
pin voltage range; when it is connected to VREG or a 3.3 V external supply voltage, the
output is 3.3 V compatible. When VDD is connected to a 5 V supply voltage, SDO is 5 V
compatible.
VDD is not internally connected to V
A 10 µF capacitor should be connected to the VDD pin in order to obtain a proper operation.
Pins FLAG
and BUSY\SYNC are open drain outputs.
6.3 Charge pump
To ensure the correct driving of the high-side integrated MOSFETs, a voltage higher than
the motor power supply voltage needs to be applied to the Vboot pin. The high-side gate
driver supply voltage Vboot is obtained through an oscillator and a few external components
realizing a charge pump (see Figure 5).
, an external connection is always needed.
REG
20/70DocID022729 Rev 5
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L6472Functional description
Figure 5. Charge pump circuitry
6.4 Microstepping
The driver is able to divide the single step into up to 16 microsteps. Step mode can be
programmed by the STEP_SEL parameter in the STEP_MODE register (see Table 20 on
page 47).
Step mode can only be changed when bridges are disabled. Every time step mode is
changed, the electrical position (i.e. the point of microstepping sine wave that is generated)
is reset to zero, and the absolute position counter value (see Section 6.5) becomes
meaningless.
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Functional descriptionL6472
Figure 6. Normal mode and microstepping (16 microsteps)
Automatic full-step mode
When motor speed is greater than a programmable full-step speed threshold, the L6472
switches automatically to full-step mode (see Figure 7); the driving mode returns to
microstepping when motor speed decreases below the full-step speed threshold. The fullstep speed threshold is set through the FS_SPD register (see Section 9.1.9 on page 44).
1IBTF"
1IBTF#
Figure 7. Automatic full-step switching
*
QFBL
P4UFQQJOH
TJOSY*
QFBL
'VMM4UFQ
/YS/YS
P4UFQQJOH
22/70DocID022729 Rev 5
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L6472Functional description
6.5 Absolute position counter
An internal 22-bit register (ABS_POS) keeps track of the motor motion according to the
selected step mode; the stored value unit is equal to the selected step mode (full, half,
quarter, etc.). The position range is from -2
21
to +221-1 (µ) steps (see Section 9.1.1 on page
41).
6.6 Programmable speed profiles
The user can easily program a customized speed profile, independently defining
acceleration, deceleration, maximum and minimum speed values through the ACC, DEC,
MAX_SPEED and MIN_SPEED registers respectively (see Section 9.1.5 on page 42, 9.1.6
on page 42, 9.1.7 on page 43 and 9.1.8 on page 43).
When a command is sent to the device, the integrated logic generates the microstep
frequency profile that performs a motor motion compliant to speed profile boundaries.
All acceleration parameters are expressed in step/tick
expressed in step/tick; the unit of measurement does not depend on selected step mode.
Acceleration and deceleration parameters range from 2
(equivalent to 14.55 to 59590 step/s2).
For detailed command descriptions refer to Section 9.2 on page 54.
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Functional descriptionL6472
6.7.1 Constant speed commands
A constant speed command produces a motion in order to reach and maintain a user
defined target speed starting from the programmed minimum speed (set in the MIN_SPEED
register) and with the programmed acceleration/deceleration value (set in the ACC and DEC
registers). A new constant speed command can be requested anytime.
Figure 8. Constant speed command examples
6.7.2 Positioning commands
An absolute positioning command produces a motion in order to reach a user-defined
position that is sent to the device together with the command. The position can be reached
by performing the minimum path (minimum physical distance) or forcing a direction (see
Figure 9).
The performed motor motion is compliant to programmed speed profile boundaries
(acceleration, deceleration, minimum and maximum speed).
Note that with some speed profiles or positioning commands, the deceleration phase can
start before the maximum speed is reached.
24/70DocID022729 Rev 5
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L6472Functional description
Figure 9. Positioning command examples
6.7.3 Motion commands
Motion commands produce a motion in order to perform a user-defined number of
microsteps in a user-defined direction that are sent to the device together with the command
(see Figure 10).
The performed motor motion is compliant to programmed speed profile boundaries
(acceleration, deceleration, minimum and maximum speed).
Note that with some speed profiles or motion commands, the deceleration phase can start
before the maximum speed is reached.
Figure 10. Motion command examples
6.7.4 Stop commands
A stop command forces the motor to stop. Stop commands can be sent anytime.
The SoftStop command causes the motor to decelerate with a programmed deceleration
value until the MIN_SPEED value is reached and then stops the motor maintaining the rotor
position (a holding torque is applied).
DocID022729 Rev 525/70
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Functional descriptionL6472
The HardStop command stops the motor instantly, ignoring deceleration constraints and
maintaining the rotor position (a holding torque is applied).
The SoftHiZ command causes the motor to decelerate with a programmed deceleration
value until the MIN_SPEED value is reached and then forces the bridges into highimpedance state (no holding torque is present).
The HardHiZ command instantly forces the bridges into high-impedance state (no holding
torque is present).
6.7.5 Step-clock mode
In step-clock mode the motor motion is defined by the step-clock signal applied to the STCK
pin.
At each step-clock rising edge, the motor is moved by one microstep in the programmed
direction and the absolute position is consequently updated.
When the system is in step-clock mode the SCK_MOD flag in the STATUS register is raised,
the SPEED register is set to zero and the motor status is considered stopped whatever the
STCK signal frequency (the MOT_STATUS parameter in the STATUS register equal to
g00h).
6.7.6 GoUntil and ReleaseSW commands
In most applications the power-up position of the stepper motor is undefined, so an
initialization algorithm driving the motor to a known position is necessary.
The GoUntil and ReleaseSW commands can be used in combination with external switch
input (see Section 6.13 on page 30) to easily initialize the motor position.
The GoUntil command makes the motor run at the target constant speed until the SW input
is forced low (falling edge). When this event occurs, one of the following actions can be
performed:
ABS_POS register is set to zero (home position) and the motor decelerates to zero
speed (as a SoftStop command)
ABS_POS register value is stored in the MARK register and the motor decelerates to
zero speed (as a SoftStop command).
If the SW_MODE bit of the CONFIG register is set to e0f, the motor does not decelerate but
it immediately stops (as a HardStop command).
The ReleaseSW command makes the motor run at the programmed minimum speed until
the SW input is forced high (rising edge). When this event occurs, one of the following
actions can be performed:
ABS_POS register is set to zero (home position) and the motor immediately stops
(as a HardStop command)
ABS_POS register value is stored in the MARK register and the motor immediately
stops (as a HardStop command).
If the programmed minimum speed is less than 5 step/s, the motor is driven at 5 step/s.
26/70DocID022729 Rev 5
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L6472Functional description
6.8 Internal oscillator and oscillator driver
The control logic clock can be supplied by the internal 16-MHz oscillator, an external
oscillator (crystal or ceramic resonator) or a direct clock signal.
These working modes can be selected by the EXT_CLK and OSC_SEL parameters in the
CONFIG register (see Table 25 on page 50).
At power-up the device starts using the internal oscillator and provides a 2-MHz clock signal
on the OSCOUT pin.
Warning:In any case, before changing clock source configuration,
a hardware reset is mandatory. Switching to different clock
configurations during operation could cause unexpected
behavior.
