Honeywell HMC1021S-TR 1- and 2-axis magnetic sensor Datasheet

1- and 2-Axis Magnetic Sensors
HMC1001/1002/1021/1022
The
Honeywell
HMC100x
and
HMC102x
magnetic sensors are one and two-axis surface
mount sensors designed for low field magnetic
sensing. By adding supporting signal processing,
cost effective magnetometers or compassing
solutions are enabled. Th ese small, low cost
solutions are easy to assemble for high volume
OEM designs. Applications for the HMC100x and
HMC102x
sensors
include
Compassing,
Navigation Systems, Magnetometry, and Current
Sensing.
The HMC100x and HMC102x sensors utilize Honeywell’s Anisotropic Magnetoresistive (AMR) technology that provides
advantages over coil based magnetic sensors. They are extremely sensitive, low field, solid-state magnetic sensors
designed to measure direction and magnitude of Earth’s magnetic fields, from tens of micro-gauss to 6 gauss.
Honeywell’s Magnetic Sensors are among the most sensitive and reliable low-field sensors in the industry.
Honeywell continues to maintain product excellence and performance by introducing innovative solid-state magnetic
sensor solutions. These are highly reliable, top performance products that are delivered when promised. Honeywell’s
magnetic sensor solutions provide real solutions you can count on.
FEATURES
BENEFITS
4
Surface Mount 1 and 2-Axis Sensors
4 Easy to Assemble & Compatible with High Speed SMT Assembly
4
Low Cost
4 Designed for High Volume, Cost Effective OEM Designs
4
4-Element Wheatstone Bridges
4 Low Noise Passive Element Design
4
Low Voltage Operations (2.0V)
4 Compatible for Battery Powered Applications
4
Available in Tape & Reel Packaging
4 High Volume OEM Assembly
4
Patented Offset and Set/Reset Straps
4 Stray Magnetic Field Compensation
4
Wide Field Range (up to +/-6 Oe)
4 Sensor Can Be Used in Strong Magnetic Field Environments
HMC1001/1002/1021/1022
HMC1001/1002 SPECIFICATIONS
Characteristics
Conditions*
Min
Typ
Max
Units
Vbridge (Vb) referenced to GND
-
5.0
12
Volts
Bridge current = 10mA
per bridge
600
850
1200
ohms
Ambient
-55
150
°C
Ambient, unbiased
-55
175
°C
Full scale (FS) – total applied field
-2
+2
gauss
Bridge Elements
Supply
Resistance
Operating Temperature
Storage Temperature
Field Range
Linearity Error
Best fit straight line
± 1 gauss
± 2 gauss
0.1
1.0
0.5
2.0
%FS
Hysteresis Error
3 sweeps across ±2 gauss
0.05
0.10
%FS
Repeatability Error
3 sweeps across ±2 gauss
0.05
0.10
%FS
100
µV
S/R Repeatability
Output variation after alternate S/R pulses
Vb = 5V, ISR = 3A
Bridge Offset
Sensitivity
Noise Density
Offset = (OUT+) – (OUT-)
Field = 0 gauss after Set pulse, Vb = 8V
-60
-15
+30
mV
Set/Reset Current = 3A
2.5
3.2
4.0
mV/V/gauss
@ 1Hz, Vb=5V
29
nV/sqrt Hz
Resolution
10Hz Bandwidth, Vb=5V
27
µgauss
Bandwidth
Magnetic signal (lower limit = DC)
5
MHz
Disturbing Field
Sensitivity Tempco
Sensitivity starts to degrade.
Use S/R pulse to restore sensitivity.
