AMSCO AS5040_1

AS5040
Data Sheet
10Bit 360° Programmable Magnetic Rotary Encoder
1 General Description
2 Key Features
The AS5040 is a contactless magnetic rotary encoder
for accurate angular measurement over a full turn of
360°. It is a system-on-chip, combining integrated Hall
elements, analog front end and digital signal processing
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 0.35° = 1024 positions per revolution. This
digital data is available as a serial bit stream and as a
PWM signal.
Furthermore, a user-programmable incremental output
is available, making the chip suitable for replacement of
various optical encoders.
An internal voltage regulator allows the AS5040 to
operate at either 3.3 V or 5 V supplies.
ƒ
Contactless high resolution rotational position
encoding over a full turn of 360 degrees
ƒ
Two digital 10bit absolute outputs:
- Serial interface and
- Pulse width modulated (PWM) output
ƒ
Three incremental output modes:
- Quadrature A/B and Index output signal
- Step / Direction and Index output signal
- 3-phase commutation for brushless DC
motors
- 10, 9, 8 or 7 bit user programmable
resolution
ƒ
User programmable zero / index position
ƒ
Failure detection mode for magnet placement
monitoring and loss of power supply
ƒ
Rotational speeds up to 30,000 rpm
ƒ
Push button functionality detects movement
of magnet in Z-axis
ƒ
Serial read-out of multiple interconnected
AS5040 devices using Daisy Chain mode
ƒ
Wide temperature range: - 40°C to + 125°C
ƒ
Fully automotive qualified to AEC-Q100,
grade 1
ƒ
Small Pb-free package: SSOP 16 (5.3mm x
6.2mm)
Figure 1: Typical Arrangement of AS5040 and Magnet
3 Applications
Benefits
ƒ
Industrial applications:
- Contactless rotary position sensing
- Robotics
- Brushless DC motor commutation
- Power tools
ƒ
Automotive applications:
- Steering wheel position sensing
- Gas pedal position sensing
- Transmission gearbox encoder
- Headlight position control
- Power seat position indicator
ƒ
Complete system-on-chip
ƒ
Flexible system solution provides absolute,
PWM and incremental outputs simultaneously
ƒ
Ideal for applications in harsh environments
due to contactless position sensing
ƒ
Office equipment: printers, scanners, copiers
Tolerant to magnet misalignment and airgap
variations
ƒ
ƒ
Replacement of optical encoders
ƒ
Front panel rotary switches
ƒ
No temperature compensation necessary
ƒ
Replacement of potentiometers
ƒ
No calibration required
www.austriamicrosystems.com
Revision 2.10
1 - 33
AS5040
Data Sheet
4 Pin Configuration
Figure 2: Pin Configuration SSOP16
1
16
VDD5V
MagDECn
2
15
VDD3V3
A_LSB_U
3
14
NC
B_Dir_V
4
13
NC
NC
5
12
PWM_LSB
Index_W
6
11
CSn
VSS
7
10
CLK
Prog
8
9
DO
AS5040
MagINCn
Pin Description
Table 2 shows the description of each pin of the standard SSOP16 package (Shrink Small Outline Package, 16 leads,
body size: 5.3mm x 6.2mmm; see Figure 2).
Pins 7, 15 and 16 are supply pins, pins 5, 13 and 14 are for internal use and must not be connected.
Pins 1 and 2 are the magnetic field change indicators, MagINCn and MagDECn (magnetic field strength increase or
decrease through variation of the distance between the magnet and the device). These outputs can be used to detect
the valid magnetic field range. Furthermore those indicators can also be used for contact-less push-button
functionality.
Pins 3, 4 and 6 are the incremental pulse output pins. The functionality of these pins can be configured through
programming the one-time programmable (OTP) register.
Table 1: Pin Assignment for the Different Incremental Output Modes
Output Mode
Pin 3
Pin 4
Pin 6
Pin 12
A
B
Index
PWM
2.x:step/direction
LSB
Direction
Index
PWM
3.x: commutation
U
V
W
LSB
1.x: quadrature
Mode 1.x: Quadrature A/B Output
Represents the default quadrature A/B signal mode.
Mode 2.x: Step / Direction Output
Configures pin 3 to deliver up to 512 pulses (up to 1024 state changes) per revolution. It is equivalent to the LSB
(least significant bit) of the absolute position value. Pin 4 provides the information of the rotational direction.
Both modes (mode 1.x and mode 2.x) provide an index signal (1 pulse/revolution) with an adjustable width of one LSB
or three LSB’s.
www.austriamicrosystems.com
Revision 2.10
2 - 33
AS5040
Data Sheet
Table 2 Pin Description SSOP16
Pin
Symbol
Type
MagINCn
DO_OD
Magnet Field Magnitude INCrease; active low, indicates a distance
reduction between the magnet and the device surface.
MagDECn
DO_OD
Magnet Field Magnitude DECrease; active low, indicates a distance
increase between the device and the magnet.
A_LSB_U
DO
Mode1.x: Quadrature A channel
Mode2.x: Least Significant Bit
Mode3.x: U signal (phase1)
B_Dir_V
DO
Mode1.x: Quadrature B channel quarter period shift to channel A.
Mode2.x: Direction of Rotation
Mode3.x: V signal (phase2)
NC
-
Index_W
DO
VSS
S
Prog
DI_PD
OTP Programming Input and Data Input for Daisy Chain mode. Internal
pull-down resistor (~74kΩ).
May be connected to VSS if programming is not used
9
DO
DO_T
Data Output of Synchronous Serial Interface
10
CLK
DI, ST
Clock Input of Synchronous Serial Interface; Schmitt-Trigger input
CSn
DI_PU, ST
12
PWM_LSB
DO
13
NC
-
Must be left unconnected
14
NC
-
Must be left unconnected
15
VDD3V3
S
3V-Regulator Output (see Figure 19)
16
VDD5V
S
1
2
3
4
5
6
7
8
11
DO_OD
DO
DI_PD
DI_PU
digital
digital
digital
digital
output open drain
output
input pull-down
input pull-up
Description
Must be left unconnected
Mode1.x and Mode2.x : Index signal indicates the absolute zero position
Mode3.x: W signal (phase3)
Negative Supply Voltage (GND)
Chip Select, active low; Schmitt-Trigger input, internal pull-up resistor
(~50kΩ) connect to VSS in incremental mode (see 0)
Pulse Width Modulation of approx. 1kHz; LSB in Mode3.x
Positive Supply Voltage 5 V
S
DI
DO_T
ST
supply pin
digital input
digital output /tri-state
Schmitt-Trigger input
Mode 3.x: Brushless DC Motor Commutation Mode
In addition to the absolute encoder output over the SSI interface, this mode provides commutation signals for
brushless DC motors with either one pole pair or two pole pair rotors. The commutation signals are usually provided
by 3 discrete Hall switches, which are no longer required, as the AS5040 can fulfill two tasks in parallel: absolute
encoder + BLDC motor commutation.
In this mode, pin 12 provides the LSB output instead of the PWM (Pulse-Width-Modulation) signal.
Pin 8 (Prog) is also used to program the different incremental interface modes, the incremental resolution and the
zero position into the OTP (see page 18).
This pin is also used as digital input to shift serial data through the device in Daisy Chain configuration,
(see page 11).
Pin 11 Chip Select (CSn; active low) selects a device within a network of AS5040 encoders and initiates serial data
transfer. A logic high at CSn puts the data output pin (DO) to tri-state and terminates serial data transfer. This pin is
also used for alignment mode (page 21) and programming mode (page 16).
www.austriamicrosystems.com
Revision 2.10
3 - 33
AS5040
Data Sheet
Pin 12 allows a single wire output of the 10-bit absolute position value. The value is encoded into a pulse width
modulated signal with 1µs pulse width per step (1µs to 1024µs over a full turn). By using an external low pass filter,
the digital PWM signal is converted into an analog voltage, allowing a direct replacement of potentiometers.
5 Electrical Characteristics
Absolute Maximum Ratings (non operating)
Stresses beyond those listed under “Absolute Maximum Ratings“ may cause permanent damage to the device. These are stress
ratings only. Functional operation of the device at these or any other conditions beyond those indicated under “Operating
Conditions” is not implied. Exposure to absolute maximum rating conditions for extended periods may affect device reliability.