6.8.1 Internal oscillator
In this mode the internal oscillator is activated and OSCIN is unused. If the OSCOUT clock
source is enabled, the OSCOUT pin provides a 2, 4, 8 or 16-MHz clock signal (according to
the OSC_SEL value); otherwise it is unused (see Figure 11).
6.8.2 External clock source
Two types of external clock source can be selected: crystal/ceramic resonator or direct clock
source. Four programmable clock frequencies are available for each external clock source:
8, 16, 24 and 32 MHz.
When an external crystal/resonator is selected, the OSCIN and OSCOUT pins are used to
drive the crystal/resonator (see Figure 11). The crystal/resonator and load capacitors (CL)
must be placed as close as possible to the pins. Refer to Ta bl e 8 for the choice of the load
capacitor value according to the external oscillator frequency.
1. First harmonic resonance frequency.
2. Lower ESR value allows the driving of greater load capacitors.
If a direct clock source is used, it must be connected to the OSCIN pin, and the OSCOUT
pin supplies the inverted OSCIN signal (see Figure 11).
Table 8. CL values according to external oscillator frequency
Crystal/resonator freq.
8 MHz 25 pF (ESR
16 MHz 18 pF (ESR
24 MHz 15 pF (ESR
32 MHz 10 pF (ESR
(1)
CL
(2)
= 80 )
max
= 50 )
max
= 40 )
max
= 40 )
max
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Functional descriptionL6472
Figure 11. OSCIN and OSCOUT pin configurations
Note:When OSCIN is UNUSED, it should be left floating.
When OSCOUT is UNUSED it should be left floating.
6.9 Overcurrent detection
When the current in any of the power MOSFETs exceeds a programmed overcurrent
threshold, the STATUS register OCD flag is forced low until the overcurrent event expires
and a GetStatus command is sent to the IC (see Section 9.1.19 on page 52 and 9.2.20 on
page 63). The overcurrent event expires when all the power MOSFET currents fall below
the programmed overcurrent threshold.
The overcurrent threshold can be programmed through the OCD_TH register in one of 16
available values ranging from 375 mA to 6 A with steps of 375 mA (see Table 18 on
page 47).
It is possible to set if an overcurrent event causes or not the MOSFET turn-off (bridges in
high-impedance status) acting on the OC_SD bit in the CONFIG register (see
Section 9.1.18 on page 49). The OCD flag in the STATUS register is raised anyway
(see Table 26 on page 50).
When the IC outputs are turned off by an OCD event, they cannot be turned on until the
OCD flag is released by a GetStatus command.
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L6472Functional description
Warning:The overcurrent shutdown is a critical protection feature. It is
not recommended to disable it.
6.10 Undervoltage lockout (UVLO)
The L6472 provides motor supply UVLO protection. When the motor supply voltage falls
below the V
threshold voltage, the STATUS register UVLO flag is forced low. When
SthOff
a GetStatus command is sent to the IC, and the undervoltage condition expires, the UVLO
flag is released (see Section 9.1.19 on page 52 and 9.2.20 on page 63). The undervoltage
condition expires when the motor supply voltage goes over the V
threshold voltage.
SthOn
When the device is in the undervoltage condition, no motion command can be performed.
The UVLO flag is forced low by logic reset (power-up included) even if no UVLO condition is
present.
6.11 Thermal warning and thermal shutdown
An internal sensor allows the L6472 to detect when the device internal temperature exceeds
a thermal warning or an overtemperature threshold.
When the thermal warning threshold (T
register is forced low (see Section 9.1.19) until the temperature decreases below T
and a GetStatus command is sent to the IC (see Section 9.1.19 and 9.2.20).
When the thermal shutdown threshold (T
shutdown condition: the TH_SD bit in the STATUS register is forced low, the power bridges
are disabled bridges in high-impedance state and the HiZ bit in the STATUS register is
raised (see Section 9.1.19).
The thermal shutdown condition only expires when the temperature goes below the thermal
warning threshold (T
j(WRN)
On exiting the thermal shutdown condition, the bridges are still disabled (HiZ flag high);
whichever motion command makes the device exit from High Z state (HardStop and
SoftStop included).
6.12 Reset and standby
The device can be reset and put into standby mode through a dedicated pin. When the
STBY
\RST pin is driven low, the bridges are left open (High Z state), the internal charge
pump is stopped, the SPI interface and control logic are disabled, and the internal 3 V
voltage regulator maximum output current is reduced to IREG,STBY; as a result, the L6472
heavily reduces the power consumption. At the same time the register values are reset to
default and all protection functions are disabled. STBY\RST
least for t
STBY,min
On exiting standby mode, as well as for IC power-up, a delay of up to t
before applying a new command to allow proper oscillator and logic startup and a delay of
up to t
cpwu
in order to ensure the complete switch to standby mode.
must be given to allow the charge pump startup.
) is reached, the TH_WRN bit in the STATUS
j(WRN)
) is reached, the device goes into the thermal
j(OFF)
j(WRN)
).
input must be forced low at
must be given
logicwu
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Functional descriptionL6472
On exiting standby mode the bridges are disabled (HiZ flag high) and whichever motion
command causes the device to exit High Z state (HardStop and SoftStop included).
Warning:It is not recommended to reset the device when outputs are
active. The device should be switched to high-impedance
state before being reset.
6.13 External switch (SW pin)
The SW input is internally pulled-up to V
and detects if the pin is open or connected to
DD
ground (see Figure 12).
The SW_F bit of the STATUS register indicates if the switch is open (‘0’) or closed (‘1’) (see
Section 9.1.19 on page 52); the bit value is refreshed at every system clock cycle (125 ns).
The SW_EVN flag of the STATUS register is raised when a switch turn-on event (SW input
falling edge) is detected (see Section 9.1.19). A GetStatus command releases the SW_EVN
flag (see Section 9.2.20 on page 63).
By default a switch turn-on event causes a HardStop interrupt (SW_MODE bit of the
CONFIG register set to ‘0’). Otherwise (SW_MODE bit of the CONFIG register set to ‘1’),
switch input events do not cause interrupts and the switch status information is at the user’s
disposal (see Table 26 on page 50).
The switch input can be used by the GoUntil and ReleaseSW commands as described in
Section 9.2.10 on page 59 and 9.2.11 on page 60.
If the SW input is not used, it should be connected to VDD.
Figure 12. External switch connection
6.14 Programmable DMOS slew rate, deadtime and blanking time
Using the POW_SR parameter in the CONFIG register, it is possible to set the commutation
speed of the power bridge output (see Table 28 on page 51).
30/70DocID022729 Rev 5
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L6472Functional description
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6.15 Integrated analog-to-digital converter
The L6472 integrates an N
bit ramp-compare analog-to-digital converter with a reference
ADC
voltage equal to VREG. The analog-to-digital converter input is available through the ADCIN
pin and the conversion result is available in the ADC_OUT register (see Section 9.1.13 on
page 46). The sampling frequency is equal to the clock frequency divided by 512.
The ADC_OUT value can be used for the torque regulation or can remain at the user’s
disposal.
