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Product Information
Allegro Hall-Effect Sensor ICs
By Shaun Milano
Allegro MicroSystems, LLC
Allegro™ MicroSystems, LLC is a world leader in developing, manufacturing, and marketing high-performance Halleffect sensor integrated circuits. This note provides a basic
understanding of the Hall effect and how Allegro designs
and implements Hall technology in packaged semiconductor
monolithic integrated circuits.
Hall Effect Principles
B
The Hall effect is named after Edwin Hall, who in 1879 discovered that a voltage potential develops across a currentcarrying conductive plate when a magnetic field passes
through the plate in a direction perpendicular to the plane of
the plate, as illustrated in the lower panel of figure 1.
The fundamental physical principle behind the Hall effect is
the Lorentz force, which is illustrated in the upper panel of
figure 1. When an electron moves along a direction, v, perpendicular to the applied magnetic field, B, it experiences a
force, F, the Lorentz force, that is normal to both the applied
field and the current flow.
In response to this force, the electrons move in a curved
path along the conductor and a net charge, and therefore a
voltage, develops across the plate. This Hall voltage, VH ,
obeys the formula below, which shows that VH is proportional to the applied field strength, and that the polarity of
VH is determined by the direction, either north or south, of
the applied magnetic field. By this property, the Hall effect
is employed as a magnetic sensor.
VH =
I B>
Rn q t
where:
Lorentz Force
→
→
→
F=qv×B
v
F
B
V = VH
IH
IH
V=0
B
Figure 1. The Hall effect and the Lorentz force. The blue arrows,
B, represent a magnetic field passing perpendicularly through the
conductive plate.
VH is the Hall voltage across the conductive plate,
I is the current passing through the plate,
q is the magnitude of the charge of the charge carriers,
ρn is the number of charge carriers per unit volume, and
t is the thickness of the plate.
Allegro semiconductor integrated circuits integrate a Hall
element, as the Hall effect applies to both conductive plates
and semiconductor plates. By using the Hall effect in a fully
integrated monolithic IC it is possible to measure magnetic
field strength and create a vast array of Hall-effect integrated circuits for many different applications.
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An Allegro Hall switch is activated by a positive magnetic
field that is generated by a south pole. A positive field will
turn on the output transistor and connect the output to GND,
acting as an an active low device.
The field required to activate the device and turn on the output transistor is called the magnetic operating point, and is
abbreviated BOP. When the field is removed the output transistor
is turned off. The field required to turn off the device once it is
activated is called the magnetic release point, or BRP. The difference between BOP and BRP is called the hysteresis and is used to
prevent switching bounce due to noise.
Allegro also makes magnetic latches and linear devices. Magnetic latches switch on with a south pole (BOP) and switch off
with a north pole (BRP). Requiring a north pole to deactivate the
latch separates latches from simple switches. Because they do
not switch off when the field is removed, they “latch” the output
in the present state until the opposite field is applied. Latches
are used for sensing rotating magnets for motor commutation or
speed sensing.
Linear devices have an analog output and are used for linear position sensing in linear encoders such as automotive throttle pedal
position sensors. They have a ratiometric output voltage that is
nominally VCC / 2 when no field is applied. In the presence of
a south pole the output will move in the direction of VCC and in
the presence of a north pole the output will move in the direction
of GND. Allegro has a broad range of Hall switches, latches and
linear devices suitable for a wide variety of applications. Please
reference the Allegro product selection guide at:
http://www.allegromicro.com/en/Products/Categories/Sensors.
Integrated circuits are electronic structures having a large number
of circuit elements in high density, regarded as a single unit.
The circuit elements include active components such as transistors and diodes, as well as passive components such as resistors,
capacitors, and inductors. These components are interconnected
by metal, usually aluminum, to make up the more complex
op-amps and comparators of the device. The Hall switch in
figure 2 is used for a simple illustration, but these components
are employed on all Allegro devices for even the most complex
ICs. The Hall element in figure 2 is shown as the square box with
the “X.” Its output is amplified, fed into a comparator, and then
to an open NMOS digital output. Allegro also makes Hall ICs
with two Hall elements for sensing differential magnetic fields
and even three Hall elements for direction detection of moving
VCC
Regulator
To all subcircuits
VOUT
Amp
Employing the Hall Effect
Allegro Hall-effect integrated circuits (IC) employ the Hall effect
by incorporating a Hall element with other circuitry, such as opamps and comparators, to make magnetically activated switches
and analog output devices. A simple Hall switch, such as the open
NMOS device shown in figure 2, can be used to determine if a
magnet is present or absent, and responds with a digital output.