Parameter
Symbol
Min
Max
Unit
DC supply voltage at pin VDD5V
VDD5V
-0.3
7
V
DC supply voltage at pin VDD3V3
VDD3V3
-0.3
5
V
-0.3
VDD5V +0.3
-0.3
7.5
-100
100
mA
Norm: JEDEC 78
±2
kV
Norm: MIL 883 E method 3015
125
°C
Min – 67°F ; Max +257°F
260
°C
t=20 to 40s, Norm: IPC/JEDEC JStd-020C
Input pin voltage
Vin
Input current (latchup immunity)
Iscr
Electrostatic discharge
ESD
Storage temperature
Tstrg
Body temperature (Lead-free
package)
TBody
Humidity non-condensing
-55
V
Note
Pins MagIncn, MagDecn, CLK, CSn,
Pin Prog
Lead finish 100% Sn “matte tin”
H
5
85
%
Operating Conditions
Parameter
Symbol
Min
Typ Max Unit
Ambient temperature
Tamb
-40
125
°C
Supply current
Isupp
16
21
mA
External supply voltage at pin VDD5V
Internal regulator output voltage at pin
VDD3V3
External supply voltage at pin VDD5V,
VDD3V3
VDD5V
4.5
5.0
5.5
V
VDD3V3
3.0
3.3
3.6
V
VDD5V
3.0
3.3
3.6
V
VDD3V3
3.0
3.3
3.6
V
Note
-40°F…+257°F
5V operation
3.3V operation (pins VDD5V and
VDD3V3 connected)
DC Characteristics for Digital Inputs and Outputs
CMOS Schmitt-Trigger Inputs: CLK, CSn (CSn = internal Pull-up)
(operating conditions: Tamb = -40 to +125°C, VDD5V = 3.0-3.6V (3V operation) VDD5V = 4.5-5.5V (5V operation)
unless otherwise noted)
Parameter
Symbol
Min
High level input voltage
VIH
0.7 * VDD5V
Low level input voltage
VIL
Schmitt Trigger hysteresis
Input leakage current
Pull-up low level input current
www.austriamicrosystems.com
Max
Unit
0.3 * VDD5V
V
V
Note
Normal operation
VIon- VIoff
1
ILEAK
-1
1
µA
CLK only
IiL
-30
-100
µA
CSn only, VDD5V: 5.0V
Revision 2.10
V
4 - 33
AS5040
Data Sheet
CMOS / Program Input: Prog
(operating conditions: Tamb = -40 to +125°C, VDD5V = 3.0-3.6V (3V operation) VDD5V = 4.5-5.5V (5V operation)
unless otherwise noted)
Parameter
Symbol
Min
Max
Unit
High level input voltage
VIH
0.7 * VDD5V
5
V
High level input voltage
VPROG
Low level input voltage
VIL
0.3 * VDD5V
V
Pull-down high level input current
IiL
100
µA
See “programming conditions”
V
Note
During programming
VDD5V: 5.5V
CMOS Output Open Drain: MagINCn, MagDECn
(operating conditions: Tamb = -40 to +125°C, VDD5V = 3.0-3.6V (3V operation) VDD5V = 4.5-5.5V (5V operation)
unless otherwise noted)
Parameter
Symbol
Max
Unit
VOL
VSS+0.4
V
Output current
IO
4
2
mA
Open drain leakage current
IOZ
1
µA
Low level output voltage
Min
Note
VDD5V: 4.5V
VDD5V: 3V
CMOS Output: A, B, Index, PWM
(operating conditions: Tamb = -40 to +125°C, VDD5V = 3.0-3.6V (3V operation) VDD5V = 4.5-5.5V (5V operation)
unless otherwise noted)
Parameter
Symbol
Min
High level output voltage
VOH
VDD5V-0.5
Low level output voltage
VOL
VSS+0.4
V
IO
4
2
mA
Output current
Max
Unit
Note
V
VDD5V: 4.5V
VDD5V: 3V
Tristate CMOS Output: DO
(operating conditions: Tamb = -40 to +125°C, VDD5V = 3.0-3.6V (3V operation) VDD5V = 4.5-5.5V (5V operation)
unless otherwise noted)
Parameter
Symbol
Min
Max
High level output voltage
VOH
VDD5V –0.5
Low level output voltage
Unit
Note
V
VOL
VSS+0.4
V
Output current
IO
4
2
mA
Tri-state leakage current
IOZ
1
µA
VDD5V: 4.5V
VDD5V: 3V
Magnetic Input Specification
(operating conditions: Tamb = -40 to +125°C, VDD5V = 3.0-3.6V (3V operation) VDD5V = 4.5-5.5V (5V operation) unless otherwise
noted)
Two-pole cylindrical diametrically magnetised source:
Parameter
Symbol
Min
Typ
Diameter
dmag
4
6
Thickness
tmag
2.5
Magnetic input field
amplitude
www.austriamicrosystems.com
Bpk
45
Max
Unit
Note
mm
Recommended magnet: Ø 6mm x 2.5mm for
cylindrical magnets
mm
75
Revision 2.10
mT
Required vertical component of the
magnetic field strength on the die’s surface,
measured along a concentric circle with a
radius of 1.1mm
5 - 33
AS5040
Data Sheet
Parameter
Magnetic offset
Symbol
Min
Typ
Max
Unit
± 10
mT
Constant magnetic stray field
5
%
Including offset gradient
fmag_abs
10
Hz
Absolute mode: 600 rpm @ readout of 1024
positions (see Table 6)
fmag_inc
500
Hz
Incremental mode: no missing pulses at
rotational speeds of up to 30,000 rpm (see
Table 6)
Boff
Field non-linearity
Input frequency
(rotational speed of
magnet)
0.25
Displacement radius
Disp
mm
0.485
Chip placement
tolerance
±0.23
5
Recommended magnet
material and
temperature drift
mm
-0.12
%/K
-0.035
Note
Max. X-Y offset between defined IC package
center and magnet axis (see Figure 21)
Max. X-Y offset between chip center and
magnet axis.
Placement tolerance of chip within IC
package (see Figure 23)
NdFeB (Neodymium Iron Boron)
SmCo (Samarium Cobalt)
Electrical System Specifications
(operating conditions: Tamb = -40 to +125°C, VDD5V = 3.0-3.6V (3V operation) VDD5V = 4.5-5.5V (5V operation) unless otherwise
noted)
Parameter
Resolution
Symbol
Min
RES
9 bit
Integral non-linearity
(optimum)
Unit
10
bit
1.406
LSB
deg
0.703
10 bit
Integral non-linearity
(optimum)
Max
Note
0.352 deg
2.813
7 bit
8 bit
Typ
Adjustable resolution only available
for incremental output modes;
Least significant bit, minimum step
0.352
± 0.5
INLopt
± 0.9
INLtemp
deg
Maximum error with respect to the
best line fit.
Verified at optimum magnet
placement, Tamb =25 °C.
deg
Maximum error with respect to the
best line fit.
Verified at optimum magnet
placement ,
Tamb = -40 to +125°C
Best line fit = (Errmax – Errmin) / 2
Integral non-linearity
INL
± 1.4
deg
Over displacement tolerance with
6mm diameter magnet, Tamb = -40 to
+125°C
Differential non-linearity
DNL
± 0.176
deg
10bit, no missing codes
TN
0.12
Deg
RMS
RMS equivalent to 1 sigma
deg
Incremental modes only
Transition noise
Hysteresis
Hyst
0.704
Power-on reset thresholds
On voltage; 300mV typ.
hysteresis
Von
1.37
Off voltage; 300mV typ.
hysteresis
Voff
1.08
2.2
2.9
V
1.9
2.6
DC supply voltage 3.3V (VDD3V3)
DC supply voltage 3.3V (VDD3V3)
Power-up time
tPwrUp
50
ms
Until offset compensation finished
System propagation delay
absolute output
tdelay
48
µs
Includes delay of ADC and DSP
www.austriamicrosystems.com
Revision 2.10
6 - 33
AS5040
Data Sheet
Parameter
Symbol
Min
Typ
Max
Unit
192
µs
System propagation delay
incremental output
9.90
Sampling rate for absolute
output
10.42
10.94
Read-out frequency
9.38
10.42
11.46
CLK
Calculation over two samples
Internal sampling rate, Tamb = 25°C
kHz
fS
Note
1
MHz
Internal sampling rate, Tamb = -40 to
+125°C
Max. clock frequency to read out
serial data
Figure 3: Integral and Differential Non-linearity Example (exaggerated curve)
α 10bit code
1023
1023
Actual curve
TN
2
DNL+1LSB
1
Ideal curve
INL
0.35°
0
512
512
0
360 °
180°
0°
α [degrees]
Integral Non-Linearity (INL) is the maximum deviation between actual position and indicated position.
Differential Non-Linearity (DNL) is the maximum deviation of the step length from one position to the next.
Transition Noise (TN) is the repeatability of an indicated position.