6.16 Internal voltage regulator
The L6472 device integrates a voltage regulator which generates a 3 V voltage starting from
motor power supply (VSA and VSB). In order to make the voltage regulator stable, at least
22 µF should be connected between the VREG pin and ground (the suggested value is 47
µF).
The internal voltage regulator can be used to supply the VDD pin in order to make the
device digital output range 3.3 V compatible (Figure 13). A digital output range 5 V
compatible can be obtained connecting the VDD pin to an external 5 V voltage source. In
both cases, a 10 µF capacitance should be connected to the VDD pin in order to obtain
a correct operation.
The internal voltage regulator is able to supply a current up to I
consumption included (I
can be supplied is I
REG, STBY
If an external 3.3 V regulated voltage is available, it can be applied to the VREG pin in order
to supply all the internal logic and avoid power dissipation of the internal 3 V voltage
regulator (Figure 13). The external voltage regulator should never sink current from the
VREG pin.
). When the device is in standby mode the maximum current that
logic
, internal consumption included (I
REG,MAX
logic, STBY
, internal logic
).
Figure 13. Internal 3 V linear regulator
70
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Functional descriptionL6472
6.17 BUSY\SYNC pin
This pin is an open drain output which can be used as the busy flag or synchronization
signal according to the SYNC_EN bit value (STEP_MODE register).
6.17.1 BUSY operation mode
The pin works as busy signal when the SYNC_EN bit is set low (default condition). In this
mode the output is forced low while a constant speed, absolute positioning or motion
command is under execution. The BUSY
executed (target speed or target position reached). The STATUS register includes a BUSY
flag that is the BUSY pin mirror (see Section 9.1.19 on page 52).
In the case of daisy chain configuration, BUSY pins of different ICs can be hard-wired to
save host controller GPIOs.
6.17.2 SYNC operation mode
The pin works as a synchronization signal when the SYNC_EN bit is set high. In this mode
a step-clock signal is provided on the output according to a SYNC_SEL and STEP_SEL
parameter combination (see Section 9.1.16 on page 47).
pin is released when the command has been
6.18 FLAG pin
By default an internal open drain transistor pulls the FLAG pin to ground when at least one
of the following conditions occur:
Power-up or standby/reset exit
Overcurrent detection
Thermal warning
Thermal shutdown
UVLO
Switch turn-on event
Wrong command
Non-performable command.
It is possible to mask one or more alarm conditions by programming the ALARM_EN
register (see Table 23 on page 49). If the corresponding bit of the ALARM_EN register is
low, the alarm condition is masked and it does not cause a FLAG pin transition; all other
actions imposed by alarm conditions are performed anyway. In the case of daisy chain
configuration, the FLAG pins of different ICs can be OR-wired to save host controller
GPIOs.
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L6472Phase current control
7 Phase current control
The L6472 performs a new current control technique, named predictive current control,
allowing the device to obtain the target average phase current. This method is described in
detail in Section 7.1. Furthermore, the L6472 automatically selects the better decay mode in
order to follow the current profile.
Current control algorithm parameters can be programmed by the T_FAST, TON_MIN,
TOFF_MIN and CONFIG registers (see Section 9.1.11 on page 45, 9.1.12 on page 45,
9.1.13 on page 46 and 9.1.18 on page 49 for details).
Different current amplitude can be set for acceleration, deceleration and constant speed
phases and when the motor is stopped through the TVAL_ACC, TVAL_DEC, TVAL_RUN
and TVAL_HOLD registers (see Section 7.4 on page 37). The output current amplitude can
also be regulated by the ADCIN voltage value (see Section 6.15).
Each bridge is driven by an independent control system that shares the control parameters
only with other bridges.
7.1 Predictive current control
Unlike a classical peak current control system, that causes the phase current decay when
the target value is reached, this new method keeps the power bridge on for an extra time
after reaching the current threshold.
At each cycle the system measures the time required to reach the target current (t
After that the power stage is kept in a “predictive” ON state (t
mean value of t
in Figure 14.
in the last two control cycles (actual one and previous one), as shown
SENSE
Figure 14. Predictive current control
) for a time equal to the
PRED
SENSE
).
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Phase current controlL6472
At the end of the predictive ON state the power stage is set in the OFF state for a fixed time,
as in a constant t
current control. During the OFF state both slow and fast decay can be
OFF
performed; the better decay combination is automatically selected by the L6472, as
described in Section 7.2.
As shown in Figure 14, the system is able to center the triangular wave on the desired
reference value improving dramatically the accuracy of the current control system: in fact
the average value of a triangular wave is exactly equal to the middle point of each of its
segments and at steady-state the predictive current control tends to equalize the duration of
the t
SENSE
and the t
Furthermore, the t
time.
PRED
value is recalculated each time a new current value is requested
OFF
(microstep change) in order to keep the PWM frequency as near as possible to the
programmed one (TSW parameter in the CONFIG register).
The device can be forced to work using a classic peak current control setting the PRED_EN
bit in the CONFIG register low (default condition). In this case, after the sense phase
(t
) the power stage is set in the OFF state, as shown in Figure 15.
SENSE
Figure 15. Non-predictive current control
7.2 Auto-adjusted decay mode
During the current control, the device automatically selects the better decay mode in order
to follow the current profile reducing the current ripple.
At reset, the OFF time is performed by turning on both the low-side MOSFETs of the power
stage and the current recirculates in the lower half of the bridge (slow decay).
If, during a PWM cycle, the target current threshold is reached in a time shorter than the
TON_MIN value, a fast decay of TOFF_FAST/8 (T_FAST register) is immediately performed
turning on the opposite MOS of both half-bridges and the current recirculates back to the
supply bus.
After this time, the bridge returns to the ON state: if the time needed to reach the target
current value is still less than TON_MIN, a new fast decay is performed with a period twice
the previous one. Otherwise, the normal control sequence is followed as described in
Section 7.1. The maximum fast decay duration is set by the TOFF_FAST value.
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L6472Phase current control
Figure 16. Adaptive decay - fast decay tuning
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When two or more fast decays are performed with the present target current, the control
system adds a fast decay at the end of every OFF time, keeping the OFF state duration
constant (t
is split into t
OFF
OFF,SLOW
and t
OFF,FAST
). When the current threshold is increased
by a microstep change (rising step), the system returns to normal decay mode (slow decay
only) and the t
value is halved.
FAST
Stopping the motor or reaching the current sine wave zero crossing causes the current
control system to return to the reset state.
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Phase current controlL6472
Figure 17. Adaptive decay switch from normal to slow + fast decay mode and vice-versa
7.3 Auto-adjusted fast decay during the falling steps
When the target current is decreased by a microstep change (falling step), the device
performs a fast decay in order to reach the new value as fast as possible. Anyway,
exceeding the fast duration may cause a strong ripple on the step change. The L6472
device automatically adjusts these fast decays reducing the current ripple.
At reset, the fast decay value (t
value is doubled every time, within the same falling step, an extra fast decay is necessary to
obtain an ON time greater than TON_MIN. The maximum t
FALL_STEP.
At the next falling step, the system uses the last t
Stopping the motor or reaching the current sine wave zero crossing causes the current
control system to return to the reset state.
36/70DocID022729 Rev 5
) is set to FALL_STEP/4 (T_FAST register). The t
FALL
value is equal to
FALL
value of the previous falling step.
