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AS5262
12-Bit Magnetic Angle Position Sensor
General Description
The AS5262 is a contactless magnetic angle position sensor for
accurate angular measurement over a full turn of 360°. A sub
range can be programmed to achieve the best resolution for
the application. It is a system-on-chip, combining integrated
Hall elements, analog front end, digital signal processing and
best in class automotive protection features in a single device.
To measure the angle, only a simple two-pole magnet, rotating
over the center of the chip, is required. The magnet may be
placed above or below the IC.
The absolute angle measurement provides instant indication of
the magnet’s angular position with a resolution of
0.022° = 16384 positions per revolution. According to this
resolution the adjustment of the application specific
mechanical positions are possible. The angular output data is
available over a 12 bit ratiometric analog output.
The AS5262 operates at a supply voltage of 5V and the supply
and output pins are protected against overvoltage up to +20V.
In addition the supply pins are protected against reverse
polarity up to –20V.
Figure 1:
Typical Arrangement of AS5262 and Magnet
Ordering Information and Content Guide appear at end of
datasheet.
ams Datasheet
[v1-04] 2015-Dec-07
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AS5262 − General Description
Key Benefits & Features
The benefits and features of AS5262, 12-Bit Magnetic Angle
Position Sensor are listed below:
Figure 2:
Added Value of Using AS5262
Benefits
Features
• Great flexibility on angular excursion
• 360º contactless high resolution angular position sensing
• Simple programming
• User programmable start and end point of the
application region
• Saw tooth mode 1-4 slopes per revolution
• Clamping levels
• Transition point
• Failure diagnostics
• Broken GND and VDD detection for all external load cases
• High-Resolution output signal
• Analog output ratiometric to VDD
• Ideal for applications in harsh
environments due to contactless
position sensing
• Wide temperature range: - 40°C to 150°C
• Stacked die redundant approach
• Small Pb-free package: MLF 16 6x6 (with dimple)
Applications
The AS5262 is ideal for automotive applications like:
• Throttle and valve position sensing
• Gearbox position sensor
• Tumble flap
• Chassis height level
• Pedal position sensing
• Contactless potentiometers
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ams Datasheet
[v1-04] 2015-Dec-07
AS5262 − General Description
Block Diagram
The functional blocks of this device are shown below:
Figure 3:
AS5262 Block Diagram
VDD3V3_T
VDD3V3_B
High Voltage/
Reverse Polarity
Protection
VDD_T
AS5262
VDD_B
Hall Array
Frontend
Amplifier
ADC
Sin
Cos
DSP
CORDIC
Controller
12
Single Pin
Interface
(UART)
12-bit
DAC
OUT
Driver
OUT_T
OUT_B
OTP Register
(Programming
Parameters)
GND_B
ams Datasheet
[v1-04] 2015-Dec-07
GND_T
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AS5262 − Pin Assignment
Pin Assignment
Figure 4:
MLF-16 Pin Configuration (Top View)
OUT_T
2
OUT_B
TP1_B
VDD_T
1
VDD_B
TP1_T
16
15
14
13
12
S_B
11
S_T
Epad
VDD3V3_T
3
10
TP3_B
VDD3V3_B
4
9
TP3_T
5
6
7
8
GND_T
GND_B
TP2_T
TP2_B
Pin Description
Figure 5:
MLF-16 Pin Description
Pin
Number
Pin
Name
1
TP1_T
Pin Type
DIO/AIO
Multi purpose pin
2
TP1_B
3
VDD3V3_T
Description
Test pin for fabrication. Connected to ground in the
application.
Test pin for fabrication. Connected to ground in the
application.
Output of the LDO. 1μF required.
AIO
4
VDD3V3_B
5
GND_T
Output of the LDO. 1μF required.
Ground pin. Connected to ground in the application.
Supply pin
6
GND_B
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Ground pin. Connected to ground in the application.
ams Datasheet
[v1-04] 2015-Dec-07
AS5262 − Pin Assignment
Pin
Number
Pin
Name
7
TP2_T
8
TP2_B
9
TP3_T
Test pin for fabrication. Left open in the application.
10
TP3_B
Test pin for fabrication. Left open in the application.
11
S_T
Pin Type
Description
Test pin for fabrication. Connected to ground in the
application.
DIO/AIO
Multi purpose pin
Test pin for fabrication. Connected to ground in the
application.
Test pin for fabrication. Connected to OUT_T in the
application.
( special case for the connection possible → 4-wire mode)
AIO
12
S_B
13
OUT_T
Test pin for fabrication. Connected to OUT_B in the
application.
( special case for the connection possible ® 4-wire mode)
Analog output
pin
14
OUT_B
15
VDD_T
Output pin analog output. Over this pin the programming
is possible.
Output pin analog output. Over this pin the programming
is possible.
Positive supply pin. This pin is over voltage protected.
Supply pin
16
VDD_B
ams Datasheet
[v1-04] 2015-Dec-07
Positive supply pin. This pin is over voltage protected.
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AS5262 − Absolute Maximum Ratings
Absolute Maximum Ratings
Stresses beyond those listed in Absolute Maximum Ratings may
cause permanent damage to the device. These are stress ratings
only, and functional operation of the device at these or any
other conditions beyond those indicated in Electrical
Characteristics is not implied. Exposure to absolute maximum
rating conditions for extended periods may affect device
reliability.
Figure 6:
Absolute Maximum Ratings
Symbol
Parameter
Min
Max
Units
Comments
Electrical Parameters
VDD
DC supply voltage at pin
VDD Overvoltage
-20
20
V
No operation
VOUT
Output voltage OUT
-0.3
20
V
Permanent
Vdiff
Voltage difference at pin
VDD and OUT
-20
20
V
VDD3V3
DC supply voltage at pin
VDD3V3
-0.3
5
V
Input current
(latchup immunity)
-100
100
mA
Norm: AEC-Q100-004
kV
Norm: AEC-Q100-002
Iscr
Electrostatic Discharge
ESD
Electrostatic discharge
±2
Temperature Ranges and Storage Conditions
TStrg
Storage temperature
TBody
Body temperature
RHNC
Relative humidity
non-condensing
MSL
Moisture Sensitivity Level
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-55
150
5
3
ºC
Min -67ºF; Max 302ºF
260
ºC
The reflow peak soldering
temperature (body
temperature) specified is in
accordance with IPC/JEDEC
J-STD-020 “Moisture/Reflow
Sensitivity Classification for
Non-Hermetic Solid State
Surface Mount Devices”. The
lead finish for Pb-free leaded
packages is matte tin (100% Sn).
85
%
Represents a maximum floor life
time of 168h
ams Datasheet
[v1-04] 2015-Dec-07
AS5262 − Electrical Characteristics
Electrical Characteristics
Operating Conditions
In this specification, all the defined tolerances for external
components need to be assured over the whole operation
conditions range and also over lifetime.