Timing Characteristics
Synchronous Serial Interface (SSI)
(operating conditions: Tamb = -40 to +125°C, VDD5V = 3.0-3.6V (3V operation) VDD5V = 4.5-5.5V (5V operation) unless otherwise
noted)
Parameter
Data output activated
(logic high)
Symbol
Min
t DO active
Typ
Max
Unit
Note
100
ns
Time between falling edge of CSn and
data output activated
First data shifted to output
register
tCLK FE
500
ns
Time between falling edge of CSn and
first falling edge of CLK
Start of data output
T CLK / 2
500
ns
Rising edge of CLK shifts out one bit at a
time
Data output valid
t DO valid
357
413
ns
Time between rising edge of CLK and
data output valid
100
ns
After the last bit DO changes back to
“tristate”
ns
CSn = high; To initiate read-out of next
angular position
Data output tristate
t DO tristate
Pulse width of CSn
t CSn
www.austriamicrosystems.com
500
Revision 2.10
7 - 33
AS5040
Data Sheet
Parameter
Symbol
Min
fCLK
>0
Read-out frequency
Typ
Max
Unit
1
MHz
Note
Clock frequency to read out serial data
Pulse Width Modulation Output
(operating conditions: Tamb = -40 to +125°C, VDD5V = 3.0-3.6V (3V operation) VDD5V = 4.5-5.5V (5V operation) unless otherwise
noted)
Parameter
Symbol
PWM frequency
f PWM
Min
Typ
Max
0.927
0.976
1.024
Unit
KHz
Note
Signal period = 1025µs ±5% at Tamb = 25°C
=1025µs ±10% at Tamb = -40 to +125°C
0.878
0.976
1.074
Minimum pulse width
PW MIN
0.90
1
1.10
µs
Position 0d; angle 0 degree
Maximum pulse width
PW MAX
922
1024
1126
µs
Position 1023d; angle 359.65 degree
Incremental Outputs
(operating conditions: Tamb = -40 to +125°C, VDD5V = 3.0-3.6V (3V operation) VDD5V = 4.5-5.5V (5V operation) unless otherwise
noted)
Parameter
Symbol
Incremental outputs valid
after power-up
t Incremental
Directional indication valid
t Dir valid
Min
Typ
Max
Unit
500
ns
Time between first falling edge of CSn
after power-up and valid incremental
outputs
500
ns
Time between rising or falling edge of
LSB output and valid directional indication
outputs valid
Note
Programming Conditions
(operating conditions: Tamb = -40 to +125°C, VDD5V = 3.0-3.6V (3V operation) VDD5V = 4.5-5.5V (5V operation) unless otherwise
noted)
Parameter
Symbol
Min
Programming enable time
t Prog enable
2
µs
Write data start
t Data in
2
µs
Write data valid
t Data in valid
250
ns
Load programming data
t Load PROG
3
µs
Rise time of VPROG before
CLKPROG
t PrgR
0
µs
Hold time of VPROG after
CLKPROG
t PrgH
0
Write data – programming
CLKPROG
CLK pulse width
µs
During programming; 16 clock cycles
µs
Programmed data is available after
next power-on
7.5
V
Must be switched off after zapping
1
V
Line must be discharged to this level
I PROG
130
mA
During programming
CLKAread
100
kHz
Analog readback mode
Vprogrammed
100
mV
V PROG
7.3
Programming voltage off level
V ProgOff
0
www.austriamicrosystems.com
Write data at the rising edge of
CLKPROG
2.2
Programming voltage
Unprogrammed zener voltage
(log. 0)
Time between rising edge at Prog pin
and rising edge of CSn
kHz
2
Programmed zener voltage
(log.1)
Note
250
CLK PROG
t PROG finished
Analog read CLK
Unit
µs
1.8
Programming current
Max
5
t PROG
Hold time of Vprog after
programming
Typ
Vunprogrammed
2
7.4
1
V
Revision 2.10
VRef-VPROG during analog readback
mode (see Analog Readback Mode)
8 - 33
AS5040
Data Sheet
6 Functional Description
The AS5040 is manufactured in a CMOS standard process and uses a spinning current Hall technology for sensing
the magnetic field distribution across the surface of the chip.
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 AS5040
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 M a g I N C n and M a g D E C n 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 (see
Figure 20).
The AS5040 senses the orientation of the magnetic field and calculates a 10-bit binary code. This code can be
accessed via a Synchronous Serial Interface (SSI). In addition, an absolute angular representation is given by a Pulse
Width Modulated signal at pin 12 (PWM).
Besides the absolute angular position information the device simultaneously provides incremental output signals. The
various incremental output modes can be selected by programming the OTP mode register bits (see page 19). As
long as no programming voltage is applied to pin Prog, the new setting may be overwritten at any time and will be
reset to default when power is turned off. To make the setting permanent, the OTP register must be programmed (see
Figure 15). The default setting is a quadrature A/B mode including the Index signal with a pulse width of 1 LSB. The
Index signal is logic high at the user programmable zero position.
The AS5040 is tolerant to magnet misalignment and magnetic stray fields due to differential measurement technique
and Hall sensor conditioning circuitry.
Figure 4: AS5040 Block Diagram
www.austriamicrosystems.com
Revision 2.10
9 - 33
AS5040
Data Sheet
7 10-bit Absolute Angular Position Output
Synchronous Serial Interface (SSI)
Figure 5: Synchronous Serial Interface with Absolute Angular Position Data
CSn
t CLK FE
T CLK / 2
t CSn
1
CLK
DO
D9
t DO active
t DO valid
8
D8
D7
D6
D5
D4
D3
D2
t CLK FE
1
16
D1
D0
OCF
COF
LIN
Mag
INC
M ag Even
D EC PAR
Status Bits
Angular Position Data
D9
t DO Tristate
If CSn changes to logic low, Data Out (DO) will change from high impedance (tri-state) to logic high and the read-out
will be initiated.
ƒ
After a minimum time tCLK FE, data is latched into the output shift register with the first falling edge of CLK.
ƒ
Each subsequent rising CLK edge shifts out one bit of data.
ƒ
The serial word contains 16 bits, the first 10 bits are the angular information D[9:0], the subsequent 6 bits contain
system information, about the validity of data such as OCF, COF, LIN, Parity and Magnetic Field status
(increase/decrease) .
ƒ
A subsequent measurement is initiated by a log. “high” pulse at CSn with a minimum duration of tCSn.
Data Content:
D9:D0 absolute angular position data (MSB is clocked out first)
OCF (Offset Compensation Finished), logic high indicates the finished Offset Compensation Algorithm.
For fast startup, this bit may be polled by the external microcontroller. As soon as this bit is set, the AS5040 has
completed the startup and the data is valid (see Table 4)
COF (Cordic Overflow), logic high indicates an out of range error in the CORDIC part. When this bit is set, the
data at D9:D0 is invalid. The absolute output maintains the last valid angular value.
This alarm may be resolved by bringing the magnet within the X-Y-Z tolerance limits.
LIN (Linearity Alarm), logic high indicates that the input field generates a critical output linearity.
When this bit is set, the data at D9:D0 may still be used, but can contain invalid data. This warning may be
resolved by bringing the magnet within the X-Y-Z tolerance limits.
MagINCn, (Magnitude Increase) becomes HIGH, when the magnet is pushed towards the IC, thus the magnetic field
strength is increasing.
MagDECn, (Magnitude Decrease) becomes HIGH, when the magnet is pulled away from the IC, thus the magnetic
field strength is decreasing.
Both signals HIGH indicate a magnetic field that is out of the allowed range (see Table 3).
www.austriamicrosystems.com
Revision 2.10
10 - 33
AS5040
Data Sheet
Table 3: Magnetic Magnitude Variation Indicator
Mag
INCn
Mag
DECn
0
0
No distance change; Magnetic input field OK (in range, 45..75mT)
0
1
Distance increase: Pull-function. This state is dynamic, it is only active while the magnet is
moving away from the chip in Z-axis
1
0
Distance decrease: Push- function. This state is dynamic, it is only active while the magnet is
moving towards the chip in Z.-axis.
1
1
Magnetic Input Field invalid – out of range: <45mT or >75mT (or missing magnet)
Description
Note: Pins 1 and 2 (MagINCn, MagDECn) are open drain outputs and require external pull-up resistors. If the
magnetic field is in range, both outputs are turned off.
The two pins may also be combined with a single pull-up resistor. In this case, the signal is high when the magnetic
field is in range. It is low in all other cases (see Table 3).
Even Parity bit for transmission error detection of bits 1…15 (D9…D0, OCF, COF, LIN, MagINCn, MagDECn)
The absolute angular output is always set to a resolution of 10 bit. Placing the magnet above the chip, angular values
increase in clockwise direction by default.