FALL
FALL
Page 37
L6472Phase current control
Figure 18. Fast decay tuning during the falling steps
7.4 Torque regulation (output current amplitude regulation)
The output current amplitude can be regulated in two ways: writing the TVAL_ACC,
TVAL_DEC, TVAL_RUN and TVAL_HOLD registers or varying the ADCIN voltage value.
The EN_TQREG bit (CONFIG register) sets the torque regulation method. If this bit is high,
the ADC_OUT prevalue is used to regulate output current amplitude (see Section 9.1.14 on
page 46). Otherwise the internal analog-to-digital converter is at the user’s disposal and the
output current amplitude is managed by the TVAL_HOLD, TVAL_RUN, TVAL_ACC and
TVAL_DEC registers (see Section 9.1.10 on page 44).
The voltage applied to the ADCIN pin is sampled at f
bit digital signal. The analog-to-digital conversion result is available in the ADC_OUT
register.
frequency and converted in an NADC
S
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Serial interfaceL6472
8 Serial interface
The integrated 8-bit serial peripheral interface (SPI) is used for a synchronous serial
communication between the host microprocessor (always master) and the L6472 (always
slave).
The SPI uses chip select (CS
output (SDO) pins. When CS
(high-impedance).
The communication starts when CS
data communication.
All commands and data bytes are shifted into the device through the SDI input, most
significant bit first. The SDI is sampled on the rising edges of the CK.
All output data bytes are shifted out of the device through the SDO output, most significant
bit first. The SDO is latched on the falling edges of the CK. When a return value from the
device is not available, an all zero byte is sent.
After each byte transmission, the CS
in order to allow the device to decode the received command and put the return value into
the shift register.
All timing requirements are shown in Figure 19 (see Section 3 on page 11 for the respective
electrical characteristics for values).
Multiple devices can be connected in a daisy chain configuration, as shown in Figure 20.
), serial clock (CK), serial data input (SDI) and serial data
is high, the device is unselected and the SDO line is inactive
is forced low. The CK line is used for synchronization of
input must be raised and be kept high for at least t
Figure 19. SPI timings diagram
disCS
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L6472Serial interface
Figure 20. Daisy chain configuration
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Programming manualL6472
9 Programming manual
9.1 Register and flag description
Tab le 9 shows a map of the user registers available (detailed description in respective
paragraphs from Section 9.1.1 on page 41 to Section 9.1.19 on page 52):
Table 9. Register map
Address
[Hex]
Register
name
Register function
Len.
[bit]
Reset
[Hex]
Reset valueRemarks
(1)
h01 ABS_POS Current position 22 000000 0 R, WS
h02 EL_POS Electrical position 9 000 0 R, WS
h03 MARK Mark position 22 000000 0 R, WR
h04 SPEED Current speed 20 00000 0 step/tick (0 step/s) R
1. R: Readable, WH: writable only when outputs are in high-impedance, WS: writable only when motor is stopped, WR: always
writable.
2. According to startup conditions.
3. The bit 3 of the register must be set to one.
Register
name
Register function
Len.
[bit]
Reset
[Hex]
Reset valueRemarks
Internal oscillator, 2 MHz OSCOUT
clock, supply voltage compensation
disabled, overcurrent shutdown
enabled,
slew rate = 290 V/µs TSW = 40 µs
High-impedance state, UVLO/reset
(2)
flag set.
R, WH
R
9.1.1 ABS_POS
The ABS_POS register contains the current motor absolute position in agreement to the
selected step mode; the stored value unit is equal to the selected step mode (full, half,
quarter, etc.). The value is in 2's complement format and it ranges from -2
At power-on the register is initialized to “0” (HOME position).
21
to +221-1.
(1)
Any attempt to write the register when the motor is running causes the command to be
ignored and the NOTPERF_CMD flag to rise (see Section 9.1.19 on page 52).
9.1.2 EL_POS
The EL_POS register contains the current electrical position of the motor. The two MSbits
indicate the current step and the other bits indicate the current microstep (expressed in
step/128) within the step.
Bit 8 Bit 7 Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0
STEP MICROSTEP
When the EL_POS register is written by the user the new electrical position is instantly
imposed. When the EL_POS register is written its value must be masked in order to match
with the step mode selected in the STEP_MODE register in order to avoid a wrong
microstep value generation (see Section 9.1.16 on page 47); otherwise the resulting
microstep sequence is incorrect.
Any attempt to write the register when the motor is running causes the command to be
ignored and the NOTPERF_CMD flag to rise (see Section 9.1.19 on page 52).
Table 10. EL_POS register
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step s
SPEED 2
28–
tick
-------------------------------------=
step s
ACC 2
40–
tick
2
---------------------------- -=
9.1.3 MARK
The MARK register contains an absolute position called MARK, in accordance with the
selected step mode; the stored value unit is equal to the selected step mode (full, half,
quarter, etc.).
It is in 2's complement format and it ranges from -2
21
to +221-1.
9.1.4 SPEED
The SPEED register contains the current motor speed, expressed in step/tick (format
unsigned fixed point 0.28).
In order to convert the SPEED value in step/s the following formula can be used:
Equation 1
where SPEED is the integer number stored in the register and tick is 250 ns.
The available range is from 0 to 15625 step/s with a resolution of 0.015 step/s.
Note:The range, effectively available to the user, is limited by the MAX_SPEED parameter.
Any attempt to write the register causes the command to be ignored and the
NOTPERF_CMD flag to rise (see Section 9.1.19 on page 52).
9.1.5 ACC
The ACC register contains the speed profile acceleration expressed in step/tick2 (format
unsigned fixed point 0.40).
In order to convert ACC value in step/s2 the following formula can be used:
Equation 2
where ACC is the integer number stored in the register and tick is 250 ns.
The available range is from 14.55 to 59590 step/s
The 0xFFF value of the register is reserved and it should never be used.
Any attempt to write to the register when the motor is running causes the command to be
ignored and the NOTPERF_CMD flag to rise (see Section 9.1.19).
9.1.6 DEC
The DEC register contains the speed profile deceleration expressed in step/tick2 (format
unsigned fixed point 0.40).
In order to convert the DEC value in step/s2 the following formula can be used:
Equation 3
where DEC is the integer number stored in the register and tick is 250 ns.
The available range is from 14.55 to 59590 step/s
2
with a resolution of 14.55 step/s2.
Any attempt to write the register when the motor is running causes the command to be
ignored and the NOTPERF_CMD flag to rise (see Section 9.1.19 on page 52).
9.1.7 MAX_SPEED
The MAX_SPEED register contains the speed profile maximum speed expressed in
step/tick (format unsigned fixed point 0.18).
In order to convert it in step/s the following formula can be used:
Equation 4
where MAX_SPEED is the integer number stored in the register and tick is 250 ns.
The available range is from 15.25 to 15610 step/s with a resolution of 15.25 step/s.
9.1.8 MIN_SPEED
The MIN_SPEED register contains the following parameters:
Bit12 Bit 11 Bit 10 Bit 9 Bit 8 Bit 7 Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0
0 MIN_SPEED
The MIN_SPEED parameter contains the speed profile minimum speed. Its value is
expressed in step/tick and to convert it in step/s the following formula can be used:
Equation 5
where MIN_SPEED is the integer number stored in the register and tick is the ramp 250 ns.