Figure 7:
Operating Conditions
Symbol
Parameter
TAMB
Ambient temperature
Isupp
Supply current
VDD
Supply voltage at pin VDD
Conditions
Min
Typ
-40
Only for one die. Must be
multiplied by 2
4.5
5.0
Max
Units
150
ºC
12
mA
5.5
V
Magnetic Input Specification
TAMB = -40ºC to 150ºC, VDD = 4.5V to 5.5V (5V operation), unless
otherwise noted.
Two-Pole Cylindrical Diametrically Magnetized Source
Figure 8:
Magnetic Input Specification
Symbol
Bpk
Bpkext
Boff
Disp
Parameter
Conditions
Min
Magnetic input field
amplitude
Required vertical component of
the magnetic field strength on
the die’s surface, measured
along a concentric circle with a
radius of 1.25 mm
Magnetic input field
amplitude
(extended) default setting
Required vertical component of
the magnetic field strength on
the die’s surface, measured
along a concentric circle with a
radius of 1.25 mm. Increased
sensor output noise.
Magnetic offset
Constant magnetic stray field
Field non-linearity
Including offset gradient
Displacement radius
Offset between defined device
center and magnet axis.
Dependent on the selected
magnet. Including Eccentricity.
ams Datasheet
[v1-04] 2015-Dec-07
Typ
Max
Units
30
70
mT
10
90
mT
±5
mT
5
%
1
mm
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AS5262 − Electrical Characteristics
Electrical System Specifications
TAMB = -40ºC to 150ºC, V DD = 4.5V to 5.5V (5V operation),
Magnetic Input Specification, unless otherwise noted.
Figure 9:
Electrical System Specifications
Symbol
Parameter
RES
Resolution Analog Output
INLopt
INLtemp
Conditions
Min
Typ
Max
Units
Range > 90º
1LSB=1.221mV typ
12
bit
Integral non-linearity
(optimum)
Best aligned reference magnet
at 25ºC over full turn 360º
0.5
deg
Integral non-linearity
(optimum)
Best aligned reference magnet
over temperature -40º to 150º
over full turn 360º
0.9
deg
INL
Integral non-linearity
Best aligned reference magnet
over temperature -40º -150º
over full turn 360º and
displacement
1.4
deg
DNL
Differential non-linearity
Monolitic
0.05
deg
ON
Output noise
(360º segment)
1 LSB after filter peak/peak rms
value
0.2
%/VDD
tPwrUp
Power-up time 0-5V
See Figure 10
10
ms
tdelay
System propagation delay
absolute output: delay of
ADC, DSP and absolute
interface
10kOhm, 100 μF RC filter
300
μs
Figure 10:
Power-Up Timing Diagram
VDD
4.5V
OUT pin in HiZ
First Valid Data on OUT pin
tPwrUp
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ams Datasheet
[v1-04] 2015-Dec-07
AS5262 − Electrical Characteristics
Timing Characteristics
Figure 11:
Timing Conditions
Symbol
Parameter
TDETWD
WachDog error detection time
Conditions
Min
Typ
Max
Units
12
ms
Power Management - Supply Monitor
Figure 12:
Power Management - Supply Monitor Conditions
Symbol
Parameter
Conditions
Min
Typ
Max
Units
VDDUVTH
VDD undervoltage upper
threshold
3.5
4.0
4.5
V
VDDUVTL
VDD undervoltage lower
threshold
3.0
3.5
4.0
V
VDDUVHYS
VDD undervoltage hysteresis
300
500
900
mV
VDDUVDET
VDD undervoltage detection
time
10
50
250
μs
VDDUVREC
VDD undervoltage recovery time
10
50
250
μs
VDDOVTH
VDD overvoltage upper
threshold
6.0
6.5
7.0
V
VDDOVTL
VDD overvoltage lower threshold
5.5
6
6.5
V
VDDOVHYS
VDD overvoltage hysteresis
300
500
900
mV
ANATOVDET
VDD overvoltage detection time
(analog path)
10
50
250
μs
ANATOVREC
VDD overvoltage recovery time
(analog path)
10
50
250
μs
ams Datasheet
[v1-04] 2015-Dec-07
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AS5262 − Detailed Description
Detailed Description
The AS5262 is manufactured in a CMOS process and uses a
spinning current Hall technology for sensing the magnetic field
distribution across the surface of the chip.
This IC consists of two galvanic isolated dies. All following in
and register names refers to one die.
The integrated Hall elements are placed around the center of
the device and deliver a voltage representation of the magnetic
field at the surface of the IC.
Through Sigma-Delta Analog / Digital Conversion and Digital
Signal-Processing (DSP) algorithms, the AS5262 provides
accurate high-resolution absolute angular position
information. For this purpose a Coordinate Rotation Digital
Computer (CORDIC) calculates the angle and the magnitude of
the Hall array signals.
The DSP is also used to provide digital information at the
outputs that indicate movements of the used magnet towards
or away from the device’s surface.
A small low cost diametrically magnetized (two-pole) standard
magnet provides the angular position information.
The AS5262 senses the orientation of the magnetic field and
calculates a 14-bit binary code. This code is mapped to a
programmable output characteristic in analog voltage format.
This signal is available at the pin (OUT).
The application angular region can be programmed in a user
friendly way. The start angle position T1 and the end point T2
can be set and programmed according the mechanical range
of the application with a resolution of 14 bits. In addition the
T1Y and T2Y parameter can be set and programmed according
the application. The transition point 0 to 360 degree can be
shifted using the break point parameter BP. The voltage for
clamping level low CLL and clamping level high CLH can be
programmed with a resolution of 9 bits. Both levels are
individually adjustable.
The output parameters can be programmed in an OTP register.
No additional voltage is required to program the AS5262. The
setting may be overwritten at any time and will be reset to
default when power is cycled. To make the setting permanent,
the OTP register must be programmed by using a lock bit the
content could be frozen for ever.
The AS5262 is tolerant to magnet misalignment and unwanted
external magnetic fields due to differential measurement
technique and Hall sensor conditioning circuitry.
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ams Datasheet
[v1-04] 2015-Dec-07
AS5262 − Detailed Description
Operation
VDD Voltage Monitor
VDD Over Voltage Management. If the supply voltage at pin
VDD exceeds the over-voltage upper threshold for longer than
the detection time the output is turned off. When the over
voltage event has passed and the voltage applied to pin VDD
falls below the over-voltage lower threshold for longer than the
recovery time the device enters the normal mode and the
output is enabled.
VDD Under Voltage Management. When the voltage applied
to the VDD pin falls below the under-voltage lower threshold
for longer than the detection time the output is turned off.
When the voltage applied to the VDD pin exceeds the
under-voltage upper threshold for longer than the detection
time the device enters the normal mode and the output is
enabled.
Analog Output
By default (after programmed CUST_LOCK OTP bit) the analog
output mode is selected. The pin OUT provides an analog
voltage that is proportional to the angle of the rotating magnet
and ratiometric to the supply voltage VDD. It can source or sink
currents up in normal operation. A short circuit protection is in
place and will switch the output driver in high Z in case of an
overload event. Due to an intelligent approach a permanent
short circuit will not damage the device. This is also feasible in
a high voltage condition up to 20 V and at the highest specified
ambient temperature.
