CN201726380U - Hall-switch circuit with temperature compensation - Google Patents
Hall-switch circuit with temperature compensation Download PDFInfo
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- CN201726380U CN201726380U CN2010202606920U CN201020260692U CN201726380U CN 201726380 U CN201726380 U CN 201726380U CN 2010202606920 U CN2010202606920 U CN 2010202606920U CN 201020260692 U CN201020260692 U CN 201020260692U CN 201726380 U CN201726380 U CN 201726380U
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- hall
- output
- switch circuit
- hysteresis comparator
- sensing sheet
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Abstract
The utility model relates to a Hall-switch circuit with temperature compensation, which comprises a voltage stabilizer, a Hall sensor connected between the output and ground wire of the voltage stabilizer, a Hall voltage differential amplifier with the two input terminals thereof being respectively connected with the Hall sensor, a hysteresis comparator connected with the output terminal of the Hall voltage differential amplifier, and an output unit connected with the output terminal of the hysteresis comparator, wherein the Hall-switch circuit is characterized in that the Hall voltage differential amplifier comprises a differential input pair consisting of two transistors, a PTAT (proportional to absolute temperature) current source for biasing the differential input pair, and a loading resistor made of the same material as the Hall sensor and respectively connected in series to each transistor of the differential input pair. Accordingly, the Hall-switch circuit of the utility model is easy-to-control and capable of eliminating the impact on the muH temperature coefficient without specific requirements for processes.
Description
Technical field
The utility model relates to a kind of Hall switch circuit, particularly a kind of Hall switch circuit with temperature-compensating.
Background technology
The principle of Hall effect is: to a suitable Hall material, if along the V that switches on its directions X
R, add magnetic field B on the Y direction, on the Z direction voltage V can appear then
H, V
HBe called Hall voltage, itself and magnetic field B, voltage V
RWith the pass of material self be
L wherein, W are the length of this Hall material and wide,
Be the Geometric corrections factor, μ
HBe hall mobility.
Semiconductor is good Hall effect material, so semiconductor integrated hall effect transducer is widely used in the various electronic equipments.Hall switch is a kind of in the Hall element, and its principle is: utilize integrated semiconductor Hall plate induction external magnetic field, output Digital Logic 0 or 1.Its transmission characteristic as shown in Figure 1, when the external magnetic field greater than working point magnetic field intensity B
OPThe time, be output as 0; When the external magnetic field less than point of release magnetic field intensity B
RPThe time, be output as 1.
Conventional Hall switch circuit composition module comprises pressurizer 201, hall sensing sheet 202, Hall voltage differential amplifier 203, hysteresis comparator 204 and output unit 205 as shown in Figure 2.
If the gain of Hall voltage differential amplifier is A
V, the sluggish width of hysteresis comparator is V
CO, then have
A
VV
H=V
CO (2)
Do not consider symbol, obtain B by formula (1) and (2)
OPAnd B
RPThe expression formula unification be:
μ in the formula (3)
HRising with temperature descends, and just negative temperature characteristic will make B
OPAnd B
RPExcellent temperature stability is arranged, must make in the formula (3) other parameter suitable temperature coefficient be arranged to offset μ
HNegative temperature coefficient.And
With
These two geometric parameter temperatures coefficient are very little, can ignore, so can only be to V
CO, A
VAnd V
RIn one or several carry out temperature-compensating.
According to These characteristics, publication number is that the Chinese patent application of CN101290233A has been announced a kind of temperature compensation, A in the formula (3)
VAnd V
RUnder the condition to temperature constant, regulate V
COTemperature coefficient to reduce μ
HThe influence of temperature coefficient, finally reduce B
OPAnd B
RPTemperature coefficient.It is a certain particular value that its circuit realizes requiring the temperature coefficient of one type resistance, and this just requires arts demand that the resistance of specified temp coefficient value is provided, and is more special to the requirement of technology.