5
TA= -40 to 125°C, Vb=8V
TA= -40 to 125°C, Ibridge=5mA
-0.32
gauss
-0.30
-0.06
-0.28
%/°C
Bridge Offset Tempco
TA= -40 to 125°C, No Set/Reset
TA= -40 to 125°C, With Set/Reset
±0.03
±0.001
%/°C
Bridge Ohmic Tempco
TA= -40 to 125°C
0.25
%/°C
Cross field = 1 gauss, Happlied = ±1 gauss
±3
%FS
With set/reset
±0.5
Cross-Axis Effect
Max. Exposed Field
No perming effect on zero reading
10000
gauss
1.5
1.8
ohms
3.0
5
Amp
Set/Reset Straps
Resistance
Current
Resistance Tempco
Measured from S/R+ to S/R0.1% duty cycle, or less, 2µsec current pulse
2.0
TA= -40 to 125°C
0.37
%/°C
Measured from OFF+ to OFF-
2.5
3.5
ohms
51
56
mA/gauss
Offset Straps
Resistance
Offset Constant
DC Current
Field applied in sensitive direction
Resistance Tempco
TA= -40 to 125°C
* Tested at 25°C except stated otherwise.
2
46
0.39
%/°C
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HMC1001/1002/1021/1022
HMC1021/1022 SPECIFICATIONS
Characteristics
Conditions*
Min
Typ
Max
Units
Vbridge (Vb) referenced to GND
2
5.0
25
Volts
Bridge current = 10mA
per bridge
800
1100
1300
ohms
Ambient
-55
150
°C
Ambient, unbiased
-55
175
°C
Full scale (FS) – total applied field
-6
+6
gauss
Bridge Elements
Supply
Resistance
Operating Temperature
Storage Temperature
Field Range
Linearity Error
Best fit straight line
± 1 gauss
± 3 gauss
± 6 gauss
0.05
0.4
1.6
%FS
Hysteresis Error
3 sweeps across ±2 gauss
0.08
%FS
Repeatability Error
3 sweeps across ±2 gauss
0.08
%FS
Bridge Offset
Sensitivity
Noise Density
Offset = (OUT+) – (OUT-)
Field = 0 gauss after Set pulse, Vb = 5V
-10
±2.5
+11.25
mV
Set/Reset Current = 0.5A
0.8
1.0
1.25
mV/V/gauss
@ 1Hz, Vb=5V
48
nV/sqrt Hz
Resolution
10Hz Bandwidth, Vb=5V
85
µgauss
Bandwidth
Magnetic signal (lower limit = DC)
5
MHz
Disturbing Field
Sensitivity Tempco
Sensitivity starts to degrade.
Use S/R pulse to restore sensitivity.
20
TA= -40 to 125°C, Vb=5V
TA= -40 to 125°C, Ibridge=5mA
-0.32
gauss
-0.30
-0.06
-0.28
%/°C
Bridge Offset Tempco
TA= -40 to 125°C, No Set/Reset
TA= -40 to 125°C, With Set/Reset
±0.05
±0.001
%/°C
Bridge Ohmic Tempco
TA= -40 to 125°C
0.25
%/°C
Cross field = 1 gauss, Happlied = ±1 gauss
+0.3
%FS
Cross-Axis Effect
Max. Exposed Field
No perming effect on zero reading
10000
gauss
Set/Reset Straps
Resistance
Current
Resistance Tempco
Measured from S/R+ to S/R-
5.5
7.7
9
ohms
0.1% duty cycle, or less, 2µsec current pulse
0.5
0.5
4.0
Amp
TA= -40 to 125°C
0.37
%/°C
Offset Straps
Resistance
Offset Constant
Measured from OFF+ to OFF-
38
50
60
ohms
DC Current
Field applied in sensitive direction
4.0
4.6
6.0
mA/gauss
Resistance Tempco
TA= -40 to 125°C
* Tested at 25°C except stated otherwise.
www.honeywell.com
0.39
%/°C
3
HMC1001/1002/1021/1022
KEY PERFORMANCE DATA
4
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HMC1001/1002/1021/1022
PACKAGE / PINOUT SPECIFICATIONS
Arrow indicates direction of applied field that generates a positive output voltage after a SET pulse.