After the digital signal processing (DSP) a 12-bit
Digital-to-Analog converter and output stage provides the
output signal.
The DSP maps the application range to the output
characteristic. An inversion of the slope is also programmable
to allow inversion of the rotation direction.
The reference voltage for the Digital-to-Analog converter (DAC)
is taken from VDD. In this mode, the output voltage is
ratiometric to the supply voltage.
An on-chip diagnostic feature handles the error state at the
output. Depending on the failure the output is in HiZ condition
or is driven in the failure band (see Figure 21).
ams Datasheet
[v1-04] 2015-Dec-07
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AS5262 − Detailed Description
Programming Parameters
The analog output characteristic is programmable by OTP.
Depending on the application, the analog output can be
adjusted. The user can program the following application
specific parameters.
Figure 13:
Programming Parameters
T1
Mechanical angle start point
T2
Mechanical angle end point
T1Y
Voltage level at the T1 position
T2Y
Voltage level at the T2 position
CLL
Clamping Level Low
CLH
Clamping Level High
BP
Break point (transition point 0 to 360º)
These parameters are input parameters. Using the available
programming software and programmer these parameters are
converted and finally written into the AS5262 128 bit OTP
memory.
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ams Datasheet
[v1-04] 2015-Dec-07
AS5262 − Detailed Description
Application Specific Angular Range Programming
The application range can be selected by programming T1 with
a related T1Y and T2 with a related T2Y into the AS5262. The
clamping levels CLL and CLH can be programmed independent
from the T1 and T2 position and both levels can be separately
adjusted.
Figure 14:
Programming of an Individual Application Range
90 degree
Application range
electrical range
T2
mechanical range
T1
100%DC
clamping range
high
CLH
CLL
0 degree
T2Y
180 degree
CLH
T1Y
BP
CLL
0
clamping range
low
T1
T2
270 degree
Figure 14 shows a simple example of the selection of the range.
The mechanical starting point T1 and the mechanical end point
T2 are defining the mechanical range. A sub range of the
internal CORDIC output range is used and mapped to the
needed output characteristic. The analog output signal has 12
bit, hence the level T1Y and T2Y can be adjusted with this
resolution. As a result of this level and the calculated slope the
clamping region low is defined. The break point BP defines the
transition between CLL and CLH. In this example the BP is set
to 0 degree. The BP is also the end point of the clamping level
high CLH. This range is defined by the level CLH and the
calculated slope. Both clamping levels can be set
independently form each other.
ams Datasheet
[v1-04] 2015-Dec-07
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AS5262 − Detailed Description
Application Specific Programming of the Break Point
The break point BP can be programmed as well with 14 bits.
This is important when the default transition point is inside the
application range. In such a case the default transition point
must be shifted out of the application range. The parameter BP
defines the new position.
Figure 15:
Individual Programming of the Break Point BP
90 degree
Application range
electrical range
T2
mechanical range
T1
100%DC
CLH
clamping range
high
CLH
0 degree
T2Y
180 degree
CLL
T1Y
CLL
BP
0
clamping range
low
T1
T2
clamping range
low
270 degree
Full Scale Mode
Duty Cycle
Figure 16:
Full Scale Mode
0
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ams Datasheet
[v1-04] 2015-Dec-07
AS5262 − Detailed Description
For simplification, Figure 16 describes a linear output voltage
from rail to rail (0V to VDD) over the complete rotation range.
In practice, this is not feasible due to saturation effects of the
output stage transistors. The actual curve will be rounded
towards the supply rails (as indicated Figure 16).
Multiple Slope Output
The AS5262 can be programmed to multiple slopes. Where one
programmed reference slope characteristic is copied to
multiple slopes. Two, three and four slopes are selectable by the
user OTP bits QUADEN (1:0). In addition to the steepness of the
slope the clamping levels can be programmed as well.
Duty Cycle
Figure 17:
Two Slope Mode
0
Duty Cycle
Figure 18:
Four Slope Mode
0
ams Datasheet
[v1-04] 2015-Dec-07
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AS5262 − Detailed Description
Resolution of Parameters
The programming parameters have a wide resolution of up to
14 bits.
Figure 19:
Resolution of the Programming Parameters
Symbol
Parameter
Resolution
T1
Mechanical angle start point
14 bits
T2
Mechanical angle stop point
14 bits
T1Y
Mechanical start voltage level
12 bits
T2Y
Mechanical stop voltage level
12 bits
CLL
Clamping level low
9 bits
CLH
Clamping level high
9 bits
Break point
14 bits
BP
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Note
ams Datasheet
[v1-04] 2015-Dec-07
AS5262 − Detailed Description
Figure 20:
Overview of the Angular Output Voltage
100
96
Failure Band High
Clamping Region High
Output Voltage in percent of VDD
CLH
T2Y
Application Region
T1Y
CLL
Clamping Region Low
4
0
Failure Band Low
Figure 12 gives an overview of the different ranges. The failure
bands are used to indicate a wrong operation of the AS5262.
This can be caused due to a broken supply line. By using the
specified load resistors, the output level will remain in these
bands during a fail. It is recommended to set the clamping level
CLL above the lower failure band and the clamping level CLH
below the higher failure band.
Analog Output Diagnostic Mode
Due to the low pin count in the application a wrong operation
must be indicated by the output pin OUT. This could be realized
using the failure bands. The failure band is defined with a fixed
level. The failure band low is specified from 0 to 4% of the supply
range over the total operation range. The failure band high is
defined always from 96 to 100%. Several failures can happen
during operation. The output signal remains in these bands
over the specified operating and load conditions. All different
failures can be grouped into the internal alarms (failures) and
the application related failures.
C LOAD ≤ 33nF, R PU= 4kΩ to 10kΩ
R PD = 4kΩ to 10kΩ load pull-up
ams Datasheet
[v1-04] 2015-Dec-07
Page 17
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AS5262 − Detailed Description
Figure 21:
Different Failure Cases of AS5262
Type
Internal alarms
(failures)
Application
related failures
Failure Mode
Symbol
Failure Band
Out of magnetic range
(too less or too high
magnetic input)
MAGRng
High/Low
Programmable by OTP bit
DIAG_HIGH
CORDIC overflow
COF
High/Low
Programmable by OTP bit
DIAG_HIGH
Offset compensation
finished
OCF
High/Low
Programmable by OTP bit
DIAG_HIGH
Watchdog fail
WDF
High/Low
Programmable by OTP bit
DIAG_HIGH
Oscillator fail
OF
High/Low
Programmable by OTP bit
DIAG_HIGH
Overvoltage condition
OV
High/Low
Dependant on the load
resistor
Pull up → failure band high
Pull down → failure band
low
High/Low
Switch off → short circuit
dependent
Broken VDD
BVDD
Broken VSS
BVSS
Short circuit output
SCO
Note
For efficient use of diagnostics, it is recommended to program
to clamping levels CLL and CLH.
Page 18
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ams Datasheet
[v1-04] 2015-Dec-07
AS5262 − Detailed Description
Analog Output Driver Parameters
The output stage is configured in a push-pull output. Therefore
it is possible to sink and source currents.