The available range is from 0 to 976.3 step/s with a resolution of 0.238 step/s.
Any attempt to write the register when the motor is running causes the NOTPERF_CMD flag
to rise.
The FS_SPD register contains the threshold speed. When the actual speed exceeds this
value the step mode is automatically switched to full-step two-phase on. Its value is
expressed in step/tick (format unsigned fixed point 0.18) and to convert it in step/s the
following formula can be used.
Equation 6
If the FS_SPD value is set to h3FF (max.) the system always works in microstepping mode
(SPEED must go beyond the threshold to switch to full-step mode). Setting FS_SPD to zero
does not have the same effect as setting step mode to full-step two phase on: the zero
FS_SPD value is equivalent to a speed threshold of about 7.63 step/s.
The available range is from 7.63 to 15625 step/s with a resolution of 15.25 step/s.
9.1.10 TVAL_HOLD, TVAL_RUN, TVAL_ACC and TVAL_DEC
The TVAL_HOLD register contains the current value that is assigned to the torque
regulation DAC when the motor is stopped.
The TVAL_RUN register contains the current value that is assigned to the torque regulation
DAC when the motor is running at constant speed.
The TVAL_ACC register contains the current value that is assigned to the torque regulation
DAC during acceleration.
The TVAL_DEC register contains the current value that is assigned to the torque regulation
DAC during deceleration.
The available range is from 31.25 mA to 4 A with a resolution of 31.25 mA, as shown in
Tab le 1 2.
Table 12. Torque regulation by TVAL_HOLD, TVAL_ACC, TVAL_DEC and TVAL_RUN
registers
TVAL_X [6 … 0] Output current amplitude
0 0 0 0 0 0 0 31.25 mA
0 0 0 0 0 0 1 62.5 mA
…
…
…
…
…
…
…
1 1 1 1 1 1 0 3.969 A
1 1 1 1 1 1 1 4 A
…
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9.1.11 T_FAST
The T_FAST register contains the maximum fast decay time (TOFF_FAST) and the
maximum fall step time (FALL_STEP) used by the current control system (see Section 7.2
on page 34 and 7.3 on page 36 for details):
Bit 7Bit 6Bit 5Bit 4Bit 3Bit 2Bit 1Bit 0
TOFF_FASTFAST_STEP
The available range for both parameters is from 2 µs to 32 µs.
TOFF_FAST [3 … 0] FAST_STEP [3 … 0] Fast decay time
0 0 0 0 2 µs
0 0 0 1 4 µs
…
1 1 1 0 30 µs
1 1 1 1 32 µs
…
Table 13. T_FAST register
Table 14. Maximum fast decay times
…
…
…
Any attempt to write to the register when the motor is running causes the command to be
ignored and NOTPERF_CMD to rise (see Section 9.1.19 on page 52).
9.1.12 TON_MIN
The TON_MIN register contains the minimum ON time value used by the current control
system (see Section 7.2 on page 34).
The available range for both parameters is from 0.5 µs to 64 µs.
0 0 0 0 0 0 0 0.5 µs
0 0 0 0 0 0 1 1 µs
…
1 1 1 1 1 1 0 63.5 µs
1 1 1 1 1 1 1 64 µs
Any attempt to write to the register when the motor is running causes the command to be
ignored and the NOTPERF_CMD to rise (see Section 9.1.19).
…
Table 15. Minimum ON time
TON_MIN [6 … 0] Time
…
…
…
…
…
…
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Programming manualL6472
9.1.13 TOFF_MIN
The TOFF_MIN register contains the minimum OFF time value used by the current control
system (see Section 7.1 on page 33 for details).
The available range for both parameters is from 0.5 µs to 64 µs.
TOFF_MIN [6 … 0]Time
0 0 0 0 0 0 0 0.5 µs
0 0 0 0 0 0 1 1 µs
…
1 1 1 1 1 1 0 63.5 µs
1 1 1 1 1 1 1 64 µs
…
…
Table 16. Minimum OFF time
…
…
…
…
…
Any attempt to write to the register when the motor is running causes the command to be
ignored and NOTPERF_CMD to rise (see Section 9.1.19 on page 52).
9.1.14 ADC_OUT
The ADC_OUT register contains the result of the analog-to-digital conversion of the ADCIN
pin voltage.
Any attempt to write to the register causes the command to be ignored and the
NOTPERF_CMD flag to rise (see Section 9.1.19).
VADCIN/ VREG ADC_OUT [4.0] Output current amplitude
Table 17. ADC_OUT value and torque regulation feature
0 0 0 0 0 0 125 mA
1/32 0 0 0 0 1 250 mA
…
30/32 1 1 1 1 0 3.875 A
31/32 1 1 1 1 1 4 A
…
…
…
…
…
…
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9.1.15 OCD_TH
The OCD_TH register contains the overcurrent threshold value (see Section 6.9 on page 28
for details). The available range is from 375 mA to 6 A, steps of 375 mA, as shown in
Tab le 1 8.
0 0 0 0 375 mA
0 0 0 1 750 mA
…
1 1 1 0 5.625 A
1 1 1 1 6 A
Table 18. Overcurrent detection threshold
OCD_TH [3 … 0] Overcurrent detection threshold
…
…
…
…
9.1.16 STEP_MODE
The STEP_MODE register has the following structure:
Bit 7 Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0
SYNC_EN SYNC_SEL 1
1. When the register is written this bit should be set to 1.
When the STEP_MODE register is written, the bit #3 is to be set to 1, otherwise anomalous
behaviors could occur.
Table 19. STEP_MODE register
(1)
STEP_SEL
The STEP_SEL parameter selects one of five possible stepping modes:
STEP_SEL[2 … 0] Step mode
0 0 0 Full-step
0 0 1 Half-step
0 1 0 1/4 microstep
0 1 1 1/8 microstep
1 X X 1/16 microstep
Table 20. Step mode selection
Every time the step mode is changed, the electrical position (i.e. the point of microstepping
sine wave that is generated) is reset to the first microstep.
Warning:Every time STEP_SEL is changed the value in the ABS_POS
register looses meaning and should be reset.
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Any attempt to write the register when the motor is running causes the command to be
ignored and the NOTPERF_CMD flag to rise (see Section 9.1.19).
When when SYNC_EN bit is set low, BUSY
commands execution, otherwise, when the SYNC_EN bit is set high, the BUSY
/SYNC output is forced low during the
/SYNC
output provides a clock signal according to the SYNC_SEL parameter.
The synchronization signal is obtained starting from the electrical position information
(EL_POS register) according to Tab le 22 :
Table 22. SYNC signal source
FS
SYNC_SEL[2 … 0] Source
0 0 0 EL_POS[7]
0 0 1 EL_POS[6]
0 1 0 EL_POS[5]
0 1 1 EL_POS[4]
1 0 0 EL_POS[3]
1 0 1 UNUSED
1 1 0 UNUSED
1 1 1 UNUSED
1. When this value is selected the BUSY output is forced low.
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L6472Programming manual
9.1.17 ALARM_EN
The ALARM_EN register allows the selection of which alarm signals are used to generate
the FLAG output. If the respective bit of the ALARM_EN register is set high, the alarm
condition forces the FLAG pin output down.