BASIC DEVICE OPERATION
The Honeywell HMC100x and HMC102x Anisotropic Magneto-Resistive (AMR) sensors are simple resistive Wheatstone
bridges to measure magnetic fields and only require a supply voltage for the measurement. With power supply applied to
the bridges, the sensors convert any incident magnetic field in the sensitive axis directions to a differential voltage outputs.
In addition to the bridge circuits, each sensor has two on-chip magnetically coupled straps; the offset strap and the
set/reset strap. These straps are Honeywell patented features for incident field adjustment and magnetic domain
alignment; and eliminate the need for external coils positioned around the sensors.
The magnetoresistive sensors are made of a nickel-iron (Permalloy) thin-film deposited on a silicon wafer and patterned
as a resistive strip element. In the presence of a magnetic field, a change in the bridge resistive elements causes a
corresponding change in voltage across the bridge outputs.
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HMC1001/1002/1021/1022
These resistive elements are aligned together to have a common sensitive axis (indicated by arrows on the pinouts) that
will provide positive voltage change with magnetic fields increasing in the sensitive direction. Because the output only is in
proportion to the one-dimensional axis (the principle of anisotropy) and its magnitude, additional sensor bridges placed at
orthogonal directions permit accurate measurement of arbitrary field direction. The combination of sensor bridges in two
and three orthogonal axis permit applications such as compassing and magnetometry. See Figure 1 for a representation
of the magneto-resistive elements.
Permalloy Thin Film
Out-
Vb
Gnd
Easy Axis
Out+
Sensitive
Axis
Figure 1 – Magneto-Resistive Wheatstone Bridge Elements
The offset strap allows for several modes of operation when a direct current is driven through it. These modes are: 1)
Subtraction (bucking) of an unwanted external magnetic field, 2) null-ing of the bridge offset voltage, 3) Closed loop field
cancellation, and 4) Auto-calibration of bridge gain.
The set/reset strap can be pulsed with high currents for the following benefits: 1) Enable the sensor to perform high
sensitivity measurements, 2) Flip the polarity of the bridge output voltage, and 3) Periodically used to improve linearity,
lower cross-axis effects, and temperature effects.
Offset Straps
The offset strap is a spiral of metallization that couples to the sensor element’s sensitive axis. The offset strap has some
modest resistance and requires a moderate current flow for each gauss of induced field. The straps will easily handle
currents to buck or boost fields through the linear measurement range, but designers should note the extreme thermal
heating on the die when doing so.
With most applications, the offset strap is not utilized and can be ignored. Designers can leave one or both strap
connections (Off- and Off+) open circuited.
Set/Reset Straps
The set/reset strap is another spiral of metallization that couples to the sensor element’s easy axis (perpendicular to the
sensitive axis on the sensor die). Each set/reset strap has a low resistance with a short but high required peak current for
reset or set pulses. With rare exception, the set/reset strap must be used to periodically condition the magnetic domains
of the magneto-resistive elements for best and reliable performance. A set pulse is defined as a positive pulse current
entering the S/R+ strap connection. The successful result would be the sensor aligned in a forward easy-axis direction so
that the sensor bridge’s polarity is a positive slope with positive fields on the sensitive axis result in positive voltages
across the bridge output connections.
A reset pulse is defined as a negative pulse current entering the S/R+ strap connection. The successful result would be
the sens or aligned in a reverse easy-axis direction so that sensor bridge’s polarity is a negative slope with positive fields
on the sensitive axis result in negative voltages across the bridge output connections.
Typically a reset pulse is sent first, followed by a set pulse a few milliseconds later. By shoving the magnetic domains in
completely opposite directions, any prior magnetic disturbances are likely to be completely erased by the duet of pulses.