C LOAD ≤ 33nF, R PU= 4kΩ to 10kΩ;
R PD = 4kΩ to 10kΩ load pull-up
Figure 22:
General Parameters for the Output Driver
Symbol
Parameter
Min
Typ
Max
Unit
Note
IOUTSCL
Short circuit output current
(low side driver)
5
10
20
mA
VOUT=20V
IOUTSCH
Short circuit output current
(high side driver)
-20
-10
-5
mA
VOUT=0V
TSCDET
Short circuit detection time
20
600
μs
Output stage turned off
TSCREC
Short circuit recovery time
2
20
ms
Output stage turned on
VOUT=VDD=5V
ILEAKOUT
Output Leakage current
-20
20
μA
BGNDPU
Output voltage broken GND
with pull-up
96
100
%VDD
BGNDPD
Output voltage broken GND
with pull-down
0
4
%VDD
BVDDPU
Output voltage broken VDD
with pull-up
96
100
%VDD
BVDDPD
Output voltage broken VDD
with pull-down
0
4
%VDD
-0.5
0.5
%VDD
10(1)
LSB
Between 4% and 96% of
VDD
10(2)
LSB
Between 4% and 96% of
VDD
OUTRATIO
Output ratiometric error
OUTDNL
Output DNL
OUTINL
Output INL
-10(2)
Note(s) and/or Footnote(s):
1. This parameter will be finally defined after temperature characterisation.
2. Design target for this value is reduced.
Hysteresis Function
AS5262 device includes a hysteresis function to avoid sudden
jumps from CLH to CLL and vice versa caused by noise in the
full turn configuration.
The hysteresis amplitude can be selected via the OTP bits
HYSTSEL<1:0>.
ams Datasheet
[v1-04] 2015-Dec-07
Page 19
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AS5262 − Application Information
Application Information
Recommended Application Schematic
Figure 23 shows the recommended schematic in the
application. All components marked with (*) are optional and
can be used to further increase the EMC.
Figure 23:
AS5262 6-Wire Connection with Pull-Down / Pull-Up Resistors
Sensor PCB
Electric Control Unit
VDD1
VDD2
R1_x*
R2_x*
TP1_T
TP1_B
VDD3V3_T
C2_x
VDD3V3_B
15
14
OUT1
OUT_T
C4_x*
OUT_B
C1_x
VDD_T
VDD_B
16
13
1
12
2
11
AS5262
3
OUT2
10
4
9
5
6
7
8
S_B
S_T
TP3_B
C3_x
CL_T RLPD_T
CL_B RLPD_B
TP3_T
GND_T
GND_B
TP2_T
TP2_B
GND1
GND2
Sensor PCB
Electric Control Unit
VDD1
VDD2
R1_x*
R2_x*
TP1_T
TP1_B
VDD3V3_T
C2_x
VDD3V3_B
15
14
RLPU_B
CL_T
CL_B
13
1
12
2
11
AS5262
3
RLPU_T
OUT1
OUT_T
C4_x*
OUT_B
C1_x
VDD_T
VDD_B
16
OUT2
10
4
9
5
6
7
8
S_B
S_T
TP3_B
C3_x
TP3_T
GND_T
GND_B
TP2_T
TP2_B
GND1
GND2
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ams Datasheet
[v1-04] 2015-Dec-07
AS5262 − Application Information
Figure 24:
External Components
Symbol
Parameter
Min
Typ
Max
Unit
Note
C1
VDD buffer capacitor
0.8
1
1.2
μF
Low ESR 0.3 Ω
C2
VDD3V3 regulator capacitor
0.8
1
1.2
μF
Low ESR 0.3 Ω
C3
OUT load capacitor (sensor PCB)
4.7
nF
C4*
VDD capacitor (optional)
4.7
nF
R1*
VDD serial resistor (optional)
10
Ω
CL
OUT load capacitor (ECU)
R2*
OUT serial resistor (optional)
RLPU
OUT pull-up resistance
4
10
kΩ
RLPD
OUT pull-down resistance
4
10
kΩ
0
0
33
Do not increase due to
programming over
output.
nF
Ω
50
Programming the AS5262
The AS5262 programming is a one-time-programming (OTP)
method, based on polysilicon fuses. The advantage of this
method is that no additional programming voltage is needed.
The internal LDO provides the current for programming.
The OTP consists of 128 bits; several bits are available for user
programming. In addition factory settings are stored in the OTP
memory. Both regions are independently lockable by build in
lock bits.
A single OTP cell can be programmed only once. Per default,
the cell is “0”; a programmed cell will contain a “1”. While it is
not possible to reset a programmed bit from “1” to “0”, multiple
OTP writes are possible, as long as only unprogrammed “0”-bits
are programmed to “1”.
Independent of the OTP programming, it is possible to
overwrite the OTP register temporarily with an OTP write
command. This is possible only if the user lock bit is not
programmed.
Due to the programming over the output pin the device will
initially start in the communication mode. In this mode the
digital angle value can be read with a specific protocol format.
It is a bidirectional communication possible. Parameters can be
written into the device. A programming of the device is
triggered by a specific command. With another command
(pass2func) the device can be switched into operation mode.
ams Datasheet
[v1-04] 2015-Dec-07
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AS5262 − Application Information
In case of a programmed user lock bit the AS5262 automatically
starts up in the functional operation mode. No communication
of the specific protocol is possible after this.
A standard half duplex UART protocol is used to exchange data
with the device in the communication mode.
UART Interface for Programming
The AS5262 uses a standard UART interface with an address
byte and two data bytes. The read or write mode is selected
with bit R/Wn in the first byte. The timing (baudrate) is selected
by the AS5262 over a synchronization frame. The baud rate
register can be read and overwritten (optional). Every start bit
is used for synchronization.
A time out function detects not complete commands and resets
the AS5262 UART after the timeout period.
Frame Organization
Each frame is composed by 24 bits. The first byte of the frame
specifies the read/write operation with the register address. 16
data bits contains the communication data. There will be no
operation in case of the usage of a not specified CMD. The UART
programming interface block of the AS5262 can operate in
slave communication or master communication mode. In the
slave communication mode the AS5262 receives the data. The
programming tool is the driver of the single communication
line. In case of the master communication mode the AS5262
transmits data in the frame format. The single communication
line can be pulled down by the AS5262.
The UART frame consists of 1 start bit (low level), 8 data bit, 1
even-parity bit and 1 stop bit (high level). Data are transferred
from LSB to MSB.
Figure 25:
General UART Frame
start
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Document Feedback
D0
D1
D2
D3
D4
D5
D6
D7 par stop
ams Datasheet
[v1-04] 2015-Dec-07
AS5262 − Application Information
Figure 26:
Bit Timing
Symbol
Parameter
Min
Typ
Max
Unit
START
Start bit
1
TBIT
Dx
Data bit
1
TBIT
PAR
Parity bit
1
TBIT
STOP
Stop bit
TSW
Slave/Master Switch Time
1
Note
TBIT
7
TBIT
Each communication starts with the reception of a request from
the external controller. The request consists of two frames: one
synchronization frame and the command frame.