ALARM_EN bit Alarm condition
0 (LSB) Overcurrent
1 Thermal shutdown
2 Thermal warning
3 Undervoltage
4 UNUSED
5 UNUSED
6 Switch turn-on event
7 (MSB) Wrong or non-performable command
Table 23. ALARM_EN register
9.1.18 CONFIG
The CONFIG register has the following structure:
Bit 15 Bit 14 Bit 13 Bit 12 Bit 11 Bit 10 Bit 9 Bit 8
PRED_EN TSW POW_SR
Bit 7 Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0
OC_SD RESERVED EN_TQREG SW_MODE EXT_CLK OSC_SEL
Table 24. CONFIG register
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Programming manualL6472
The OSC_SEL and EXT_CLK bits set the system clock source:
The SW_MODE bit sets the external switch to act as HardStop interrupt or not:
Table 26. External switch hard stop interrupt mode
SW_MODE Switch mode
0 HardStop interrupt
1 User disposal
The OC_SD bit sets if an overcurrent event causes or not the bridges to turn off; the OCD
flag in the STATUS register is forced low anyway:
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Table 27. Overcurrent event
OC_SD Overcurrent event
1 Bridges shut down
0 Bridges do not shut down
The POW_SR bits set the slew rate value of the power bridge output:
1. See S
Table 28. Programmable power bridge output slew rate values
POW_SR [1 … 0] Output slew rate (1) [V/s]
0 0 320
0 1 75
1 0 110
1 1 270
Rout_r
and S
parameters in Table 5 on page 11 for details.
Rout_f
(1)
The TQREG bit sets if the torque regulation (see Section 7.4 on page 37) is performed
through ADCIN voltage (external) or the TVAL_HOLD, TVAL_ACC, TVAL_DEC and
TVAL_RUN registers (internal):
Table 29. External torque regulation enable
TQREG External torque regulation enable
0 Internal registers
1 ADC input
The TSW parameter is used by the current control system and it sets the target switching
period.
TSW [4 … 0] Switching period
0 0 0 0 0 4 µs (250 kHz)
0 0 0 0 1 4 µs (250 kHz)
0 0 0 1 0 8 µs (125 kHz)
…
…
…
1 1 1 1 1 124 µs (8 kHz)
Table 30. Switching period
…
…
…
Any attempt to write the CONFIG register when the motor is running causes the command
to be ignored and the NOTPERF_CMD flag to rise (see Section 9.1.19).
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9.1.19 STATUS
Bit 15 Bit 14 Bit 13 Bit 12 Bit 11 Bit 10 Bit 9 Bit 8
SCK_MOD X X OCD TH_SD TH_WRN UVLO WRONG_CMD
Bit 7 Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0
NOTPERF_CMD MOT_STATUS DIR SW_EVN SW_F BUSY HiZ
Table 31. STATUS register
When the HiZ flag is high it indicates that the bridges are in high-impedance state. Any
motion command causes the device to exit from High Z state (HardStop and SoftStop
included), unless error flags forcing a High Z state are active.
The UVLO flag is active low and is set by an undervoltage lockout or reset event (power-up
included). The TH_WRN, TH_SD, OCD flags are active low and indicate respectively
thermal warning, thermal shutdown and overcurrent detection events.
The NOTPERF_CMD and WRONG_CMD flags are active high and indicate, respectively,
that the command received by SPI can't be performed or does not exist at all. The SW_F
reports the SW input status (low for open and high for closed).
The SW_EVN flag is active high and indicates a switch turn-on event (SW input falling
edge).
The UVLO, TH_WRN, TH_SD, OCD, NOTPERF_CMD, WRONG_CMD and SW_EVN flags
are latched: when the respective conditions make them active (low or high) they remain in
that state until a GetStatus command is sent to the IC.
The BUSY bit reflects the BUSY pin status. The BUSY flag is low when a constant speed,
positioning or motion command is under execution and is released (high) after the
command has been completed.
The SCK_MOD bit is an active high flag indicating that the device is working in step-clock
mode. In this case the step-clock signal should be provided through the STCK input pin. The
DIR bit indicates the current motor direction:
Table 32. STATUS register DIR bit
DIR Motor direction
1 Forward
0 Reverse
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MOT_STATUS indicates the current motor status:
0 0 Stopped
0 1 Acceleration
1 0 Deceleration
1 1 Constant speed
Table 33. STATUS register MOT_STATUS bits
MOT_STATUS Motor status
Any attempt to write to the register causes the command to be ignored and the
NOTPERF_CMD to rise.
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9.2 Application commands
A summary of commands is given in Tab le 3 4.
Command mnemonic Command binary code Action
NOP 000 0 0 00 0 Nothing
SetParam (PARAM, VALUE) 000 [PARAM] Writes VALUE in the PARAM register
GetParam (PARAM) 001 [PARAM] Returns the stored value in the PARAM register
Run (DIR, SPD) 010 1 0 00 DIR Sets the target speed and the motor direction
StepClock (DIR) 010 1 1 00 DIR
Move (DIR,N_STEP) 010 0 0 00 DIR
Table 34. Application commands
[7 … 5] [4] [3] [2 …1] [0]
Puts the device into step-clock mode and
imposes DIR direction
Makes N_STEP (micro) steps in DIR direction
(non-performable when motor is running)
GoTo (ABS_POS) 011 0 0 00 0
GoTo_DIR (DIR,ABS_POS) 011 0 1 00 DIR
GoUntil (ACT,DIR,SPD) 100 0 ACT 01 DIR
ReleaseSW (ACT, DIR) 100 1 ACT 01 DIR
GoHome 011 1 0 00 0 Brings the motor in HOME position
GoMark 011 1 1 00 0 Brings the motor in MARK position
ResetPos 110 1 1 00 0
ResetDevice 110 0 0 00 0 Device is reset to power-up conditions
SoftStop 101 1 0 00 0 Stops motor with a deceleration phase
HardStop 101 1 1 00 0 Stops motor immediately
SoftHiZ 101 0 0 00 0
HardHiZ 101 0 1 00 0
GetStatus 110 1 0 00 0 Returns the STATUS register value
RESERVED 111 0 1 01 1 RESERVED COMMAND
Brings motor in ABS_POS position (minimum
path)
Brings motor in ABS_POS position forcing DIR
direction
Performs a motion in DIR direction with speed
SPD until SW is closed, the ACT action is
executed then a SoftStop takes place
Performs a motion in DIR direction at minimum
speed until the SW is released (open), the ACT
action is executed then a HardStop takes place
Resets the ABS_POS register (set HOME
position)
Puts the bridges in high-impedance status after
a deceleration phase
Puts the bridges in high-impedance status
immediately
RESERVED 111 1 1 00 0 RESERVED COMMAND
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9.2.1 Command management
The host microcontroller can control motor motion and configure the L6472 device through
a complete set of commands.
All commands are composed by a single byte. After the command byte, some argument
bytes should be needed (see Figure 21). Argument length can vary from 1 to 3 bytes.
Figure 21. Command with 3-byte argument
By default the device returns an all zero response for any received byte, the only exceptions
are GetParam and GetStatus commands. When one of these commands is received the
following response bytes represent the related register value (see Figure 22).