Data D9:D0 is valid, when the status bits have the following configurations:
Table 4: Status Bit Outputs
OCF
1
COF
0
LIN
0
Mag
INCn
Mag
DECn
0
0
0
1
1
0
Parity
even checksum of bits
1:15
The absolute angular position is sampled at a rate of 10kHz (0.1ms). This allows reading of all 1024 positions per 360
degrees within 0.1 seconds = 9.76Hz (~10Hz) without skipping any position. Multiplying 10Hz by 60, results the
corresponding maximum rotational speed of 600 rpm.
Readout of every second angular position allows for rotational speeds of up to 1200rpm.
Consequently, increasing the rotational speed reduces the number of absolute angular positions per revolution (see
Table 7). Regardless of the rotational speed or the number of positions to be read out, the absolute angular value is
always given at the highest resolution of 10 bit.
The incremental outputs are not affected by rotational speed restrictions due to the implemented interpolator. The
incremental output signals may be used for high-speed applications with rotational speeds of up to 30,000 rpm without
missing pulses.
Daisy Chain Mode
The Daisy Chain mode allows connection of several AS5040’s in series, while still keeping just one digital input for
data transfer (see “Data IN” in Figure 6 below). This mode is accomplished by connecting the data output (DO; pin 9)
to the data input (Prog; pin 8) of the subsequent device. An RC filter must be implemented between each PROG pin
of device n and DO pin of device n+1, to prevent the encoders to enter the alignment mode, in case of ESD
discharge, long cables, or not conform signal levels or shape. Using the values R=100R and C=1nF allow a max. CLK
frequency of 1MHz on the whole chain. The serial data of all connected devices is read from the DO pin of the first
device in the chain. The Prog pin of the last device in the chain should be connected to VSS. The length of the serial
bit stream increases with every connected device, it is
n * (16+1) bits:
e.g. 34 bit for two devices, 51 bit for three devices, etc…
The last data bit of the first device (Parity) is followed by a logic low bit and the first data bit of the second device (D9),
etc… (see Figure 7).
www.austriamicrosystems.com
Revision 2.10
11 - 33
AS5040
Data Sheet
Programming Daisy Chained Devices
In Daisy Chain mode, the Prog pin is connected directly to the DO pin of the subsequent device in the chain (see
Figure 6). During programming (see section 12), a programming voltage of 7.5V must be applied to pin Prog. This
voltage level exceeds the limits for pin DO, so one of the following precautions must be made during programming:
ƒ
open the connection DOÆProg during programming or
ƒ
add a Schottky diode between DO and Prog (Anode = DO, Cathode = Prog)
Due to the parallel connection of CLK and CSn, all connected devices may be programmed simultaneously.
Figure 6: Daisy Chain Hardware Configuration
CSn
CSn
CSn
CLK
CLK
CLK
DI
DO
100R
PROG
CSn
DO
PROG
GND
GND
GND
AS5040
DO
1nF
1nF
MCU
CLK
100R
PROG
AS5040
AS5040
Figure 7: Daisy Chain Mode Data Transfer
CSn
tCLK FE
TCLK/2
1
CLK
DO
D9
tDO active
8
D8
D7
D6
tDO valid
D5
D4
D3
D2
16
D1
D0
OCF
Angular Position Data
COF
LIN
Mag
INC
Status Bits
1st Device
Mag
DEC
Even
PAR
D
1
D9
2
D8
3
D7
Angular Position Data
2nd Device
8 Incremental Outputs
Three different incremental output modes are possible with quadrature A/B being the default mode.
Figure 8 shows the two-channel quadrature as well as the step / direction incremental signal (LSB) and the direction
bit in clockwise (CW) and counter-clockwise (CCW) direction.
Quadrature A/B Output (Quad A/B Mode)
The phase shift between channel A and B indicates the direction of the magnet movement. Channel A leads channel
B at a clockwise rotation of the magnet (top view) by 90 electrical degrees. Channel B leads channel A at a counterclockwise rotation.
LSB Output (Step / Direction Mode)
Output LSB reflects the LSB (least significant bit) of the programmed incremental resolution (OTP Register Bit Div0,
Div1). Output Dir provides information about the rotational direction of the magnet, which may be placed above or
below the device (1=clockwise; 0=counter clockwise; top view). Dir is updated with every LSB change.
In both modes (quad A/B, step/direction) the resolution and the index output are user programmable. The index pulse
indicates the zero position and is by default one angular step (1LSB) wide. However, it can be set to three LSBs by
programming the Index-bit of the OTP register accordingly (see Table 6).
www.austriamicrosystems.com
Revision 2.10
12 - 33
AS5040
Data Sheet
Figure 8: Incremental Output Modes
Q uad A/B-M ode
M echanical
Zero Position
Rotation Direction
Change
M echanical
Zero Position
A
B
Index=0
1LSB
H yst =
2 LSB
Index
Step / Dir-Mode
Index=1
3 LSB
LSB
Dir
Clockwise cw
CSn
Counterclockwise ccw
t
t
D ir valid
Increm ental outputs valid
Incremental Power-up Lock Option
After power-up, the incremental outputs can optionally be locked or unlocked, depending on the status of the CSn pin:
CSn = low at power-up:
CSn has an internal pull-up resistor and must be externally pulled low (Rext ≤ 5kΩ). If Csn is low at power-up,
the incremental outputs (A, B, Index) will be high until the internal offset compensation is finished.
This unique state (A=B=Index = high) may be used as an indicator for the external controller to shorten the
waiting time at power-up. Instead of waiting for the specified maximum power up-time (0), the controller can
start requesting data from the AS5040 as soon as the state (A=B=Index = high) is cleared.
CSn = high or open at power-up:
In this mode, the incremental outputs (A, B, Index) will remain at logic high state, until CSn goes low or a low
pulse is applied at CSn. This mode allows intentional disabling of the incremental outputs until for example the
system microcontroller is ready to receive data.
Incremental Output Hysteresis
To avoid flickering incremental outputs at a stationary magnet position, a hysteresis is introduced.
In case of a rotational direction change, the incremental outputs have a hysteresis of 2 LSB.
Regardless of the programmed incremental resolution, the hysteresis of 2 LSB always corresponds to the highest
resolution of 10 bit. In absolute terms, the hysteresis is set to 0.704 degrees for all resolutions.
For constant rotational directions, every magnet position change is indicated at the incremental outputs (see
Figure 9). If for example the magnet turns clockwise from position „x+3“ to „x+4“, the incremental output would also
indicate this position accordingly.
A change of the magnet’s rotational direction back to position „x+3“ means, that the incremental output still remains
unchanged for the duration of 2 LSB, until position „x+2“ is reached. Following this direction, the incremental outputs
will again be updated with every change of the magnet position.
www.austriamicrosystems.com
Revision 2.10
13 - 33
AS5040
Data Sheet
Figure 9: Hysteresis Window for Incremental Outputs
Incremental
Output
Indication
X +4
Hysteresis:
0.7°
X +3
X +2
X +1
X
X
X +1 X +2 X +3 X +4 X +5
Magnet Position
Clockwise Direction
Counterclockwise Direction
9 Pulse Width Modulation (PWM) Output
The AS5040 provides a pulse width modulated output (PWM), whose duty cycle is proportional to the measured
angle:
Position =
t on ⋅ 1025
(ton + toff ) − 1
The PWM frequency is internally trimmed to an accuracy of ±5% (±10% over full temperature range). This tolerance
can be cancelled by measuring the complete duty cycle as shown above.
Figure 10: PWM Output Signal
Angle
PW MIN
0 deg
(Pos 0)
1µs
1025µs
PW MAX
359.65 deg
(Pos 1023)
1024µs
1/fPWM
www.austriamicrosystems.com
Revision 2.10
14 - 33
AS5040
Data Sheet
Table 5: PWM Signal Parameters
Parameter
Symbol
Typ
Unit
Note
PWM frequency
fPWM
0.9756
kHz
MIN pulse width
PWMIN
1
µs
- Position 0d
- Angle 0 deg
MAX pulse width
PWMAX
1024
µs
- Position 1023d
- Angle 359,65 deg
Signal period: 1025µs
10 Analog Output
An analog output may be generated by averaging the PWM signal, using an external active or passive lowpass filter.
The analog output voltage is proportional to the angle: 0°= 0V; 360° = VDD5V.
Using this method, the AS5040 can be used as direct replacement of potentiometers.
Figure 11: Simple Passive 2nd Order Lowpass Filter
Pin12
R2
R1
analog out
PWM
VDD2
C1
C2
0V2
0°
Pin7
360°
VSS
R1,R2 ≥ 4k7
C1,C2 ≥ 1µF / 6V
R1 should be ≥4k7 to avoid loading of the PWM output. Larger values of Rx and Cx will provide better filtering and
less ripple, but will also slow down the response time.
11 Brushless DC Motor Commutation Mode
Brushless DC motors require angular information for stator commutation. The AS5040 provides U-V-W commutation
signals for one and two pole pair motors. In addition to the three-phase output signals, the step (LSB) output at pin 12
allows high accuracy speed measurement. Two resolutions (9 or 10 bit) can be selected by programming Div0
according to Table 6.