The synchronization frame contains the data 0x55 and allows
the UART to measure the external controller baud rate.
Figure 27:
Synchronization Frame
start
D0
D1
D2
D3
D4
D5
D6
D7
par
stop
The second frame contains the command Read/ Write (1 bit)
and the address (7 bits).
Figure 28:
Address and Command Frame
start
AD
0
AD
1
AD
2
AD
3
AD
4
AD
5
AD
R/Wn
6
par
stop
Only two commands are possible. In case of read command the
idle phase between the command and the answer is the time
TSW. In case of parity error command is not executed.
ams Datasheet
[v1-04] 2015-Dec-07
Page 23
Document Feedback
AS5262 − Application Information
Figure 29:
Possible Commands
Possible Interface
Commands
Description
WRITE
Write data to the OTP memory
or Registers
READ
Read data to the OTP memory or
Registers
AS5X63
Communication Mode
Command
CMD
SLAVE
0
SLAVE & MASTER
1
Note(s) and/or Footnote(s):
1. In case of Write command the request is followed by the frames containing the data to write.
2. In case of Read command the communication direction will change and the AS5262 will answer with the frames containing the
requested data.
WRITE (Command Description)
Figure 30:
Full Write Command
Synchronization frame
start
D0
D1
D2
D3
D4
D5
AD0
AD1
AD2
AD3
AD4
AD5
D6
D7
par
stop
par
stop
Write command frame
start
AD6
R/
Wn
Data0 frame (data to write on address AD<6:0>)
start
D00
D01
D03
D04
D05
D06
D07
par
stop
D03
D04
D05
D06
D07
par
stop
D02
Data1 frame (data to write on address AD<6:0>+1)
start
D00
D01
D02
• Writing the AS5262 KEY in the fuse register (address 0x41)
triggers the transfer of the data from the OTP RAM into
the Poly Fuse cell.
• Writing the AS5262 KEY in the Pass2Func Register (address
0x60) forces the device into normal mode.
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ams Datasheet
[v1-04] 2015-Dec-07
AS5262 − Application Information
READ (Command Description)
Figure 31:
Full Read Command
Synchronization frame:
start
D0
D1
D2
D3
D4
D5
D6
D7
par
stop
AD0
AD1
AD2
AD3
AD4
AD5
AD6
R/Wn
par
stop
Read command frame:
start
Data0 frame (data read from address AD<6:0>) (MASTER):
start
D00
D01
D02
D03
D04
D05
D06
D07
par
stop
D04
D05
D06
D07
par
stop
Data1 frame (data read from address AD<6:0>+1) (MASTER):
start
D00
D01
D02
D03
Baud-Rate Automatic Detection
The UART includes a built-in baud-rate monitor that uses the
synchronization frame to detect the external controller
baud-rate. This baud-rate is used after the synchronization byte
to decode the following frame and to transmit the answer and
it is stored in the BAUDREG register.
Baud-Rate Manual Setting (Optional)
The BAUDREG register can be read and over-written for a
possible manual setting of the baud-rate: in case the register is
overwritten with a value different from 0, this value will be used
for the following UART communications and the
synchronization frame must be removed from the request.
ams Datasheet
[v1-04] 2015-Dec-07
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Document Feedback
AS5262 − Application Information
S 0 0 0 0 0 0 0 0 0 P IDLE
Even Parity
Stop
Start
High Byte
MSB
LSB
Low Byte
S 0 1 0 1 1 1 0 0 0 P IDLE
Start
P IDLE
Even Parity
Stop
0
R/n
Even Parity
Stop
S
MSB
LSB
MSB
LSB
WR BAUDREG
Address
Start
R/n
Even Parity
Stop
S 1 0 1 0 1 0 1 0 0 P IDLE
Start
IDLE
synch frame
MSB
LSB
Figure 32:
Manual Baud-Rate Setting
AS5262 in Receiving Mode (Write Access)
AS5262 in Receiving
Mode
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Document Feedback
MSB
High Byte
Even Parity
IDLE
Stop
P
Start
S
High Byte
S
P
IDLE
Stop
IDLE
Even Parity
P
MSB
LSB
Low Byte
Start
S
Even Parity
Stop
LSB
IDLE
Start
P
Stop
1
IDLE
AS5262 in Receiving Mode (Write Access)
MSB
Reg. Address
R/Wn
Even Parity
LSB
Start
S
LSB
P
Even Parity
Stop
S
AS5262 in Receiving
Mode
IDLE
Low Byte
MSB
LSB
IDLE
MSB
R/n
Even Parity
P
Start
0
Stop
Reg. Address
S
Start
IDLE
MSB
LSB
Figure 33:
Simple Read and Write
AS5262 in transmitting mode (Read Access)
ams Datasheet
[v1-04] 2015-Dec-07
AS5262 − Application Information
OTP Programming Data
Figure 34:
OTP Memory Map
Data Byte
Bit
Number
Symbol
Default
0
0
1
0
2
0
3
0
4
0
5
0
6
0
7
0
Description
DATA15 (0x0F)
1
Factory
Settings
0
ams (reserved)
0
2
0
3
0
4
0
5
0
6
0
7
0
0
0
1
0
Factory Settings
0
DATA14 (0x0E)
CUSTID<0>
0
3
CUSTID<1>
0
4
CUSTID<2>
0
5
CUSTID<3>
0
6
CUSTID<4>
0
7
CUSTID<5>
0
0
CUSTID<6>
0
DATA13 (0x0D)
DATA12 (0x0C)
ams Datasheet
[v1-04] 2015-Dec-07
Customer Identifier
Customer Settings
2
Page 27
Document Feedback
AS5262 − Application Information
Bit
Number
Symbol
Default
DATA11 (0x0B)
7
CLH<0>
0
0
CLH<1>
0
1
CLH<2>
0
2
CLH<3>
0
3
CLH<4>
0
4
CLH<5>
0
5
CLH<6>
0
6
CLH<7>
0
7
CLH<8>
0
DATA10 (0x0A)
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Document Feedback
Description
Clamping Level High
Customer Settings
Data Byte
ams Datasheet
[v1-04] 2015-Dec-07
AS5262 − Application Information
Data Byte
Bit
Number
Symbol
Default
0
CLL<0>
0
1
CLL<1>
0
2
CLL<2>
0
3
CLL<3>
0
4
CLL<4>
0