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HMC1001/1002/1021/1022
For simpler circuits with less critical requirements for noise and accuracy, a single polarity pulse circuit may be employed
periodically (all sets or all resets). With these uni-polar pulses, several uni-polar pulses become close in performance to a
single bipolar set/reset pulse circuit.
NOISE CHARACTERISTICS
The noise density curve for a typical AMR sensor is shown in the figure below. The 1/f slope has a nominal corner
frequency near 10Hz and flattens out to a 3.8 nV/sqrtHz slope. This is approximately equivalent to the Johnson noise (or
white noise) for an 850 ohm resistor, the typical bridge resistance. To relate the noise density voltage to the magnetic
fields, use the following expressions:
For Vbridge = 5V and Sensitivity = 3.2mV/V/gauss, the bridge output (Voutput) is 16mV/gauss
The noise density at 1Hz is about 30nV/sqrtHz or 1.8 micro-gauss/sqrtHz
1/f noise (0.1 to 10Hz) = 30 * sqrt[(ln10/0.1)] nV = 64nV (rms) = 4 micro-gauss (rms) = 27 micro-gauss (pk-pk)
White noise (BW = 1kHz) = 3.8 * sqrt[BW] nV = 120nV (rms) = 50 micro-gauss (pk-pk)
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HMC1001/1002/1021/1022
SET/RESET STRAP OPERATION
The reasons to perform a set or reset on an AMR sensor are: 1) To recover from a strong external magnetic field that
likely has re-magnetized the sensor, 2) to optimize the magnetic domains for most sensitive performance, and 3) to flip
the domains for extraction of bridge offset under changing temperature conditions.
Strong external magnetic fields that exceed a 10 to 20 gauss “disturbing field” limit, can come from a variety of sources.
The most common types of strong field sources come from permanent magnets such as speaker magnets, nearby highcurrent conductors such as welding cables and power feeder cables, and by magnetic coils in electronic equipment such
as CRT monitors and power transformers. Magnets exhibit pole face strengths in hundreds to thousands of gauss. These
high intensity magnetic field sources do not permanently damage the sensor elements, but the elements will be disturbed
to the exposed fields rather than the required easy axis directions. The result of this re-magnetization of the sensor
elements, the sensor will lack sensitivity or indicate a “stuck” sensor output. Using the set and reset pulses will
magnetically “restore” the sensor.
AMR sensors are also ferromagnetic devices with a crystalline structure. This same thin film structure that makes the
sensor sensitive to external magnetic fields also has the downside that changing magnetic field directions and thermal
energy over time will increase the self-noise of the sensor elements. This noise, while very small, does impair the
accurate measurement of sub-milligauss field strengths or changes in field strength in microgauss increments. By
employing frequent set and reset fields on the sensor, the self-noise will be to its lowest possible level.
As the sensor element temperature changes, either due to self-heating or external environments, each element’s
resistance will change in proportion to the temperature. One way to eliminate the bridge offset voltage is to make stable
magnetic field measurements of the bridge output voltage in between each set and reset field application. Since the
external field components of the bridge output voltage will flip polarity, the set and reset bridge output voltages can be
subtracted and the result divided by two to calculate the bridge offset. See application note AN212 for the details on
bridge offset voltage computation and correction.
SET/RESET DRIVE CIRCUITS
The above description explained that providing pulses of electrical current creates the needed magnetic fields to realign
the magnetic domains of the sensor resistive elements. Also the rationale for performing these set and reset pulses has
been justified. The following paragraphs shall show when and how to apply these pulsed currents, and circuits to
implement them. Figure 2 shows a simplistic schematic of a set/reset circuit.
These set and reset pulses are shown in Figure 2 as dampened exponential pulse waveforms because the most popular
method of generating these relatively high current, short duration pulses is via a capacitive “charge and dump” type of
circuit. Most electronics, especially in consumer battery powered devices, do not have the capability to supply these high
current pulses from their existing power supply sources. Thus “Vsr” is actually a charged up capacitor that is suddenly
switched across the set/reset strap. The value of this capacitor is usually a couple hundred nano-Farads (ηF) to a few
micro-Farads (µF) depending on the strap resistance to be driven. The decay of the exponential waveform will mostly be
governed by a time constant (τ or Tau) that is the capacitance in farads multiplied by the resistance, and is measured in
seconds.