Mode 3.0 (3.1) is used for brush-less DC motors with one-pole pair rotors. The three phases (U, V, W) are 120
degrees apart, each phase is 180 degrees on and 180 degrees off.
Mode 3.2 (3.3) is used for motors with two pole pairs requiring a higher pulse count to ensure a proper current
commutation. In this case the pulse width is 256 positions, equal to 90 degrees.
The precise physical angle at which the U, V and W signals change state (“Angle” in Figure 12 and Figure 13) is
calculated by multiplying each transition position by the angular value of 1 count:
Angle [deg] = Position x (360 degree / 1024)
www.austriamicrosystems.com
Revision 2.10
15 - 33
AS5040
Data Sheet
Figure 12: U, V and V-signals for BLDC Motor Commutation (Div1=0, Div0=0)
Commutation - Mode 3.0
(One-pole-pair)
Width: 512 Steps
Width: 512 Steps
U
V
W
CW Direction
Position:
Angle:
0
171
341
512
683
853
0
0.0
60.12
119.88
180.0
240.12
299.88
360.0
Figure 13: U, V and W-signals for 2-pole BLDC Motor Commutation (Div1=1; Div0=0)
Commutation - Mode 3.2
Width: 256 Steps
(Two-pole-pairs)
Width: 256 Steps
U
V
W
CW Direction
Position:
Angle:
0
85
171
256
341
427
512
597
683
768
853
939
0
0.0
29.88
60.12
90.0
119.88
150.12
180.0
209.88
240.12
270.00
299.88
330.12
360.0
12 Programming the AS5040
After power-on, programming the AS5040 is enabled with the rising edge of CSn with Prog = high and CLK = low. 16
bit configuration data must be serially shifted into the OTP register via the Prog-pin. The first “CCW” bit is followed by
the zero position data (MSB first) and the incremental mode setting as shown in Table 6. Data must be valid at the
rising edge of CLK (see Figure 14).
After writing data into the OTP register it can be permanently programmed by rising the Prog pin to the programming
voltage VPROG. 16 CLK pulses (tPROG) must be applied to program the fuses (Figure 15). To exit the programming
mode, the chip must be reset by a power-on-reset. The programmed data is available after the next power-up.
Note: During the programming process, the transitions in the programming current may cause high voltage spikes
generated by the inductance of the connection cable. To avoid these spikes and possible damage to the IC, the
connection wires, especially the signals Prog and VSS must be kept as short as possible. The maximum wire length
between the VPROG switching transistor and pin Prog (see Figure 16) should not exceed 50mm (2 inches). To
suppress eventual voltage spikes, a 10nF ceramic capacitor should be connected close to pins Prog and VSS. This
capacitor is only required for programming, it is not required for normal operation.
The clock timing tclk must be selected at a proper rate to ensure that the signal Prog is stable at the rising edge of CLK
(see Figure 14). Additionally, the programming supply voltage should be buffered with a 10µF capacitor mounted
close to the switching transistor. This capacitor aids in providing peak currents during programming.
The specified programming voltage at pin Prog is 7.3 – 7.5V (see section 0). To compensate for the voltage drop
across the VPROG switching transistor, the applied programming voltage may be set slightly higher (7.5 - 8.0V, see
Figure 16).
www.austriamicrosystems.com
Revision 2.10
16 - 33
AS5040
Data Sheet
OTP Register Contents:
CCW
Counter Clockwise Bit
ccw=0 – angular value increases in clockwise direction
ccw=1 – angular value increases in counterclockwise direction
Z [9:0]
Programmable Zero / Index Position
Indx
Index Pulse Width Selection: 1LSB / 3LSB
Div1,Div0
Divider Setting of Incremental Output
Md1, Md0
Incremental Output Mode Selection
OTP Default Setting
The AS5040 can also be operated without programming. The default, un-programmed setting is shown in Table 6
(Mode 0.0):
CCW: 0
= clockwise operation
Z9 to Z0: 00
= no programmed zero position
Indx: 0
= Index bit width = 1LSB
Div0,Div1 : 00
= incremental resolution = 10bit
Md0, MD1: 00
= incremental mode = quadrature
Figure 14: Programming Access – Write Data (section of Figure 15)
Figure 15: Complete Programming Sequence
Write Data
Programming Mode
Power Off
CSn
Prog
Data
1
16
7.5V
VDD
VProgOff
0V
CLKPROG
tLoad PROG
www.austriamicrosystems.com
tPrgH
tPrgR
tPROG
Revision 2.10
tPROG finished
17 - 33
AS5040
Data Sheet
USB
Figure 16: OTP Programming Connection of AS5040 (shown with AS5040 demoboard)
Incremental Mode Programming
Three different incremental output modes are available.
Mode: Md1=0 / Md0=1 sets the AS5040 in quadrature mode.
Mode: Md1=1 / Md0=0 sets the AS5040 in step / direction mode (see Table 1)
In both modes, the incremental resolution may be reduced from 10 bit down to 9, 8 or 7 bit using the divider OTP bits
Div1 and Div0. (see Table 6 below ).
Mode: Md1=1 / Md0=1 sets the AS5040 in brushless DC motor commutation mode with an additional LSB
incremental signal at pin 12 (PWM_LSB).
To allow programming of all bits, the default factory setting is all bits = 0. This mode is equal to mode 1:0 (quadrature
A/B, 1LSB index width, 256ppr).
The absolute angular output value, by default, increases with clockwise rotation of the magnet (top view).
Setting the CCW-bit (see Figure 14) allows reversing the indicated direction, e.g. when the magnet is placed
underneath the IC:
CCW = 0 – angular value increases clockwise;
CCW = 1 – angular value increases counterclockwise.
By default, the zero / index position pulse is one LSB wide. It can be increased to a three LSB wide pulse by setting
the Index-bit of the OTP register.
Further programming options (commutation modes) are available for brushless DC motor-control.
Md1 = Md0 = 1 changes the incremental output pins 3, 4 and 6 to a 3-phase commutation signal. Div1 defines the
number of pulses per revolution for either a two-pole (Div1=0) or four-pole (Div1=1) rotor.
In addition, the LSB is available at pin 12 (the LSB signal replaces the PWM signal), which allows for high rotational
speed measurement of up to 30,000 rpm.
www.austriamicrosystems.com
Revision 2.10
18 - 33
AS5040
Data Sheet
Table 6: One Time Programmable (OTP) Register Options
OTP-Mode-Register-Bit
Mode
Md1
Pin #
Md0
Div1
Div0
Index
3
4
6
Default (Mode0.0)
0
0
0*
0*
0*
quadAB-Mode1.0
0
1
0
0
0
1LSB
quadAB-Mode1.1
0
1
0
0
1
3LSBs
quadAB-Mode1.2
0
1
0
1
0
quadAB-Mode1.3
0
1
0
1
1
1LSB
A
B
3LSBs
0
1
1
0
0
1LSB
quadAB-Mode1.5
0
1
1
0
1
3LSBs
quadAB-Mode1.6
0
1
1
1
0
1LSB
quadAB-Mode1.7
0
1
1
1
1
3LSBs
Step/Dir-Mode2.0
1
0
0
0
0
1LSB
Step/Dir-Mode2.1
1
0
0
0
1
3LSBs
Step/Dir -Mode2.2
1
0
0
1
0
1LSB
Step/Dir -Mode2.3
1
0
0
1
1
Step/Dir -Mode2.4
1
0
1
0
0
Step/Dir -Mode2.5
1
0
1
0
1
LSB
Dir
3LSBs
1LSB
1
0
1
1
0
1LSB
Step/Dir -Mode2.7
1
0
1
1
1
3LSBs
CommutationMode3.0
1
1
0
0
0
CommutationMode3.1
1
1
0
1
0
CommutationMode3.2
1
1
1
0
0
CommutationMode3.3
1
0
ppr
bit
2x256
10
2x128
9
2x64
8
2x32
7
512
10
256
9
128
8
64
7
PWM
10 bit
10
U(0º)
1
PWM
10 bit
3LSBs
Step/Dir -Mode2.6
1
Incremental
Resolution
1LSB
quadAB-Mode1.4
1
12
Pulses per
Revolution
V(120º)
W(240º)
LSB
3x1
9
U’
(0º,
180º)
V’
(60º,
240º)
W’
(120º, 300º)
10
LSB
2x3
9
Note: Div1, Div0 and Index cannot be programmed in Mode 0:0
Zero Position Programming
Zero position programming is an OTP option that simplifies assembly of a system, as the magnet does not need to be
manually adjusted to the mechanical zero position. Once the assembly is completed, the mechanical and electrical
zero positions can be matched by software. Any position within a full turn can be defined as the permanent new
zero/index position.