5
CLL<5>
0
6
CLL<6>
0
7
CLL<7>
0
0
CLL<8>
0
1
OFFSET<0>
0
2
OFFSET<1>
0
3
OFFSET<2>
0
4
OFFSET<3>
0
5
OFFSET<4>
0
6
OFFSET<5>
0
7
OFFSET<6>
0
0
OFFSET<7>
0
1
OFFSET<8>
0
2
OFFSET<9>
0
3
OFFSET<10>
0
4
OFFSET<11>
0
5
OFFSET<12>
0
6
OFFSET<13>
0
7
OFFSET<14>
0
Description
DATA9 (0x09)
Clamping Level Low
Customer Settings
DATA8 (0x08)
Offset
DATA7 (0x07)
ams Datasheet
[v1-04] 2015-Dec-07
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AS5262 − Application Information
Data Byte
Bit
Number
Symbol
Default
0
OFFSET<15>
0
1
OFFSET<16>
0
2
OFFSET<17>
0
3
OFFSET<18>
0
4
OFFSET<19>
0
5
GAIN<0>
0
6
GAIN<1>
0
7
GAIN<2>
0
0
GAIN<3>
0
1
GAIN<4>
0
2
GAIN<5>
0
3
GAIN<6>
0
4
GAIN<7>
0
5
GAIN<8>
0
6
GAIN<9>
0
7
GAIN<10>
0
0
GAIN<11>
0
1
GAIN<12>
0
2
GAIN<13>
0
3
GAIN<14>
0
4
GAIN<15>
0
5
GAIN<16>
0
6
BP<0>
0
7
BP<1>
0
Description
Offset
DATA6 (0x06)
Scale Factor
Customer Settings
DATA5 (0x05)
DATA4 (0x04)
Break Point
Page 30
Document Feedback
ams Datasheet
[v1-04] 2015-Dec-07
AS5262 − Application Information
Data Byte
Bit
Number
Symbol
Default
0
BP<2>
0
1
BP<3>
0
2
BP<4>
0
3
BP<5>
0
4
BP<6>
0
5
BP<7>
0
6
BP<8>
0
7
BP<9>
0
0
BP<10>
0
1
BP<11>
0
2
BP<12>
0
3
BP<13>
0
Description
DATA3 (0x003)
Break Point
ANGLERNG
0
5
DIAG_HIGH
0
Failure Band Selection
0=Failure Band Low
1=Failure Band High
6
QUADEN<0>
0
7
QUADEN<1>
0
DATA2 (0x02)
ams Datasheet
[v1-04] 2015-Dec-07
Customer Settings
4
Sector selection
0=Angular Sector≥22.5
degrees;
1=Angular Sector<22.5
degrees
DATA2 (0x02)
Quadrant Mode Enable
00=1quadrant;
01=2quadrants;
10=3 quadrants;
11=4 quadrants
Page 31
Document Feedback
AS5262 − Application Information
Data Byte
Bit
Number
Symbol
Default
AIRGAPSEL
0
1
HYSTSEL<0>
0
2
HYSTSEL<1>
0
3
Not used
0
4
Not used
0
5
Not used
0
6
Not used
0
7
Not used
0
0
RED_ADD<0>
0
1
RED_ADD<1>
0
2
RED_ADD<2>
0
3
RED_ADD<3>
0
4
RED_BIT<0>
0
5
RED_BIT<1>
0
6
RED_BIT<2>
0
Redundancy Bit
Identify the position of the
bit to be changed in the byte
at the address
RED_ADD<3:0>
7
CUST_LOCK
0
Lock bit for Customer Area
Hysteresis selection
00=no hysteresis;
01: 56LSB;
10=91LSB;
11=137LSB
Customer Settings
Page 32
Document Feedback
Magnetic input range
extension
0:extended range;
1=normal range
0
DATA1 (0x01)
DATA0 (0x00)
Description
Redundancy Address
Identify the address of the
byte containing the bit to be
changed
ams Datasheet
[v1-04] 2015-Dec-07
AS5262 − Application Information
READ / WRITE Register Map
Figure 35:
Read/Write Registers
Data Byte
Bit
Number
Symbol
Default
0
BAUDREG<0>
0
1
BAUDREG<1>
0
2
BAUDREG<2>
0
3
BAUDREG<3>
0
4
BAUDREG<4>
0
5
BAUDREG<5>
0
6
BAUDREG<6>
0
7
BAUDREG<7>
0
0
BAUDREG<8>
0
1
Not used
0
2
Not used
0
3
Not used
0
4
Not used
0
5
Not used
0
6
Not used
0
7
Not used
0
0
DAC12IN<8>
0
1
DAC12IN<9>
0
2
DAC12IN<10>
0
3
DAC12IN<11>
0
4
DAC12INSEL
0
DAC12 buffer selection
5
R1K10K<0>
0
6
R1K10K<1>
0
Selection of the reference
resistance used for OTP
download
7
DSPRN
0
Description
DATA0 (0x20)
A read command returns all
data bits at 0
Read/Write Area
DATA1 (0x21)
UART Baud Rate Register
DAC12 buffer value
DATA2 (0x22)
ams Datasheet
[v1-04] 2015-Dec-07
Resetn of the Digital Signal
Processing circuit
Page 33
Document Feedback
AS5262 − Application Information
Data Byte
Symbol
Default
0
DAC12IN<0>
0
1
DAC12IN<1>
0
2
DAC12IN<2>
0
3
DAC12IN<3>
0
4
DAC12IN<4>
0
5
DAC12IN<5>
0
6
DAC12IN<6>
0
7
DAC12IN<7>
0
DATA3 (0x23)
Description
Read/Write Area
Bit
Number
DAC12 buffer value
READ Only Register Map
Figure 36:
Read Only Registers
Data Byte
Page 34
Document Feedback
Symbol
Default
0
Not used
0
A read command returns 0
1
OFFSETFINISHED
0
Offset compensation
finished
2
AGCFINISHED
0
AGC loop compensation
finished
3
CORDICOVF
0
Overflow of the CORDIC
4
AGCALARML
0
AGC loop saturation because
of B field too strong
5
AGCALARMH
0
AGC loop saturation because
of B field too weak
Description
6
OTP_RES
0
0=1K resistance selected for
OTP download;
1=10K resistance selected
for OTP download
7
PARITY_ERR
0
UART parity error flag
Read Area
DATA0 (0x28)
Bit
Number
ams Datasheet
[v1-04] 2015-Dec-07
AS5262 − Application Information
Data Byte
Bit
Number
Symbol
Default
0
CORDICOUT<0>
0
1
CORDICOUT<1>
0
2
CORDICOUT<2>
0
3
CORDICOUT<3>
0
4
CORDICOUT<4>
0
5
CORDICOUT<5>
0
6
CORDICOUT<6>
0
7
CORDICOUT<7>
0
0
CORDICOUT<8>
0
1
CORDICOUT<9>
0
2
CORDICOUT<10>
0
3
CORDICOUT<11>
0
4
CORDICOUT<12>
0
5
CORDICOUT<13>
0
6
Not used
0
7
Not used
0
0
DSPOUT<0>
0
1
DSPOUT<1>
0
2
DSPOUT<2>
0
3
DSPOUT<3>
0
4
DSPOUT<4>
0
5
DSPOUT<5>
0
6
DSPOUT<6>
0
7
DSPOUT<7>
0
Description
DATA1 (0x29)
CORDIC Output
Read Area
DATA2 (0x2A)
DATA3 (0x2B)
ams Datasheet
[v1-04] 2015-Dec-07
A read command returns all
data bits at 0
DSP Output
Page 35
Document Feedback
AS5262 − Application Information
Data Byte
Bit
Number
Symbol
Default
0
DSPOUT<8>
0
1
DSPOUT<9>
0
2
DSPOUT<10>
0
3
DSPOUT<11>
0
4
Not used
0
5
Not used
0
6
Not used
0
7
Not used
0
0
AGCVALUE<0>
0
1
AGCVALUE<1>
0
2
AGCVALUE<2>
0
3
AGCVALUE<3>
0
4
AGCVALUE<4>
0
5
AGCVALUE<5>
0
6
AGCVALUE<6>
