HONEYWELL HMC6042R1K

2-Axis Magnetic Sensor Circuit
HMC6042
Advanced Information
The Honeywell HMC6042 is a surface mount multi-chip module designed
for low field magnetic sensing such as low cost compassing and
magnetometry. The HMC6042 includes our state of the art 1042 series
magneto-resistive sensors plus a precision mixed signal ASIC containing
three sensor amplifiers and a compatible set/reset strap driver circuit for 2.4
to 3.6 volt operation. The ASIC plus sensors are surface mount packaged in
a 3.6 by 5.0 by 1.0mm LCC that can be used stand alone for very low cost
2-axis compasses, or with the HMC1041Z to complete the magnetic sensor
portion of a 3-axis, tilt compensated compass. Applications for the
HMC6042 include Consumer Electronic Compassing and Magnetometry.
The HMC6042 utilizes Honeywell’s Anisotropic Magnetoresistive (AMR) technology that provides advantages over other
magnetic sensor technologies. The sensors feature precision in-axis sensitivity and linearity, solid-state construction with
very low cross-axis sensitivity designed to measure both 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
2-Axis Magnetoresistive Sensor and
ASIC in a Single Package
Size for Highly Integrated Products. Just Add a Micro4 Small
Controller Interface with ADC, Plus Two External SMT Capacitors
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Low Cost
4 Designed for High Volume, Cost Sensitive OEM Designs
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5 x 3.6 x 1.0mm LCC Surface Mount
Package
4 Easy to Assemble & Compatible with High Speed SMT Assembly
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Low Voltage Operations (2.4 to 3.6V)
4 Compatible for Battery Powered Applications
4
Built-In Set/Reset Drive Circuit
4 Single Logic Input for Degaussing, Thermal Drift Compensation
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Signal Processing Flexibility
4 Feedback Pins for Gain and Bandwidth Shaping
4
Lead Free Package Construction
4 Complies with Current Environmental Standards
4
Wide Magnetic Field Range (+/-6 Oe)
4 Sensors Can Be Used in Strong Magnetic Field Environments
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Available in Tape & Reel Packaging
4 High Volume OEM Assembly
HMC6042
SPECIFICATIONS
Characteristics
Conditions*
Min
Open Loop Gain, After Set/Reset Pulses
175
VDD1 = 3.0 volts
0.75
Full Scale
±1
VDD1, VDD2 Referenced to GND
2.4
Bridge Current = 0.9mA/volt per axis
Continuous (VDD1)
Peak (0.5msec) (VDD1 + VDD2)
Typ
Max
Units
275
mV/V/gauss
2.25
volts
±2
gauss
3.6
Volts
5.2
7.0
25
mA
Full scale (FS) – total applied field
-6
+6
gauss
Sensitivity
After Set/Reset Pulses
0.8
1.25
mV/V/gauss
Resolution
1 kHz bandwidth, VDD1 = 3.0 volts
System
Sensitivity
Zero Field Offset
Magnetic Field Range
1.5
Power Supply
Supply Voltage
Current
3.0
Magnetic sensors
Field Range
Bridge Offset
Cross-Axis Sensitivity
Offset = (OUT+) – (OUT-)
Field = 0 gauss after Set pulse
1.0
0.12
-1.25
Cross field = 0.5 gauss,
Happlied = ±3 gauss
±0.5
milli-gauss (RMS)
+1.25
±0.2%
mV/V
%FS/gauss
Sensitivity starts to degrade.
Use S/R pulse to restore sensitivity.
20
gauss
Max. Exposed Field
No perming effect on zero reading
10000
gauss
Sensitivity Tempco
TA= -40 to 125°C, Vbridge=5V
-2000
ppm/°C
Disturbing Field
Bridge Offset Tempco
Bridge Ohmic Tempco
-3500
-3100
TA= -40 to 125°C, No Set/Reset
±500
TA= -40 to 125°C, With Set/Reset
±10
VDD1 = 3.0V, TA = -40 to 125°C
2100
2500
ppm/°C
2900
ppm/°C
Best fit straight line
± 1 gauss
± 3 gauss
± 6 gauss
0.17
0.42
0.80
%FS
Hysteresis Error
3 sweeps across ±3 gauss
0.15
%FS
Repeatability Error
3 sweeps across ±3 gauss
0.11
%FS
No Feedback Connections
225
V/V
Linearity Error
ASIC
Amplifier Gains
Bandwidth
10
Slew Rate
kHz
0.1
V/µsec
Gain Bainwidth
Av = 250
1.0
MHz
Phase Margin
Av = 250
45
deg
VDD1 = 3.0V
0.15
Source
Sink
3.6
3.6
Reservior Cap C1
Recommended Capacitor Size
2.2
Load Road Range
Includes Internal 1042 S/R Strap
1.5
Output Voltage Range
Output Current
2.85
V
mA
Set/Reset Strap Driver
2
4.4
10
µF
6
ohms
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HMC6042
Characteristics
Conditions*
Min
Max
Units
3
6
ohms
Ambient
-40
125
°C
Ambient, unbiased
-55
125
°C
Internal Strap Resistance
Typ
Other
Operating Temperature
Storage Temperature
Weight
* Tested at 25°C except stated otherwise.