For zero position programming, the magnet is turned to the mechanical zero position (e.g. the “off”-position of a rotary
switch) and the actual angular value is read.
This value is written into the OTP register bits Z9:Z0 (see Figure 14) and programmed as described in section 12.
This new absolute zero position is also the new Index pulse position for incremental output modes.
Note: The zero position value may also be modified before programming, e.g. to program an electrical zero position
that is 180° (half turn) from the mechanical zero position, just add 512 to the value read at the mechanical zero
position and program the new value into the OTP register.
www.austriamicrosystems.com
Revision 2.10
19 - 33
AS5040
Data Sheet
Repeated OTP Programming
Although a single AS5040 OTP register bit can be programmed only once (from 0 to 1), it is possible to program other,
unprogrammed bits in subsequent programming cycles. However, a bit that has already been programmed should not
be programmed twice. Therefore it is recommended that bits that are already programmed are set to “0” during a
programming cycle.
Non-permanent Programming
It is also possible to re-configure the AS5040 in a non-permanent way by overwriting the OTP register.
This procedure is essentially a “Write Data” sequence (see Figure 14) without a subsequent OTP programming cycle.
The “Write Data” sequence may be applied at any time during normal operation. This configuration remains set while
the power supply voltage is above the power-on reset level (see 0).
See Application Note AN5000-20 for further information.
Analog Readback Mode
Non-volatile programming (OTP) uses on-chip zener diodes, which become permanently low resistive when subjected
to a specified reverse current.
The quality of the programming process depends on the amount of current that is applied during the programming
process (up to 130mA). This current must be provided by an external voltage source. If this voltage source cannot
provide adequate power, the zener diodes may not be programmed properly.
In order to verify the quality of the programmed bits, an analog level can be read for each zener diode, giving an
indication whether this particular bit was properly programmed or not.
To put the AS5040 in analog readback mode, a digital sequence must be applied to pins CSn, Prog and CLK as
shown in Figure 17. The digital level for this pin depends on the supply configuration (3.3V or 5V; see section 14).
The second rising edge on CSn (OutpEN) changes pin Prog to a digital output and the log. high signal at pin Prog
must be removed to avoid collision of outputs (grey area in Figure 17).
The following falling slope of CSn changes pin Prog to an analog output, providing a reference voltage Vref, that must
be saved as a reference for the calculation of the subsequent programmed and unprogrammed OTP bits.
Following this step, each rising slope of CLK outputs one bit of data in the reverse order as during programming.
(see Figure 17: Md0-MD1-Div0,Div1-Indx-Z0…Z9, ccw)
During analog readback, the capacitor at pin Prog (see Figure 16) should be removed to allow a fast readout rate. . If
the capacitor is not removed the analog voltage will take longer to stabilize due to the additional capacitance.
The measured analog voltage for each bit must be subtracted from the previously measured Vref, and the resulting
value gives an indication on the quality of the programmed bit: a reading of <100mV indicates a properly programmed
bit and a reading of >1V indicates a properly unprogrammed bit.
A reading between 100mV and 1V indicates a faulty bit, which may result in an undefined digital value, when the OTP
is read at power-up.
Following the 16th clock (after reading bit “ccw”), the chip must be reset by disconnecting the power supply.
Figure 17: OTP Register Analog Read
P ro g E N
O u tp E N
P o w e r-o n R e se t;
tu rn o ff
s u p p ly
A n a lo g R e a d b a c k D a ta a t P ro g
CSn
V re f
In te rn a l
te s t b it
d ig ita l
P ro g
V p ro g ra m m e d
M d 0 M d 1 D iv 0 D iv1 V u n p ro g ra m m e d Z 5
Z6
Z7
Z8
Z9
ccw
P ro g c h a n g e s to O u tp u t
1
CLK
t L o a d P ro g
www.austriamicrosystems.com
16
C L K A re a d
Revision 2.10
20 - 33
AS5040
Data Sheet
13 Alignment Mode
The alignment mode simplifies centering the magnet over the chip to gain maximum accuracy and XY-alignment
tolerance.
This electrical centering method allows a wider XY-alignment tolerance (0.485mm radius) than mechanical centering
(0.25mm radius) as it eliminates the placement tolerance of the die within the IC package (+/- 0.235mm).
Alignment mode can be enabled with the falling edge of CSn while Prog = logic high (Figure 18). The Data bits D9-D0
of the SSI change to a 10-bit displacement amplitude output. A high value indicates large X or Y displacement, but
also higher absolute magnetic field strength. The magnet is properly aligned, when the difference between highest
and lowest value over one full turn is at a minimum.
Under normal conditions, a properly aligned magnet will result in a reading of less than 32 over a full turn.
The MagINCn and MagDECn indicators will be = 1 when the alignment mode reading is < 32. At the same time, both
hardware pins MagINCn (#1) and MagDECn (#2) will be pulled to VSS. A properly aligned magnet will therefore
produce a MagINCn = MagDECn = 1 signal throughout a full 360° turn of the magnet.
Stronger magnets or short gaps between magnet and IC may show values larger than 32. These magnets are still
properly aligned as long as the difference between highest and lowest value over one full turn is at a minimum.
The alignment mode can be reset to normal operation mode by a power-on-reset (disconnect / re-connect power
supply).
Figure 18: Enabling the Alignment Mode
Prog
CSn
AlignMode enable
Read-out
via SSI
2µs 2µs
min. min.
14 3.3V / 5V Operation
The AS5040 operates either at 3.3V ±10% or at 5V ±10%. This is made possible by an internal 3.3V Low-Dropout
(LDO) voltage regulator. The internal supply voltage is always taken from the output of the LDO, meaning that the
internal blocks are always operating at 3.3V.
For 3.3V operation, the LDO must be bypassed by connecting VDD3V3 with VDD5V (see Figure 19).
For 5V operation, the 5V supply is connected to pin VDD5V, while VDD3V3 (LDO output) must be buffered by a
2.2...10µF capacitor, which is supposed to be placed close to the supply pin (see Figure 19).
The VDD3V3 output is intended for internal use only It must not be loaded with an external load.
The output voltage of the digital interface I/O’s corresponds to the voltage at pin VDD5V, as the I/O buffers are
supplied from this pin (see Figure 19).
www.austriamicrosystems.com
Revision 2.10
21 - 33
AS5040
Data Sheet
Figure 19: Connections for 5V / 3.3V Supply Voltages
5V Operation
3.3V Operation
2.2...10µF
VDD3V3
VDD3V3
100n
VDD5V
100n
LDO
VDD5V
Internal
VDD
LDO
Internal
VDD
DO
DO
4.5 - 5.5V
VSS
I
N
T
E
R
F
A
C
E
PWM_LSB
CLK
3.0 - 3.6V
CSn
A_LSB_U
B_Dir_V
Index_W
Prog
VSS
I
N
T
E
R
F
A
C
E
PWM_LSB
CLK
CSn
A_LSB_U
B_Dir_V
Index_W
Prog
A buffer capacitor of 100nF is recommended in both cases close to pin VDD5V. Note that pin VDD3V3 must always
be buffered by a capacitor. It must not be left floating, as this may cause an instable internal 3.3V supply voltage
which may lead to larger than normal jitter of the measured angle.
15 Choosing the Proper Magnet
Typically the magnet should be 6mm in diameter and ≥2.5mm in height. Magnetic materials such as rare earth
AlNiCo, SmCo5 or NdFeB are recommended.
The magnet’s field strength perpendicular to the die surface should be verified using a gauss-meter. The magnetic
field Bv at a given distance, along a concentric circle with a radius of 1.1mm (R1), should be in the range of
±45mT…±75mT. (see Figure 20).
www.austriamicrosystems.com
Revision 2.10
22 - 33
AS5040
Data Sheet
Figure 20: Typical Magnet and Magnetic Field Distribution
typ. 6mm diameter
N
S
Vertical field
component
Magnet axis
R1
Magnet axis
Bv
(45…75mT)
Vertical field
component
0
N
360
S
R1 concentric circle;
radius 1.1mm
Physical Placement of the Magnet
The best linearity can be achieved by placing the center of the magnet exactly over the defined center of the IC
package as shown in Figure 21:
Figure 21: Defined IC Center and Magnet Displacement Radius
3.9 mm
3.9 mm
1
2.433 mm
Defined
center
Rd
2.433 mm
Area of recommended maximum
magnet misalignment
Magnet Placement
The magnet’s center axis should be aligned within a displacement radius Rd of 0.25mm from the defined center of the
IC with reference to the edge of pin #1 (see Figure 21). This radius includes the placement tolerance of the chip within
the SSOP-16 package (+/- 0.235mm). The displacement radius Rd is 0.485mm with reference to the center of the chip
(see section 13: Alignment Mode)
www.austriamicrosystems.com
Revision 2.10
23 - 33
AS5040
Data Sheet
The vertical distance should be chosen such that the magnetic field on the die surface is within the specified limits
(see Figure 20). The typical distance “z” between the magnet and the package surface is 0.5mm to 1.8mm with the
recommended magnet (6mm x 2.5mm). Larger gaps are possible, as long as the required magnetic field strength
stays within the defined limits.