0
7
AGCVALUE<7>
0
0
MAG<0>
0
1
MAG<1>
0
2
MAG<2>
0
3
MAG<3>
0
4
MAG<4>
0
5
MAG<5>
0
6
MAG<6>
0
7
MAG<7>
0
Description
DSP Output
DATA4 (0x2C)
AGC Value
DATA6 (0x2E)
Page 36
Document Feedback
Read Area
DATA5 (0x2D)
A read command returns all
data bits at 0
Magnitude of magnetic field
ams Datasheet
[v1-04] 2015-Dec-07
AS5262 − Application Information
Data Byte
Symbol
Default
0
Not used
0
1
Not used
0
2
Not used
0
3
Not used
0
4
Not used
0
5
Not used
0
6
Not used
0
7
Not used
0
DATA7 (0x2F)
Description
A read command returns all
data bits at 0
Read Area
Bit
Number
Special Registers
Figure 37:
Special Registers
Data Byte
Bit
Number
Symbol
Default
0
AS5262KEY<0>
0
1
AS5262KEY<1>
0
2
AS5262KEY<2>
0
3
AS5262KEY<3>
0
4
AS5262KEY<4>
0
5
AS5262KEY<5>
0
6
AS5262KEY<6>
0
7
AS5262KEY<7>
0
0
AS5262KEY<8>
0
1
AS5262KEY<9>
0
2
AS5262KEY<10>
0
3
AS5262KEY<11>
0
4
AS5262KEY<12>
0
5
AS5262KEY<13>
0
6
AS5262KEY<14>
0
7
AS5262KEY<15>
0
Description
DATA0 (0x41)
Fuse Register
AS5262 KEY<15:0>=0101
0001 0110 0010
A write command with data
different from AS5262 KEY is
not executed
A read command returns all
data bits at 0
DATA1 (0x42)
ams Datasheet
[v1-04] 2015-Dec-07
Page 37
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AS5262 − Application Information
Data Byte
Bit
Number
Symbol
Default
0
AS5262KEY<0>
0
1
AS5262KEY<1>
0
2
AS5262KEY<2>
0
3
AS5262KEY<3>
0
4
AS5262KEY<4>
0
5
AS5262KEY<5>
0
6
AS5262KEY<6>
0
7
AS5262KEY<7>
0
0
AS5262KEY<8>
0
1
AS5262KEY<9>
0
2
AS5262KEY<10>
0
3
AS5262KEY<11>
0
4
AS5262KEY<12>
0
5
AS5262KEY<13>
0
6
AS5262KEY<14>
0
7
AS5262KEY<15>
0
Description
DATA0 (0x60)
Pass2Func Register
AS5262 KEY<15:0>=0101
0001 0110 0010
A write command with data
different from AS5262 KEY is
not executed
A read command returns all
data bits at 0
DATA1 (0x61)
Page 38
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ams Datasheet
[v1-04] 2015-Dec-07
AS5262 − Application Information
Programming Procedure
• Pull-Up on out pin
• VDD=5V
• Wait 10ms (after the startup time device enters
communication mode)
• Write command: Trimming bits are written in the OTP RAM
• Read command: All the trimming bits are read back to
check the correctness of the writing procedure.
• Write AS5262KEY in the Fuse register: The OTP RAM
content is permanently transferred into the Poly Fuse
cells.
• Wait 10 ms (fuse time)
• Write command, R1K_10K<1:0>=(11)b: Poly Fuse cells are
downloaded into the RAM memory using a 10K resistance
as reference.
• Wait 5 ms (download time)
• Read R1K_10K register, the expected value is 00b
• Write command, R1K_10K<1:0>=(11)b
• Read R1K_10K register, the expected value is (11)b. NB:
Step11 and Step12 have to be consecutive.
• Read command: all the fused bits downloaded with 10K
resistance are read back.
• Write command, R1K_10K=<1:0>=(10)b: Poly Fuse cells
are downloaded into the RAM memory using a 1K
resistance as reference.
• Wait 5 ms (download time)
• Read R1K_10K register, the expected value is (00)b
• Write command register, R1K_10K<1:0>=(10)b
• Read R1K_10K register, the expected value is (10)b NB:
Step18 and Step19 have to be consecutive.
• Read command: All the fused bits downloaded with 1K
resistance are read back.
• Check that read commands at Steps 5, 13 and 19 are
matching
• Write AS5262KEY in the Pass2Func register: Device enters
normal mode.
ams Datasheet
[v1-04] 2015-Dec-07
Page 39
Document Feedback
AS5262 − Application Information
Mechanical Data
The internal Hall elements are placed in the center of the
package on a circle with a radius of 1.25mm.
Figure 38:
Hall Element Position
Note(s) and/or Footnote(s):
1. All dimensions in mm.
2. Die thickness 0.150mm nom.
3. Adhesive thickness 0.011mm nom.
4. Spacer thickness 0.178mm typ.
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ams Datasheet
[v1-04] 2015-Dec-07
AS5262 − Package Drawings & Markings
Package Drawings & Markings
The device is available in a MLF-16 package.
Figure 39:
Package Drawings and Dimensions
Symbol Min
A
A1
A2
A3
L
L1
L2
Q
b
b1
D
E
e
D1
E1
D2
E2
aaa
bbb
ccc
ddd
eee
fff
N
RoHS
Green
0.80
0
0.50
0.05
0.05
0º
0.35
0.20
4.10
4.10
-
Nom
Max
0.90
0.02
0.65
0.20 REF
0.60
0.15
0.10
0.40
0.25
6.00 BSC
6.00 BSC
1.00 BSC
5.75 BSC
5.75 BSC
4.20
4.20
0.15
0.10
0.10
0.05
0.08
0.10
16
1.00
0.05
1.00
0.70
0.25
0.15
14º
0.45
0.30
4.30
4.30
-
Note(s) and/or Footnote(s):
1. Dimensions and tolerancing confirm to ASME Y14.5M-1994.
2. All dimensions are in miilimeters. Angles are in degrees.
3. Bilaretal coplanarity zone applies to the exposed pad as well as the terminal.
4. Radius on the terminal is optional.
5. N is the total number of terminals.
Figure 40:
Package Marking: YYWWMZZ@
YY
WW
M
ZZ
@
Year
Week
Assembly plant identifier
Assembly traceability code
Sublot identifier
ams Datasheet
[v1-04] 2015-Dec-07
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AS5262 − Ordering & Contact Information
Ordering & Contact Information
The devices are available as the standard products shown in
Figure 41.