τ = R*C = ~2µsec
Iset
Ireset
1
S/R+
Rsr
Strap
5 Resistance
Vsr
Set/Reset
Pulse Source
S/R-
Figure 2 – A Simple Set/Reset Circuit
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HMC1001/1002/1021/1022
The next circuit implementation is the classic set/reset design in which a push-pull output stage (totem pole stage) drives
one end of the HMC1001 set/reset strap, with the other end grounded. Figure 3 shows this circuit.
R1
200
R2
22K
VDD
8 Volts
C1
10U
X1
IRF7105P
C4
0.1U
Rsource
10
Vsource
C2
0.47U
Vsr
C3
0.47U
X2
IRF7105N
Rsr
1.5
Figure 3 – Totem Pole Set/Reset Circuit for HMC1001
The totem pole moniker comes from the stacked semiconductors between the positive supply voltage (VDD) and the
negative connection (Ground). In the above example circuit, the semiconductors depicted are two complementary power
MOSFETs, with the P-channel device on top and the N-channel device on the bottom. The International Rectifier IRF7105
part is chosen in this circuit as it contains both P-channel and N-channel MOSFET die in a very small package, and has
the electrical characteristics needed for this circuit. Other manufacturers can be used as well with the requirements that
they can be fully turned on/off with a 5-volt logic stimulus, handle the peak set/reset strap load currents, and present an
“on” resistance at those peak currents that is fairly small in comparison to the connected strap load resistance.
HIGHER VOLTAGE TOTEM POLE CIRCUITS
While the previous example uses the convenience of standard 5-volt logic drive and modest supplies, many sensor
designs require higher applied voltages to the set/reset straps to achieve greater currents or because the straps are
series connected to assure even current distribution across all the straps pulsed. By creating series chains of straps,
variances in strap resistance are less likely to fall out of the minimum or maximum range for peak pulse currents. If the
straps are parallel connected, wide set/reset strap ohmic tolerances may be prone to “current hogging” and the straps will
provide dissimilar magnetic fields at each sensor, potentially creating non-uniform accuracies at each sensor axis.
The circuit in Figure 3 relies on MOSFETs that could predictably be turned off and on completely using logic level inputs.
At higher voltages, the P-channel device needs its gate drive voltage to approach the source voltage, which is higher than
usual logic levels. To perform this level shifting from logic levels to higher pulse source voltage supply levels, a BJT level
shifter sub-circuit is employed to perform this task. Figure 4 shows this higher voltage operating circuit.
From Figure 4, Rsr1, Rsr2, and Rsr3 are three strap resistances that are modeled from the HMC1001 or HMC1002
products. Three of these strap resistances are chosen since many users desire 3-axis magnetic field sensing that comes
from a pairing of a HMC1001 and a HMC1002. Also this combination of three series straps is also used on the HMC2003
hybrid sensor module and in the HMR2300 Smart Digital Magnetometer.
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HMC1001/1002/1021/1022
R5
220
10
C2
10U
R1
1000
3
Q1
2N2222
1
Q2
2N2907
6
Vset
5
Rsr1
1.8
9
Rsr2
1.8
11
12
Rsr3
1.8
Q3
2N2222
8
D1
1N4148
X1
IRF7105P
4
R3
1000
7
2
C1
0.22U
R2
1000
C3
1N
Vdd
X2
IRF7105N
Vreset
Figure 4 – Higher Voltage Set/Reset Circuit for HMC1001 & HMC1002
The three strap resistances are chosen at 1.8 ohms, or the worst-case high resistance points. Since they require a
minimum of 3 amperes peak, the series combination requires at least 16.2 volts, so a circuit Vdd of about 18 volts would
about the right level to drive the strap load and allocate for losses in the C1 capacitor ESR and the MOSFET switches X1
and X2. C1’s value is also chosen at 0.22 micro-farad so the circuit time constant is at least around 1 micro-second.