A magnetic field outside the specified range may still produce usable results, but the out-of-range condition will be
indicated by MagINCn (pin 1) and MagDECn (pin 2), see Table 3.
Figure 22: Vertical Placement of the Magnet
N
Die surface
S
Package surface
z
0.576mm ± 0.1mm
1.282mm ± 0.15mm
16 Simulation Modelling
Figure 23: Arrangement of Hall Sensor Array on Chip (principle)
With reference to Figure 23, a diametrically magnetized permanent magnet is placed above or below the surface of
the AS5040. The chip uses an array of Hall sensors to sample the vertical vector of a magnetic field distributed across
the device package surface. The area of magnetic sensitivity is a circular locus of 1.1mm radius with respect to the
center of the die. The Hall sensors in the area of magnetic sensitivity are grouped and configured such that
orthogonally related components of the magnetic fields are sampled differentially.
The differential signal Y1-Y2 will give a sine vector of the magnetic field. The differential signal X1-X2 will give an
orthogonally related cosine vector of the magnetic field.
www.austriamicrosystems.com
Revision 2.10
24 - 33
AS5040
Data Sheet
The angular displacement (Θ) of the magnetic source with reference to the Hall sensor array may then be modelled
by:
Θ = arctan
(Y 1 − Y 2) ± 0.5°
( X 1 − X 2)
The ±0.5° angular error assumes a magnet optimally aligned over the center of the die and is a result of gain
mismatch errors of the AS5040. Placement tolerances of the die within the package are ±0.235mm in X and Y
direction, using a reference point of the edge of pin #1 (Figure 23).
In order to neglect the influence of external disturbing magnetic fields, a robust differential sampling and ratiometric
calculation algorithm has been implemented. The differential sampling of the sine and cosine vectors removes any
common mode error due to DC components introduced by the magnetic source itself or external disturbing magnetic
fields. A ratiometric division of the sine and cosine vectors removes the need for an accurate absolute magnitude of
the magnetic field and thus accurate Z-axis alignment of the magnetic source.
The recommended differential input range of the magnetic field strength (B(X1-X2),B(Y1-Y2)) is ±75mT at the surface of
the die. In addition to this range, an additional offset of ±5mT, caused by unwanted external stray fields is allowed.
The chip will continue to operate, but with degraded output linearity, if the signal field strength is outside the
recommended range. Too strong magnetic fields will introduce errors due to saturation effects in the internal
preamplifiers. Too weak magnetic fields will introduce errors due to noise becoming more dominant.
17 Failure Diagnostics
The AS5040 also offers several diagnostic and failure detection features:
Magnetic Field Strength Diagnosis
By software: the MagINCn and MagDECn status bits will both be high when the magnetic field is out of range.
By hardware: Pins #1 (MagINCn) and #2 (MagDECn) are open-drain outputs and will both be turned on (= low with
external pull-up resistor) when the magnetic field is out of range. If only one of the outputs is low, the magnet is either
moving towards the chip (MagINCn) or away from the chip (MagDECn).
Power Supply Failure Detection
By software: If the power supply to the AS5040 is interrupted, the digital data read by the SSI will be all “0”s. Data is
only valid, when bit OCF is high, hence a data stream with all “0”s is invalid. To ensure adequate low levels in the
failure case, a pull-down resistor (~10kΩ) should be added between pin DO and VSS at the receiving side.
By hardware: The MagINCn and MagDECn pins are open drain outputs and require external pull-up resistors. In
normal operation, these pins are high ohmic and the outputs are high (see Table 3). In a failure case, either when the
magnetic field is out of range or the power supply is missing, these outputs will become low. To ensure adequate low
levels in case of a broken power supply to the AS5040, the pull-up resistors (>10kΩ) from each pin must be
connected to the positive supply at pin 16 (VDD5V).
By hardware: PWM output: The PWM output is a constant stream of pulses with 1kHz repetition frequency. In case of
power loss, these pulses are missing.
By hardware: Incremental outputs: In normal operation, pins A(#3), B(#4) and Index (#6) will never be high at the
same time, as Index is only high when A=B=low. However, after a power-on-reset, if VDD is powered up or restarts
after a power supply interruption, all three outputs will remain in high state until pin CSn is pulled low. If CSn is
already tied to VSS during power-up, the incremental outputs will all be high until the internal offset compensation is
finished (within tPwrUp).
www.austriamicrosystems.com
Revision 2.10
25 - 33
AS5040
Data Sheet
18 Angular Output Tolerances
Accuracy
Accuracy is defined as the error between measured angle and actual angle. It is influenced by several factors:
ƒ
the non-linearity of the analog-digital converters,
ƒ
internal gain and mismatch errors,
ƒ
non-linearity due to misalignment of the magnet
As a sum of all these errors, the accuracy with centered magnet = (Errmax – Errmin)/2 is specified as better than ±0.5
degrees @ 25°C (see Figure 25).
Misalignment of the magnet further reduces the accuracy. Figure 24 shows an example of a 3D-graph displaying nonlinearity over XY-misalignment. The center of the square XY-area corresponds to a centered magnet (see dot in the
center of the graph). The X- and Y- axis extends to a misalignment of ±1mm in both directions. The total misalignment
area of the graph covers a square of 2x2 mm (79x79mil) with a step size of 100µm.
For each misalignment step, the measurement as shown in Figure 25 is repeated and the accuracy
(Errmax – Errmin)/2 (e.g. 0.25° in Figure 25) is entered as the Z-axis in the 3D-graph.
Figure 24: Example of Linearity Error over XY Misalignment
Linearity Error over XY-misalignment [°]
6
5
4
°
1000
3
800
600
2
400
200
1
0
-200
x
-600
-800
-1000
-1000
-400
0
-800
-600
y
-200
200
600
-400
400
1000
800
0
The maximum non-linearity error on this example is better than ±1 degree (inner circle) over a misalignment radius of
~0.7mm. For volume production, the placement tolerance of the IC within the package (±0.235mm) must also be
taken into account.
The total nonlinearity error over process tolerances, temperature and a misalignment circle radius of 0.25mm is
specified better than ±1.4 degrees.
The magnet used for this measurement was a cylindrical NdFeB (Bomatec® BMN-35H) magnet with 6mm diameter
and 2.5mm in height.
www.austriamicrosystems.com
Revision 2.10
26 - 33
AS5040
Data Sheet
Figure 25: Example of Linearity Error over 360°
linearity error with centered magnet [degrees]
0.5
0.4
0.3
0.2
transition noise
0.1
Errmax
0
-0.1
-0.2
1
55
109 163 217 271 325 379 433 487 541 595 649 703 757 811 865 919 973
Errmi
-0.3
-0.4
-0.5
Transition Noise
Transition noise is defined as the jitter in the transition between two steps.
Due to the nature of the measurement principle (Hall sensors + Preamplifier + ADC), there is always a certain degree
of noise involved.
This transition noise voltage results in an angular transition noise at the outputs. It is specified as 0.12 degrees rms (1
sigma)*1.
This is the repeatability of an indicated angle at a given mechanical position.
The transition noise has different implications on the type of output that is used:
ƒ
Absolute output; SSI interface:
The transition noise of the absolute output can be reduced by the user by applying an averaging of readings.
An averaging of 4 readings will reduce the transition noise by 6dB or 50%, e.g. from 0.12°rms to 0.06°rms (1
sigma).
ƒ
PWM interface:
If the PWM interface is used as an analog output by adding a low pass filter, the transition noise can be
reduced by lowering the cutoff frequency of the filter.
If the PWM interface is used as a digital interface with a counter at the receiving side, the transition noise
may again be reduced by averaging of readings.
ƒ
Incremental mode:
In incremental mode, the transition noise influences the period, width and phase shift of the output signals A,
B and Index. However, the algorithm used to generate the incremental outputs guarantees no missing or
additional pulses even at high speeds (up to 30,000 rpm and higher)
*1
: statistically, 1 sigma represents 68.27% of readings,
3 sigma represents 99.73% of readings.
www.austriamicrosystems.com
Revision 2.10
27 - 33
AS5040
Data Sheet
High Speed Operation
Sampling Rate
The AS5040 samples the angular value at a rate of 10.42k samples per second. Consequently, the incremental, as
well as the absolute outputs are updated each 96µs. At a stationary position of the magnet, this sampling rate creates
no additional error.