TBD
milli-grams
PIN CONFIGURATIONS
(Arrow indicates direction of applied field that generates a positive output voltage after a SET pulse.)
IN Z-
C1
S/R C
5
6
7
8
9
S/R IN
IN Z+
S/R+
S/R-
HMC6042
10
4
11
FB Z
12
OUT Z
13
FB Y
14
OUT Y
Y
OFFNC
3
X
ASIC
DIE
2
AMR DIE
VDD1
1
19
18
17
16
15
OFF+
NC
VDD2
GND
OUT X
FB X
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20
BOTTOM VIEW
Pin Number
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
Function
VDD1
NC
Offset StrapSet/Reset+
Set/ResetZ sensor In+
Z sensor InC1, reservoir cap
Set/Reset drive out
Set/Reset logic input
Z amp feedback
Z amp output
Y amp feedback
Y amp output
X amp feedback
X amp output
GND, ground return
VDD2
NC
Offset Strap+
3
HMC6042
PACKAGE OUTLINES
PACKAGE DRAWING HMC6042 (20-PIN LPCC, dimensions in millimeters)
Dimensions
Minimum
D
D1
E
E1
A
0.89
e = 0.5 Basic
Nominal
5.00 BSC
2.50 BSC
3.60 BSC
1.50 BSC
1.06
Maximum
1.23
MOUNTING CONSIDERATIONS
The following is the recommend printed circuit board (PCB) footprint for the HMC6042.
PCB Pad Definition
The HMC6042 is a fine pitch LCC package with a 0.50mm pin pitch (spacing), with the pin pads defined as 0.50mm by
0.20mm in size. PCB pads are recommended to be oversized by 0.025mm from each pad for a short dimension oversize
of 0.05mm. The interior PCB pad is recommended to be 0.05mm oversized per pin with an exterior oversize of 0.20mm
for proper package centering and to permit test probing. Lead finish is SnAgCu.
Stencil Design and Solder Paste
A 4 mil stencil and 100% paste coverage is recommended for the electrical contact pads. The HMC6042 has been tested
successfully with no-clean solder paste.
Pick and Place
Placement is machine dependant and no restrictions are recommended, and have been tested with mechanical centering.
Placement force should be equivalent 1206 SMT resistors and enough force should be used to squeeze the paste out
from the package/contact pad overlap and to keep the package pin contacts vertical.
Reflow and Rework
No special profile is required for the HMC6042 and compatible with lead eutectic and lead-free solder paste reflow
profiles. Honeywell recommends the adherence to solder paste manufacturer’s guidelines. The HMC6042 may be
reworked with soldering irons, but extreme care must be taken not to overheat the copper pads from the part’s fiberglass
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HMC6042
substrate. 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.
SCHEMATIC DIAGRAM
HMC6042
VDD1
VDD1
HMC6042
GND
IN X+
AMR
IN X-
OUT X
G
GND
FB X
GND
AN0
CLK
AN1
TXD
SERIAL
I/O
RXD
AN2
DO0
Host µC
IN Y+
OUT Y
AMR
IN Y-
Vdd
G
Vss
FB Y
VDD
GND
GND
IN Z+
OUT Z
G
IN Z-
FB Z
C1
+ 2.2µF
S/R IN
SET/RESET
VDD2
S/R+
S/R C
S/RC2
0.22µF
BASIC DEVICE OPERATION
The Honeywell HMC6042 magnetoresistive sensor circuit is a pair of sensor and analog support circuits to measure
magnetic fields. With power supply applied, the sensor converts any incident magnetic field in the sensitive axis direction
to a differential voltage output. In addition to the bridge circuit, the sensors have 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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HMC6042
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.
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 Strap
The offset strap is a spiral of metallization that couples in the sensor element’s sensitive axis. The offset strap measures
nominally 8 ohms, and requires 10mA for each gauss of induced field. The straps will easily handle currents to buck or
boost fields through the ±6 gauss 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, or ground one connection node. Do not tie both strap connections together to
avoid shorted turn magnetic circuits.