Supply reservoir capacitor C2 is chosen to many times the value of C1 and is also picked for small size, working voltage,
and low ESR relative to the strap load resistance. C2 typically will be in the 1 to 10 micro-farad range and best to error on
the high capacitance side since C2 now supplies additional X1 gate drive circuitry. Resistor R5 is then chosen after C2 to
set the recharge time constant and to limit peak supply current. These capacitors should be chosen to have a low ESR
characteristic of around 0.2 ohms per capacitor.
Working backwards from the strap load resistance, MOSFETs X1 and X2 are chosen as IRF7105 due to the total
packaged size (both X1 and X2 in one SOIC-8), and meeting the requirements for operating voltages, peak currents, and
low on resistances. X2 is directly driven from digital logic denoted as “Vset”, and “Vreset” drives the level shifting subcircuit to X1. Note that Vreset turns off X2 first prior to X1 being driven on by Vset, and also X1 is turned off before X2 is
turned on. While one logic line could control the operation of Vset and Vreset, the additional inverter stages and pulse
delay components may be too space and cost consuming compared to two logic ports in a microcontroller. See Figure 4
in Application Note 201 for the discrete Vset and Vreset pulse forming circuit.
Transistors Q1 and Q2 in Figure 4 are chosen to be generic BJTs to force MOSFET X1’s gate charge quickly into on and
off states. Resistors R1 and R2 are selected as nominal 1000 ohm values that can pump or dump X1’s gate charge by
supplying Q1 and Q2 with enough base drive currents to flip their on and off states. Transistor Q3 is also chosen as a
generic, but reasonably fast switch transistor to perform the level shift function with resistors R1 and R2. Components R3,
C3 and D1 are chosen to properly drive Q3 from a logic level source, with C3 and D1 denoted as a “speed-up” network to
quickly switch Q3 within a few nanoseconds of logic transitions.
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HMC1001/1002/1021/1022
APPLICATION CIRCUITS
The following are typical application circuits using the HMC100x and HMC102x sensors.
TWO AXIS COMPASS OR MAGNETOMETER
Figure 5 shows the typical schematic diagram.
C1
1N
VDD
R1
850
1
R7
360K
R2
850
VDD
R5
4.99K
2
3
X1A
LMV324N
VCC
R6
4.99K
XOUT
6
VDD
VEE
4
R3
850
R8
360K
R4
850
VDD
R19
1K
VREF
HMC1002
R9
850
8
R10
850
9
VCC
C2
1N
VDD
C3
0.1U
X1C
LMV324N
VEE
VREF
15
R20
1K
R15
360K
VDD
R13
4.99K
11
VCC
R14
4.99K
X1B
LMV324N
YOUT
12
VEE
10
R11
850
R16
360K
R12
850
C5
0.47U
X2
IRF7105P
16
R18
1.5
R21
100
14
VREF
R17
1.5
C4
10U
VSR
18
17
C6
0.47U
13
SR_IN
X3
IRF7105N
Figure 5 – 2-Axis Compass or Magnetometer
From Figure 5, the typical power supplied for VDD is nominally 5 volts, with about 8 volts for the set/reset strap supply
(VSR). A pair of complementary power MOSFETs provides the electronic switch functions, driving the set/reset minus
pins with the set/reset plus pins returned to the MOSFET ground. The MOSFETs are driven by typical 5 volt logic with
normally high levels expected when not pulsing. Each logic transition creates a very high current pulse, as high-to-low
transitions turn-on the P-channel FET while turning-off the N-channel FET. This transfers some of the energy from the
10uf reservoir capacitor to the pair of 0.47uf capacitors while providing a positive pulse. A negative pulse is performed on
the low-to-high logic transition as the P-channel FET is turned off and the N-channel FET is turned on. Then the energy
from the pair of 0.47uf capacitors is discharged through the set/reset straps and the N-channel MOSFET. Ceramic
capacitors with a low-ESR characteristic are required for best pulse performance.