Figure 41:
Ordering Information
Ordering Code
Description
Package
Delivery Form
AS5262-HMFP
12-bit programmable
redundant angle position
sensor with analog outputs
MLF-16
6x6
Tape & Reel
AS5262-HMFM
Delivery Quantity
4000 pcs/reel
500 pcs/reel
Buy our products or get free samples online at:
www.ams.com/ICdirect
Technical Support is available at:
www.ams.com/Technical-Support
Provide feedback about this document at:
www.ams.com/Document-Feedback
For further information and requests, e-mail us at:
[email protected]
For sales offices, distributors and representatives, please visit:
www.ams.com/contact
Headquarters
ams AG
Tobelbaderstrasse 30
8141 Unterpremstaetten
Austria, Europe
Tel: +43 (0) 3136 500 0
Website: www.ams.com
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AS5262 − RoHS Compliant & ams Green Statement
RoHS Compliant & ams Green
Statement
RoHS: The term RoHS compliant means that ams AG products
fully comply with current RoHS directives. Our semiconductor
products do not contain any chemicals for all 6 substance
categories, including the requirement that lead not exceed
0.1% by weight in homogeneous materials. Where designed to
be soldered at high temperatures, RoHS compliant products are
suitable for use in specified lead-free processes.
ams Green (RoHS compliant and no Sb/Br): ams Green
defines that in addition to RoHS compliance, our products are
free of Bromine (Br) and Antimony (Sb) based flame retardants
(Br or Sb do not exceed 0.1% by weight in homogeneous
material).
Important Information: The information provided in this
statement represents ams AG knowledge and belief as of the
date that it is provided. ams AG bases its knowledge and belief
on information provided by third parties, and makes no
representation or warranty as to the accuracy of such
information. Efforts are underway to better integrate
information from third parties. ams AG has taken and continues
to take reasonable steps to provide representative and accurate
information but may not have conducted destructive testing or
chemical analysis on incoming materials and chemicals. ams AG
and ams AG suppliers consider certain information to be
proprietary, and thus CAS numbers and other limited
information may not be available for release.
ams Datasheet
[v1-04] 2015-Dec-07
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AS5262 − Copyrights & Disclaimer
Copyrights & Disclaimer
Copyright ams AG, Tobelbader Strasse 30, 8141
Unterpremstaetten, Austria-Europe. Trademarks Registered. All
rights reserved. The material herein may not be reproduced,
adapted, merged, translated, stored, or used without the prior
written consent of the copyright owner.
Devices sold by ams AG are covered by the warranty and patent
indemnification provisions appearing in its General Terms of
Trade. ams AG makes no warranty, express, statutory, implied,
or by description regarding the information set forth herein.
ams AG reserves the right to change specifications and prices
at any time and without notice. Therefore, prior to designing
this product into a system, it is necessary to check with ams AG
for current information. This product is intended for use in
commercial applications. Applications requiring extended
temperature range, unusual environmental requirements, or
high reliability applications, such as military, medical
life-support or life-sustaining equipment are specifically not
recommended without additional processing by ams AG for
each application. This product is provided by ams AG “AS IS”
and any express or implied warranties, including, but not
limited to the implied warranties of merchantability and fitness
for a particular purpose are disclaimed.
ams AG shall not be liable to recipient or any third party for any
damages, including but not limited to personal injury, property
damage, loss of profits, loss of use, interruption of business or
indirect, special, incidental or consequential damages, of any
kind, in connection with or arising out of the furnishing,
performance or use of the technical data herein. No obligation
or liability to recipient or any third party shall arise or flow out
of ams AG rendering of technical or other services.
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ams Datasheet
[v1-04] 2015-Dec-07
AS5262 − Document Status
Document Status
Document Status
Product Preview
Preliminary Datasheet
Datasheet
Datasheet (discontinued)
ams Datasheet
[v1-04] 2015-Dec-07
Product Status
Definition
Pre-Development
Information in this datasheet is based on product ideas in
the planning phase of development. All specifications are
design goals without any warranty and are subject to
change without notice
Pre-Production
Information in this datasheet is based on products in the
design, validation or qualification phase of development.
The performance and parameters shown in this document
are preliminary without any warranty and are subject to
change without notice
Production
Information in this datasheet is based on products in
ramp-up to full production or full production which
conform to specifications in accordance with the terms of
ams AG standard warranty as given in the General Terms of
Trade
Discontinued
Information in this datasheet is based on products which
conform to specifications in accordance with the terms of
ams AG standard warranty as given in the General Terms of
Trade, but these products have been superseded and
should not be used for new designs
Page 45
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AS5262 − Revision Information
Revision Information
Changes from 1.1 (2012-Oct-31) to current revision 1-04 (2015-Dec-07)
Page
1.1 (2012-Oct-31) to 1-02 (2015-Aug-07)
Content was updated to the latest ams design
Noise Suppressor section was removed
Updated Key Benefits & Features
2
Updated Figure 35
27
Added Mechanical Data section
40
Updated Package Drawings & Markings section
41
Updated Figure 43
42
1-02 (2015-Aug-07) to 1-03 (2015-Dec-03)
Updated Detailed Description
10
Updated Figure 13
12
Updated Figure 19
16
Updated Figure 38
40
1-03 (2015-Dec-03) to 1-04 (2015-Dec-07)
Updated Figure 2
2
Updated Figure 34 [DATA11 (0x0B), DATA12 (0x0C)]
27
Updated Mechanical Data section
40
Note(s) and/or Footnote(s):
1. Page and figure numbers for the previous version may differ from page and figure numbers in the current revision.
2. Correction of typographical errors is not explicitly mentioned.
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ams Datasheet
[v1-04] 2015-Dec-07
AS5262 − Content Guide
Content Guide
ams Datasheet
[v1-04] 2015-Dec-07
1
2
2
3
General Description
Key Benefits & Features
Applications
Block Diagram
4
4
Pin Assignment
Pin Description
6
Absolute Maximum Ratings
7
7
7
8
9
9
Electrical Characteristics
Operating Conditions
Magnetic Input Specification
Electrical System Specifications
Timing Characteristics
Power Management - Supply Monitor
10
11
11
11
12
13
14
14
15
16
17
19
19
Detailed Description
Operation
VDD Voltage Monitor
Analog Output
Programming Parameters
Application Specific Angular Range Programming
Application Specific Programming of the Break Point
Full Scale Mode
Multiple Slope Output
Resolution of Parameters
Analog Output Diagnostic Mode
Analog Output Driver Parameters
Hysteresis Function
20
20
21
22
22
24
25
25
25
27
33
34
37
39
40
Application Information
Recommended Application Schematic
Programming the AS5262
UART Interface for Programming
Frame Organization
WRITE (Command Description)
READ (Command Description)
Baud-rate Automatic Detection
Baud-rate Manual Setting (Optional)
OTP Programming Data
READ / WRITE Register Map
READ Only Register Map
Special Registers
Programming Procedure
Mechanical Data
41
42
43
44
45
46
Package Drawings & Markings
Ordering & Contact Information
RoHS Compliant & ams Green Statement
Copyrights & Disclaimer
Document Status
Revision Information
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