Response length can vary from 1 to 3 bytes.
Figure 22. Command with 3-byte response
During response transmission, new commands can be sent. If a command requiring
a response is sent before the previous response is completed, the response transmission is
aborted and the new response is loaded into the output communication buffer (see
Figure 23).
Figure 23. Command response aborted
When a byte that does not correspond to a command is sent to the IC, it is ignored and the
WRONG_CMD flag in the STATUS register is raised (see Section 9.1.19).
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9.2.2 NOP
Bit 7 Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0
0 0 0 0 0 0 0 0 From host
Table 35. NOP command structure
Nothing is performed.
9.2.3 SetParam (PARAM, VALUE)
Bit 7 Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0
0 0 0 PARAM From host
The SetParam command sets the PARAM register value equal to VALUE; PARAM is the
respective register address listed in Table 9 on page 40.
The command should be followed by the new register VALUE (most significant byte first).
The number of bytes composing the VALUE argument depends on the length of the target
register (see Tabl e 9).
Table 36. SetParam command structure
VALUE Byte 2 (if needed)
VALUE Byte 1 (if needed)
VALUE Byte 0
Some registers cannot be written (see Table 9); any attempt to write one of these registers
causes the command to be ignored and the WRONG_CMD flag to rise at the end of the
command byte as if an unknown command code was sent (see Section 9.1.18 on page 49).
Some registers can only be written in particular conditions (see Tab le 9); any attempt to
write one of these registers when the conditions are not satisfied causes the command to be
ignored and the NOTPERF_CMD flag to rise at the end of last argument byte (see
Section 9.1.19 on page 52).
Any attempt to set an inexistent register (wrong address value) causes the command to be
ignored and the WRONG_CMD flag to rise at the end of the command byte as if an
unknown command code was sent.
9.2.4 GetParam (PARAM)
Bit 7 Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0
0 0 1 PARAM From host
Table 37. GetParam command structure
ANS Byte 2 (if needed) To host
ANS Byte 1 (if needed) To host
ANS Byte 0 To host
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This command reads the current PARAM register value; PARAM is the respective register
address listed in Table 9 on page 40.
The command response is the current value of the register (most significant byte first). The
number of bytes composing the command response depends on the length of the target
register (see Tabl e 9).
The returned value is the register one at the moment of GetParam command decoding. If
the register value changes after this moment, the response is not accordingly updated.
All registers can be read anytime.
Any attempt to read an inexistent register (wrong address value) causes the command to be
ignored and WRONG_CMD flag to rise at the end of command byte as if an unknown
command code is sent.
9.2.5 Run (DIR, SPD)
Bit 7 Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0
0 1 0 1 0 0 0 DIR From host
X X X X SPD (Byte 2) From host
Table 38. Run command structure
SPD (Byte 1) From host
SPD (Byte 0) From host
The Run command produces a motion at SPD speed; the direction is selected by the DIR
bit: '1' forward or '0' reverse. The SPD value is expressed in step/tick (format unsigned fixed
point 0.28) which is the same format as the SPEED register (see Section 9.1.4 on page 42).
Note:The SPD value should be lower than MAX_SPEED and greater than MIN_SPEED
otherwise the Run command is executed at MAX_SPEED or MIN_SPEED respectively.
This command keeps the BUSY flag low until the target speed is reached.
This command can be given anytime and is immediately executed.
9.2.6 StepClock (DIR)
Bit 7 Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0
Table 39. StepClock command structure
0 1 0 1 1 0 0 DIR From host
The StepClock command switches the device in step-clock mode (see Section 6.7.5 on
page 26) and imposes the forward (DIR = '1') or reverse (DIR = '0') direction.
When the device is in step-clock mode the SCK_MOD flag in the STATUS register is raised
and the motor is always considered stopped (see Section 6.7.5 and Section 9.1.18 on page
49).
The device exits from step-clock mode when a constant speed, absolute positioning or
motion command is sent through SPI. Motion direction is imposed by the respective
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StepClock command argument and can by changed by a new StepClock command without
exiting step-clock mode.
Events that cause bridges to be forced into high-impedance state (overtemperature,
overcurrent, etc.) do not cause the device to leave step-clock mode. StepClock command
does not force the BUSY flag low. This command can only be given when the motor is
stopped. If a motion is in progress the motor should be stopped and it is then possible to
send a StepClock command.
Any attempt to perform a StepClock command when the motor is running causes the
command to be ignored and the NOTPERF_CMD flag to rise (see Section 9.1.19 on page
52).
9.2.7 Move (DIR, N_STEP)
Bit 7 Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0
0 1 0 0 0 0 0 DIR From host
X X N_STEP (Byte 2) From host
The move command produces a motion of N_STEP microsteps; the direction is selected by
the DIR bit ('1' forward or '0' reverse).
The N_STEP value is always in agreement with the selected step mode; the parameter
value unit is equal to the selected step mode (full, half, quarter, etc.).
This command keeps the BUSY flag low until the target number of steps is performed. This
command can only be performed when the motor is stopped. If a motion is in progress the
motor must be stopped and it is then possible to perform a Move command.
Any attempt to perform a Move command when the motor is running causes the command
to be ignored and the NOTPERF_CMD flag to rise (see Section 9.1.19).
9.2.8 GoTo (ABS_POS)
Table 40. Move command structure
N_STEP (Byte 1) From host
N_STEP (Byte 0) From host
Table 41. GoTo command structure
Bit 7 Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0
0 1 1 0 0 0 0 0 From host
X X ABS_POS (Byte 2) From host
ABS_POS (Byte 1) From host
ABS_POS (Byte 0) From host
The GoTo command produces a motion to the ABS_POS absolute position through the
shortest path. The ABS_POS value is always in agreement with the selected step mode; the
parameter value unit is equal to the selected step mode (full, half, quarter, etc.).
The GoTo command keeps the BUSY flag low until the target position is reached.
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This command can only be given when the previous motion command has been completed
(BUSY flag released).
Any attempt to perform a GoTo command when a previous command is under execution
(BUSY low) causes the command to be ignored and the NOTPERF_CMD flag to rise
(see Section 9.1.19 on page 52).
9.2.9 GoTo_DIR (DIR, ABS_POS)
Bit 7 Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0
0 1 1 0 1 0 0 DIR From host
X X ABS_POS (Byte 2) From host
Table 42. GoTo_DIR command structure
ABS_POS (Byte 1) From host
ABS_POS (Byte 0) From host
The GoTo_DIR command produces a motion to the ABS_POS absolute position imposing
a forward (DIR = '1') or a reverse (DIR = '0') rotation. The ABS_POS value is always in
agreement with the selected step mode; the parameter value unit is equal to the selected
step mode (full, half, quarter, etc.).
The GoTo_DIR command keeps the BUSY flag low until the target speed is reached. This
command can only be given when the previous motion command has been completed
(BUSY flag released).
Any attempt to perform a GoTo_DIR command when a previous command is under
execution (BUSY low) causes the command to be ignored and the NOTPERF_CMD flag to
rise (see Section 9.1.19).