Absolute Mode with Serial Communication:
With the given sampling rate of 10.4 kHz, the number of samples (n) per turn for a magnet rotating at high speed can
be calculated by:
n=
60
rpm ⋅ 96 μs
In practice, there is no upper speed limit. The only restriction is that there will be fewer samples per revolution as the
speed increases.
Regardless of the rotational speed, the absolute angular value is always sampled at the highest resolution of 10 bit.
Likewise, for a given number of samples per revolution (n), the maximum speed can be calculated by:
rpm =
60
n ⋅ 96 μs
In absolute mode with serial communication, 610 rpm is the maximum speed, where 1024 readings per revolution can
be obtained.
In incremental mode, the maximum error caused by the sampling rate of the ADCs is 0/+96µs. It has a peak of 1LSB
= 0.35° at 610 rpm. At higher speeds this error is reduced again due to interpolation and the output delay remains at
192µs as the DSP requires two sampling periods (2x96µs) to synthesize and redistribute any missing pulses.
Absolute Mode with PWM:
The principle is the same as with the serial communication. The PWM output is refreshed with a rate of 1.025ms, the
number of samples (n) per turn for a magnet rotating at high speed can be calculated by:
n=
60
rpm ⋅1.025ms
In absolute mode with PWM output, 57 rpm is the maximum speed, where 1024 readings per revolution can be
obtained.
Incremental Mode:
Incremental encoders are usually required to produce no missing pulses up to several thousand rpm’s.
Therefore, the AS5040 has a built-in interpolator, which ensures that there are no missing pulses at the incremental
outputs for rotational speeds of up to 30,000 rpm, even at the highest resolution of 10 bits (512 pulses per revolution).
Table 7: Speed Performance
Absolute Output Mode
610rpm = 1024 samples / turn
1220rpm = 512 samples / turn
2441rpm = 256 samples / turn
etc…
Incremental Output Mode
no missing pulses
@ 10 bit resolution (512ppr):
max. speed = 30,000 rpm
Propagation Delays
The propagation delay is the delay between the time that a sample is taken until it is converted and available as
angular data. This delay is 48µs for the absolute interface and 192µs for the incremental interface.
Using the SSI interface for absolute data transmission, an additional delay must be considered, caused by the
asynchronous sampling (t= 0…1/fs) and the time it takes the external control unit to read and process the data.
www.austriamicrosystems.com
Revision 2.10
28 - 33
AS5040
Data Sheet
Angular Error Caused by Propagation Delay
A rotating magnet will therefore cause an angular error caused by the output delay. This error increases linearly with
speed:
esampling = rpm ∗ 6 * prop.delay
where: e sampling
rpm
prop.delay
= angular error [°]
= rotating speed [rpm]
= propagation delay [seconds]
Note: since the propagation delay is known, it can be automatically compensated by the control unit that is processing
the data from the AS5040, thus reducing the angular error caused by speed.
Internal Timing Tolerance
The AS5040 does not require an external ceramic resonator or quartz. All internal clock timings for the AS5040 are
generated by an on-chip RC oscillator. This oscillator is factory trimmed to ±5% accuracy at room temperature (±10%
over full temperature range). This tolerance influences the ADC sampling rate and the pulse width of the PWM output:
ƒ
Absolute output; SSI interface:
A new angular value is updated every 100µs (typ.)
ƒ
Incremental outputs:
the incremental outputs are updated every
100µs (typ.)
ƒ
PWM output:
A new angular value is updated every 100µs (typ.).
The PWM pulse timings Ton and Toff also have the same tolerance as the internal oscillator.
If only the PWM pulse width Ton is used to measure the angle, the resulting value also has this timing
tolerance.
However, this tolerance can be cancelled by measuring both Ton and Toff and calculating the angle from the
duty cycle (see section 9):
Position =
t on ⋅1025
(ton + toff ) − 1
Temperature
Magnetic Temperature Coefficient
One of the major benefits of the AS5040 compared to linear Hall sensors is that it is much less sensitive to
temperature. While linear Hall sensors require a compensation of the magnet’s temperature coefficient, the AS5040
automatically compensates for the varying magnetic field strength over temperature. The magnet’s temperature drift
does not need to be considered, as the AS5040 operates with magnetic field strengths from ±45…±75mT.
Example:
A NdFeB magnet has a field strength of 75mT @ –40°C and a temperature coefficient of -0.12% per Kelvin.
The temperature change is from –40° to +125° = 165K.
The magnetic field change is: 165 x -0.12% = -19.8%, which corresponds to 75mT at –40°C and 60mT at 125°C.
The AS5040 can compensate for this temperature related field strength change automatically, no user adjustment is
required.
Accuracy over Temperature
The influence of temperature in the absolute accuracy is very low. While the accuracy is ≤ ±0.5° at room temperature,
it may increase to ≤±0.9° due to increasing noise at high temperatures.
www.austriamicrosystems.com
Revision 2.10
29 - 33
AS5040
Data Sheet
Timing Tolerance over Temperature
The internal RC oscillator is factory trimmed to ±5%. Over temperature, this tolerance may increase to ±10%.
Generally, the timing tolerance has no influence in the accuracy or resolution of the system, as it is used mainly for
internal clock generation.
The only concern to the user is the width of the PWM output pulse, which relates directly to the timing tolerance of the
internal oscillator. This influence however can be cancelled by measuring the complete PWM duty cycle (see Internal
Timing Tolerance).
www.austriamicrosystems.com
Revision 2.10
30 - 33
AS5040
Data Sheet
19 Package Drawings and Markings
Figure 26: 16-Lead Shrink Small Outline Package SSOP-16
AYWWIZZ
AS5040
Dimensions
Marking: AYWWIZZ
mm
inch
Symbol
Min
Typ
Max
Min
Typ
Max
A
1.73
1.86
1.99
.068
.073
.078
A1
0.05
0.13
0.21
.002
.005
.008
A2
1.68
1.73
1.78
.066
.068
.070
b
0.25
0.315
0.38
.010
.012
.015
c
0.09
-
0.20
.004
-
.008
D
6.07
6.20
6.33
.239
.244
.249
E
7.65
7.8
7.9
.301
.307
.311
E1
5.2
5.3
5.38
.205
.209
.212
e
.0256
0.65
K
0°
-
8°
0°
-
8°
L
0.63
0.75
0.95
.025
.030
.037
www.austriamicrosystems.com
Revision 2.10
A: Pb-free Identifier
Y: Last Digit of Manufacturing Year
WW: Manufacturing Week
I: Plant Identifier
ZZ: Traceability Code
JEDEC Package Outline Standard:
MO - 150 AC
Thermal Resistance Rth(j-a):
typ. 151 K/W in still air, soldered on PCB
IC's marked with a white dot or the letters
"ES" denote Engineering Samples
31 - 33
AS5040
Data Sheet
20 Packing Options
Delivery:
Tape and Reel (1 reel = 2000 devices)
Tubes (1 box = 100 tubes à 77 devices)
Order # AS5040ASSU
Order # AS5040ASST
for delivery in tubes
for delivery in tape and reel
21 Recommended PCB Footprint
Recommended Footprint Data
A
B
C
D
E
www.austriamicrosystems.com
mm
9.02
6.16
0.46
0.65
5.01
Revision 2.10
inch
0.355
0.242
0.018
0.025
0.197
32 - 33
AS5040
Data Sheet
22 Copyrights
Copyright © 1997-2009, austriamicrosystems AG, Schloss Premstaetten, 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.
All products and companies mentioned are trademarks or registered trademarks of their respective companies.
23 Disclaimer
Devices sold by austriamicrosystems AG are covered by the warranty and patent indemnification provisions appearing
in its Term of Sale. austriamicrosystems AG makes no warranty, express, statutory, implied, or by description
regarding the information set forth herein or regarding the freedom of the described devices from patent infringement.
austriamicrosystems 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 austriamicrosystems AG for
current information. This product is intended for use in normal commercial applications. Applications requiring
extended temperature range, unusual environmental requirements, or high reliability applications, such as military,
medical life-support or lifesustaining equipment are specifically not recommended without additional processing by
austriamicrosystems AG for each application.
The information furnished here by austriamicrosystems AG is believed to be correct and accurate. However,
austriamicrosystems 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
austriamicrosystems AG rendering of technical or other services.
Contact Information
Headquarters
austriamicrosystems AG
A-8141 Schloss Premstaetten, Austria
Tel: +43 (0) 3136 500 0
Fax: +43 (0) 3136 525 01
For Sales Offices, Distributors and Representatives, please visit:
http://www.austriamicrosystems.com/contact
www.austriamicrosystems.com
Revision 2.10
33 - 33