Since the sensor output difference voltage is amplified by low cost operational amplifiers with a low supply voltage feature
(LMV324N), the amplifier requires a half supply voltage reference (VREF). This reference voltage is formed via a buffered
rail-splitter circuit, using a spare op-amp and resistors. The 1 nano-farad capacitors are used to bandwidth limit the
sensor, and to suppress interference. The resistors around the op-amp are chosen for earth’s magnetic field strength
(about 0.6 gauss) levels and to match with the sensor impedance. The 4.99k-ohm resistors are a bridging impedance that
is normally chosen to be 4 to 10 times larger than the sensor bridge resistance elements (HMC1002) at 850 ohms. The
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HMC1001/1002/1021/1022
360k-ohm feedback and reference resistors are chosen to provide a nominal 230mV/V/gauss gain characteristic or
1.15V/gauss gain with VDD at 5 volts. Other values than 360k-ohms may be chosen; with smaller resistances for larger
fields and larger resistances for lower field strengths. Be aware that sensor bridge offsets factor into the signal gain
selection as the offsets may be as large as the signal to be measured. See application note AN212 on methods to handle
bridge offset voltages.
As a magnetometer, the circuit outputs (Xout and Yout) should be measured against VREF and scaled for 1.15 volts per
gauss using a 5 volt sensor/amplifier power supply (VDD). Since the sensor’s bandwidth is 5 MHz, the sampling rate of
the outputs can be very fast, to the point were the filtering and speed of the amplifiers begins to effect the measurements.
Resolution will be mostly to the size of the Analog-to-Digital Converter (ADC), where a 10-bit ADC would spread its 1024
counts across the power supply or tighter.
As a compass, the two outputs constrain the earth’s magnetic field measurement to horizontal orientations with the Xout
and Yout feeding the heading equation of arctan (Yout/Xout) in degrees. The Xout direction of the HMC1002 should be
mounted to the forward direction of the product for proper orientation. If a tilt-compensated compass is desired, a third
axis could be made from the spare LMV324N amplifier and a HMC1001 sensor. Refer to the technical papers on
compassing from the website for more detail on compass implementation.
Field Detector or Current Sensor
A simple sensor implementation is shown in Figure 6 for a single axis sensor and signal conditioning circuitry for detecting
a magnetic disturbance, or as a current sensor when placed near a current carrying conductor. For more details on
current sensing, see application note AN209 on the website.
From Figure 6, the HMC1021 sensors are different from the HMC100x parts in that the bridge resistances increase to
1100 ohms and the set/reset strap resistance increases to 4.5 ohms. Because the minimum set/reset peak current is
down to 0.5 amperes, the set/reset drive circuit can now be run at common supply rails of 5 or 3 volts (VDD). Due to the
increased resistance of the set/reset strap, capacitor C3 can be reduced to about 0.22uf to maintain the desired 1 to 2
microsecond time constant. Capacitor C2 is typically chosen to be about ten times the series capacitor value, or 2.2uf.
The same pulse transition scheme in Figure 5 applies to Figure 6.
The sensor/amplifier circuit is likewise similar but the 1mV/V/gauss sensitivity requires a gain boost by increasing
feedback/reference resistors for sensing low fields like earth’s magnetic field. If a 2 or 3-axis compass is to be designed
with the HMC102x series sensor, parts like the HMC1022 plus the HMC1021Z can be used, with replication of the
difference amplifier stages for each axis. By choosing the 1 Meg-ohm and 4.99k-ohm resistors, the gain with a 5 volt
supply produces about a 1V/gauss transfer characteristic and centered at half supply (2.5 volts).