Set/Reset Strap
The set/reset strap is another spiral of metallization that couples to the sensor elements easy axis (perpendicular to the
sensitive axis on the sensor die. Each set/reset strap has a nominal resistance of 5 ohms with a nominal required peak
current of 500mA 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
magnetic domains 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 magnetic domains 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.
For simpler circuits with less critical requirements for noise and accuracy, a single polarity pulse circuit may be employed
(all sets or all resets). With these uni-polar pulses, several pulses together become close in performance to a set/reset
pulse circuit. Figure 1 shows a quick and dirty manual pulse circuit for uni-polar application of pulses to the set/reset strap.
ASIC
Within the HMC6042, the application specific integrated circuit (ASIC) performs the set/reset strap drive and sensor
amplification functions. The ASIC has its positive power supply rails broken into VDD1 and VDD2 elements to supply the
sensors/amplifiers and set/reset driver respectively. The VDD1 rail with the sensors and amplifiers combined is designed
to permit power supply duty cycling to conserve battery energy when the circuit is not used. Both the sensors and
amplifiers are designed to stabilize within 1 millisecond after power-up to permit snapshot measurements and return to
sleep status. Either PNP or P-MOSFET devices can be used to switch VDD1 off and on. To best ensure minimal energy
consumption, place any supply decoupling capacitors outside of the switch transistor, and not across the VDD1 side of the
switch.
Set/Reset Strap Driver
To permit operation from 2.4 to 3.6 volt DC supplies, and provide the required 400mA peak current spikes on the sensor
set/reset straps; both a H-bridge driver circuit and capacitive charge pump are employed. Within the H-Bridge drive circuit
several totem-pole complementary MOSFET stages are used to buffer the low voltage logic input (S/R_IN) with the last
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HMC6042
stages composed of 400 milli-ohm switches for high efficiency switching of the set and reset currents. The logic input is
expected to be normally high with high-to-low and low-to-high transitions creating reset and set pulses respectively.
Typically, the logic low time between pulses is from a half a millisecond to hundreds of milliseconds to accommodate
reverse polarity sensor measurements as desired. See application notes AN212 and AN213 for further details on nulling
sensor bridge offsets and set/reset strap operation.
To ensure plenty of current at all temperatures, strap load values, and VDD2 supply voltages, a charge pump is designed
into the ASIC to push the reservoir capacitor C1 up to a 3.3 volt value. This pump contains its own 25MHz oscillator and is
current limited to about 1mA draw for modest but quick charges after set and reset pulse usage. When using C1 values of
2.2 to 10 microfarad, only a small amount of voltage drop occurs on C1 and is quickly recharged to its quiescent voltage.
Other than momentary charge pump or set/reset pulse operation, the current draw on VDD2 goes to zero; and can be left
on continuous power supply rails indefinitely.
The choice of C1 and C2 capacitor values is dependant on the quantity and type of sensor set/reset straps used. The
requirement for the set/reset pulse values are one to two microsecond time constant pulses, with C2 and the set/reset
strap load resistance setting the RC time constant. Stand alone, the HMC6042 requires a 0.22 to 0.47 microfarad
capacitor, and with the extra HMC1041Z sensor in parallel the values increase to 0.47 to 1.0 microfarad. C1 is typically
sized at ten times the C2 value to have minimum voltage droop as a C2 charge is extracted from C1.
Amplifiers
Three sensor amplifier sections are designed into the ASIC for the embedded HMC1042 two-axis sensors and an optional
external third axis sensor. The nominal gain of each amplifier section is about 225 V/V with all three amplifiers fairly close
in matched gains. The amplifier sections are broken into two cascaded stages with gains of 22.5 and 10 from input to
output. The second stage has a feedback pin brought out to adjust the gain from unity (output and feedback pins shorted)
to ten (output and feedback pins open). The second stage feedback resistors are nominally 10k-ohms and sections gains
can be trimmed by adding external shunt resistances. Also modest amounts of feedback capacitance can be placed
across the output and feedback pins to lower the bandwidth of the amplifiers for greater EMI immunity.
ORDERING INFORMATION
Ordering Number
Caution
Product
HMC6042
Two-Axis Magnetic Sensor Circuit
HMC6042 T/R 1k
Tape and Reel 1k pieces/reel
HMC6042 Cut Tape
Cut Tape
This part is sensitive to damage
by electrostatic discharge. Use ESD
precautionary procedures when
touching, removing or inserting.
CAUTION: ESDS CAT. 1A
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 and 6,529,114 apply to the technology described
Honeywell
12001 Highway 55
Plymouth, MN 55441
Tel: 800-323-8295
www.honeywell.com/magneticsensors
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Form #900350
August 2007
©2007 Honeywell International Inc.
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