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GND
Figure 2. Block diagram of a simple Hall effect switch IC
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ferromagnetic targets. However complex the sensor topology, the
components are all manufactured in and on the surface of a thin
substrate of a semiconductor material.
V2
B
B
IHALL
Hall IC Structure
VBIAS
VHALL
V1
GND
Allegro devices are manufactured on silicon substrates, by doping directly into the silicon with different materials to create
n-type (electron) or p-type (electron hole) carrier regions. These
n-type and p-type material regions are formed into geometries
that make up the active and passive components of the integrated
circuit, including the Hall element, and are connected together by
depositing metal over the geometries. In this way the active and
passive components are electrically connected together. Since the
geometries required are very small, in the range of microns and
sometimes even smaller, the circuit density is extremely high,
allowing complex circuits on a very small area of silicon.
N+
N+
N-epi
P+
P+
Si Substrate
Figure 3. Cross section of a single Hall element; an N-type epi resistor
contacted in each of the four corners.
The fact that all the active and passive elements are grown within
the substrate, or deposited on the silicon, makes them inseparable
from the silicon, and truly identifies them as monolithic integrated circuits. Figure 3 shows how a Hall element is integrated
into the Allegro IC. It is simply an area of doped silicon that
creates an n-type plate that will conduct current. As mentioned
earlier, when a current is forced from one corner of the plate to
the opposite corner, a Hall voltage will develop across the other
two corners of the plate when in the presence of a perpendicular
magnetic field. The Hall voltage will be zero when no field is
applied. In a similar fashion more complex geometries make up
active components such as NPN or NMOS transistor structures.
Figure 4 shows cross-sections of both NPN and PMOS transistors.
S
G
D
P
N
P
Si Substrate
N
P
E
B
C
N
P
N
Si Substrate
Figure 4. Cross sections of a PMOS (top) and an n NPN type BJT
transistor (bottom)
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Allegro MicroSystems, LLC
115 Northeast Cutoff
Worcester, Massachusetts 01615-0036 U.S.A.
1.508.853.5000; www.allegromicro.com
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For production efficiency, these circuits are grown in the substrate while it is still in the form of a large wafer. The circuits
are repeated in a pattern of rows and columns that can be sawn
into individual die, or “chips,” as illustrated in figure 5. A single
Allegro Hall-effect sensor IC device can be seen in figure 6. This
is the simple switch with functional block diagram as shown in
figure 2. All of the circuitry is included on the IC, including the
Hall element which can be seen as the red square in the middle of
the chip, as well as the amplifier circuitry and protection diodes
and the numerous resistors and capacitors needed to realize the
device functionality.
Hall Device Packaging
After sawing the silicon wafer rows and columns into individual
die, the die are then packaged for individual sale. A completed
package, one of many possible styles, is shown in figure 7. The
Figure 5. Silicon wafer, sawn into die after application of IC circuit pattern
Figure 6. Single Hall IC chip
Figure 7. A typical complete Hall device package, showing the mounted
die and wire connections to the pins.
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Allegro MicroSystems, LLC
115 Northeast Cutoff
Worcester, Massachusetts 01615-0036 U.S.A.
1.508.853.5000; www.allegromicro.com
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die is seen inside the case, mounted on a copper die pad. Contact to the copper leads is made through gold wire-bonding from
metal pads on the die surface to the electrically isolated package
leads. The package is then encapsulated, or overmolded, with
plastic to protect the die from damage.
The package in figure 7 is the simple switch of figure 2 with
VCC, GND, and an Output leads in a miniature 3-pin single inline package (SIP). Other packages can be seen in figure 8 and
include a wafer-level chip scale package (CSP), an SOT23W, an
MLP, a 3-pin UA-package SIP, and a 4-pin K-package SIP.
(A)
(C)
(D)
(B)
(E)
Figure 8. Typical complete Hall device packages: (A) surface-mount MLP and (B) SOT23W, (C) wafer-level chip
scale package (CSP), and through-hole mount (D) K type SIP, and (E) UA type SIP.
Copyright ©2009-2013, Allegro MicroSystems, LLC
The information contained in this document does not constitute any representation, warranty, assurance, guaranty, or inducement by Allegro to the
customer with respect to the subject matter of this document. The information being provided does not guarantee that a process based on this information will be reliable, or that Allegro has explored all of the possible failure modes. It is the customer’s responsibility to do sufficient qualification
testing of the final product to insure that it is reliable and meets all design requirements.
For the latest version of this document, visit our website:
www.allegromicro.com
296065-AN
Allegro MicroSystems, LLC
115 Northeast Cutoff
Worcester, Massachusetts 01615-0036 U.S.A.
1.508.853.5000; www.allegromicro.com
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