An instrumentation amplifier could be substituted for the operational amplifier to minimize external discrete components,
but the very low cost of op-amps like the LMV741/LMV358/LMV324 family is hard to beat if price is more important than
printed circuit board footprint. The signal output of the amplifier can be directly placed on the input of an ADC and further
processed in digital form. If the ADC range spans the power supply range, then a 10-bit ADC can have count 512 of 1024
used as the zero gauss point when the output rests at half-supply. If 3 volt operation is required, the designer can
substitute the IRF7507 part for the IRF7105 for 2.7 volt logic drive of the complementary MOSFET gates.
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HMC1001/1002/1021/1022
C1
1N
VDD
R1
1.1K
1
R7
1MEG
R2
1.1K
VDD
R5
4.99K
2
3
X1A
LMV324N
VCC
R6
4.99K
XOUT
6
VEE
4
R3
1.1K
R8
1MEG
R4
1.1K
8
HMC1021
R9
R10 10K
10K
VDD
C2
2.2U
R11
200
VDD
14
C3
0.22U
R12
4.5
X2
IRF7105P
16
18
17
SR_IN
X3
IRF7105N
Figure 6 – Field Detector or Current Sensor
MOUNTING CONSIDERATIONS
Stencil Design and Solder Paste
A 4 mil stencil and 100% paste coverage is recommended for the electrical contact pads.
Pick and Place
Placement is machine dependant and no restrictions are recommended.
Reflow and Rework
No special profile is required for the HMC10xx parts. The product is compatible with lead and no-lead eutectic solder
paste reflow profiles. Honeywell recommends the adherence to solder paste manufacturer’s guidelines. The sensors may
be reworked with soldering irons, but extreme care must be taken not to overheat the part’s circuit board pads. Irons with
a tip temperature no greater than 315°C should be used. Excessive rework risks the copper pads pulling away into the
molten solder.
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13
HMC1001/1002/1021/1022
PACKAGE OUTLINES
14
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HMC1001/1002/1021/1022
ORDERING INFORMATION
Ordering Number
Product
Packaging
HMC1001
One Axis Magnetic Sensor, 8-pin SIP
ESD Tubes
HMC1002
HMC1002-TR
Two Axis Magnetic Sensor, 20-pin SOIC
ESD Tubes
1,000 Tape & Reel
HMC1021S
HMC1021S-TR
One Axis Magnetic Sensor, 8-pin SOIC
ESD Tubes
1,000 Tape & Reel
HMC1021Z
One Axis Magnetic Sensor, 8-pin SIP
ESD Tubes
HMC1022
HMC1022-TR
Two Axis Magnetic Sensor, 16-pin SOIC
Cut Tape
2,500 Tape & Reel
* When ordering the –RC in the product part number represents RoHS compliant. This labeling is temporary during the
transition period from leaded to non-leaded parts.
FIND OUT MORE
For more information on Honeywell’s Magnetic Sensors visit us online at www.magneticsensors.com or contact us at
800-323-8295 (763-954-2474 internationally).
The application circuits herein constitute typical usage and interface of Honeywell product. Honeywell does not warranty or assume liability of customerdesigned circuits derived from this description or depiction.
Honeywell reserves the right to make changes to improve reliability, function or design. Honeywell does not assume any liability arising out of the
application or use of any product or circuit described herein; neither does it convey any license under its patent rights nor the rights of others.
U.S. Patents 4,441,072, 4,533,872, 4,569,742, 4,681,812, 4,847,584 6,529,114 and 7,095,226 apply to the technology described
Honeywell
12001 Highway 55
Plymouth, MN 55441
Tel: 800-323-8295
www.honeywell.com
www.honeywell.com/magneticsensors
Form #900248 Rev C
August 2008
©2008 Honeywell International Inc.
15
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