9.2.10 GoUntil (ACT, DIR, SPD)
Table 43. GoUntil command structure
Bit 7 Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0
1 0 0 0 ACT 0 1 DIR From host
X X X X SPD (Byte 2) From host
SPD (Byte 1) From host
SPD (Byte 0) From host
The GoUntil command produces a motion at SPD speed imposing a forward (DIR = '1') or
a reverse (DIR = '0') direction. When an external switch turn-on event occurs (see
Section 6.13 on page 30), the ABS_POS register is reset (if ACT = '0') or the ABS_POS
register value is copied into the MARK register (if ACT = '1'); the system then performs a
SoftStop command.
The SPD value is expressed in step/tick (format unsigned fixed point 0.28) which is the
same format as the SPEED register (see Section 9.1.4 on page 42).
The SPD value should be lower than MAX_SPEED and greater than MIN_SPEED,
otherwise the target speed is imposed at MAX_SPEED or MIN_SPEED respectively.
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If the SW_MODE bit of the CONFIG register is set low, the external switch turn-on event
causes a HardStop interrupt instead of the SoftStop one (see Section 6.13 on page 30 and
9.1.18 on page 49).
This command keeps the BUSY flag low until the switch turn-on event occurs and the motor
is stopped. This command can be given anytime and is immediately executed.
9.2.11 ReleaseSW (ACT, DIR)
Bit 7 Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0
1 0 0 1 ACT 0 1 DIR From host
The ReleaseSW command produces a motion at minimum speed imposing a forward
(DIR = '1') or reverse (DIR = '0') rotation. When SW is released (opened) the ABS_POS
register is reset (ACT = '0') or the ABS_POS register value is copied into the MARK register
(ACT = '1'); the system then performs a HardStop command.
Note that resetting the ABS_POS register is equivalent to setting the HOME position.
If the minimum speed value is less than 5 step/s or low speed optimization is enabled, the
motion is performed at 5 step/s.
The ReleaseSW command keeps the BUSY flag low until the switch input is released and
the motor is stopped.
9.2.12 GoHome
Bit 7 Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0
0 1 1 1 0 0 0 0 From host
Table 44. ReleaseSW command structure
Table 45. GoHome command structure
The GoHome command produces a motion to the HOME position (zero position) via the
shortest path.
Note that this command is equivalent to the “GoTo(0…0)” command. If a motor direction is
mandatory the GoTo_DIR command must be used (see Section 9.2.9).
The GoHome command keeps the BUSY flag low until the home position is reached. This
command can only be given when the previous motion command has been completed. Any
attempt to perform a GoHome command when a previous command is under execution
(BUSY low) causes the command to be ignored and the NOTPERF_CMD to rise (see
Section 9.1.19 on page 52).
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9.2.13 GoMark
Bit 7 Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0
0 1 1 1 1 0 0 0 From host
The GoMark command produces a motion to the MARK position performing the minimum
path.
Note that this command is equivalent to the “GoTo (MARK)” command. If a motor direction
is mandatory the GoTo_DIR command must be used.
The GoMark command keeps the BUSY flag low until the MARK position is reached. This
command can only be given when the previous motion command has been completed
(BUSY flag released).
Any attempt to perform a GoMark command when a previous command is under execution
(BUSY low) causes the command to be ignored and the NOTPERF_CMD flag to rise (see
Section 9.1.19 on page 52).
9.2.14 ResetPos
Bit 7 Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0
1 1 0 1 1 0 0 0 From host
Table 46. GoMark command structure
Table 47. ResetPos command structure
The ResetPos command resets the ABS_POS register to zero. The zero position is also
defined as HOME position (see Section 6.5 on page 23).
9.2.15 ResetDevice
Bit 7 Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0
1 1 0 0 0 0 0 0 From host
The ResetDevice command resets the device to power-up conditions (seeSection 6.1 on
page 20).
Note:At power-up the power bridges are disabled.
Table 48. ResetDevice command structure
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9.2.16 SoftStop
Bit 7 Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0
1 0 1 1 0 0 0 0 From host
The SoftStop command causes an immediate deceleration to zero speed and a consequent
motor stop; the deceleration value used is the one stored in the DEC register (see
Section 9.1.6 on page 42).
When the motor is in high-impedance state, a SoftStop command forces the bridges to exit
from high-impedance state; no motion is performed.
This command can be given anytime and is immediately executed. This command keeps
the BUSY flag low until the motor is stopped.
9.2.17 HardStop
Bit 7 Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0
1 0 1 1 1 0 0 0 From host
The HardStop command causes an immediate motor stop with infinite deceleration.
Table 49. SoftStop command structure
Table 50. HardStop command structure
When the motor is in high-impedance state, a HardStop command forces the bridges to exit
from high-impedance state; no motion is performed.
This command can be given anytime and is immediately executed. This command keeps
the BUSY flag low until the motor is stopped.
9.2.18 SoftHiZ
Bit 7 Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0
1 0 1 0 0 0 0 0 From host
The SoftHiZ command disables the power bridges (high-impedance state) after
a deceleration to zero; the deceleration value used is the one stored in the DEC register
(see Section 9.1.6). When bridges are disabled the HiZ flag is raised.
When the motor is stopped, a SoftHiZ command forces the bridges to enter high-impedance
state.
This command can be given anytime and is immediately executed. This command keeps
the BUSY flag low until the motor is stopped.
Table 51. SoftHiZ command structure
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9.2.19 HardHiZ
Bit 7 Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0
1 0 1 0 1 0 0 0 From host
The HardHiZ command immediately disables the power bridges (high-impedance state) and
raises the HiZ flag.
When the motor is stopped, a HardHiZ command forces the bridges to enter highimpedance state.
This command can be given anytime and is immediately executed.
This command keeps the BUSY flag low until the motor is stopped.
9.2.20 GetStatus
Bit 7 Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0
1 1 0 1 0 0 0 0 From host
Table 52. HardHiZ command structure
Table 53. GetStatus command structure
STATUS MSByte To host
STATUS LSByte To host
The GetStatus command returns the STATUS register value.
The GetStatus command resets the STATUS register warning flags. The command forces
the system to exit from any error state. The GetStatus command does NOT reset the HiZ
flag.
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Package informationL6472
10 Package information
In order to meet environmental requirements, ST offers these devices in different grades of
ECOPACK
specifications, grade definitions and product status are available at: www.st.com.
ECOPACK is an ST trademark.
®
packages, depending on their level of environmental compliance. ECOPACK
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10.1 HTSSOP28 package information
Figure 24. HTSSOP28 package outline
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Table 54. HTSSOP28 package mechanical data
Dimensions (mm)
Symbol
Min. Typ. Max.
A 1.2
A1 0.15
A2 0.8 1.0 1.05
b 0.19 0.3
c 0.09 0.2
(1)
D
9.6 9.7 9.8
D1 5.5
E 6.2 6.4 6.6
E1
(2)
4.3 4.4 4.5
E2 2.8
e 0.65
L 0.45 0.6 0.75
L1 1.0
K 0° 8°
aaa 0.1
1. Dimension “D” does not include mold flash, protrusions or gate burrs. Mold flash, protrusions or gate burrs
do not exceed 0.15 mm per side.
2. Dimension “E1” does not include interlead flash or protrusions. Interlead flash or protrusions do not exceed
Removed “dSPIN™” from the main title on page 1.
Updated Table 6 on page 17 (added label HTSSOP and POWERSO
column).
Minor modifications throughout document.
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