Publication number is that the used method of the Chinese patent application of CN101290233 is V in the formula (3)
CO, A
VUnder the condition of maintenance to temperature constant, regulate V
RTemperature coefficient to reduce μ
HThe influence of temperature coefficient, finally reduce B
OPAnd B
RPTemperature coefficient.Its circuit is realized obtaining the item of another positive temperature coefficient to reduce μ with the item addition of the item of a positive temperature coefficient and a negative temperature coefficient
HThe influence of negative temperature characteristic.This method makes second-order characteristics difficult with control; Consider the drift of material behavior, the consistency after the batch process also is difficult to guarantee.
The utility model content
The technical problems to be solved in the utility model is the defective that will overcome prior art, provides a kind of and can eliminate μ
HThe influence of temperature coefficient, and technology there is not the yet Hall switch circuit of the band temperature-compensating of fine control of specific (special) requirements.
A kind of Hall switch circuit of the present utility model with temperature-compensating, comprise pressurizer, be connected the output of described pressurizer and the hall sensing sheet between the ground wire, two Hall voltage differential amplifiers that input links to each other with described hall sensing sheet respectively, the hysteresis comparator that links to each other with the output of described Hall voltage differential amplifier, and the output unit that links to each other with the output of described hysteresis comparator, it is characterized in that, described Hall voltage differential amplifier comprises that the difference input of being made up of two transistors is right, the described difference of setovering is imported the right current source that is proportional to absolute temperature, and is serially connected in the load resistance that one and described hall sensing sheet on each right transistor of described difference input are made with material respectively.
The Hall switch circuit of the band temperature-compensating that the utility model provides is by making V in the formula (3)
COAnd V
RMaintenance is accurately controlled the gain A of Hall voltage differential amplifier to temperature constant
VTemperature coefficient, make itself and μ
HThe temperature coefficient equal and opposite in direction, opposite in sign, the temperature coefficient of the two thereby cancel out each other obtains the B to temperature constant
OPAnd B
RPThe structure of this Hall voltage differential amplifier is: come the input of bias transistor difference right with the electric current that is proportional to absolute temperature, import right load with the resistance of hall sensing sheet material of the same type as difference.The mutual conductance of the Hall voltage differential amplifier of this structure has the characteristic to temperature constant, so, this Amplifier Gain A
VTemperature coefficient only relevant with the temperature characterisitic of the resistance of hall sensing sheet material of the same type, it just can follow the tracks of μ fully
HTemperature characterisitic (comprising second-order characteristics), produce desirable neutralization effect, and process drift is very little to consistency influence.
Description of drawings
Fig. 1 is a Hall switch transmission characteristic schematic diagram.
Fig. 2 is conventional Hall switch circuit schematic diagram.
Fig. 3 is the schematic diagram of a preferred embodiment of the utility model Hall switch circuit.
Fig. 4 a-c is the alternative preferred embodiment of the Hall voltage differential amplifier among Fig. 3.
Embodiment
3-4 is further described the utility model below in conjunction with accompanying drawing:
With reference to Fig. 3, the utility model Hall switch circuit comprises the pressurizer 301 to temperature constant, be connected the output of pressurizer 301 and the hall sensing sheet 302 between the ground wire, two Hall voltage differential amplifiers 303 that input links to each other with hall sensing sheet 302 respectively, the sluggish width that links to each other with the output of this Hall voltage differential amplifier is to the hysteresis comparator 304 of temperature constant, and the output unit 305 that links to each other with the output of this hysteresis comparator 304.This Hall voltage differential amplifier is by the current source I that is proportional to absolute temperature (PTAT)
PTAT, two NPN transistor Q
1And Q
2The difference input of forming to with the resistance R of hall sensing sheet material of the same type
EPI1, R
EPI2Constitute.Wherein, PTAT current source I
PTATBe connected two NPN transistor Q
1And Q
2Emitter and ground wire between right with this difference input of setovering, and with the resistance R of hall sensing sheet material of the same type
EPI1, R
EPI2As the right load of this difference input, be connected to this NPN transistor Q
1And Q
2Collector electrode and the output of pressurizer 301 between, this NPN transistor Q
1And Q
2Base stage be connected to hall sensing sheet 302 respectively, two inputs of hysteresis comparator 304 respectively with this NPN transistor Q
1And Q
2Collector electrode link to each other.
In the formula (3)
V
COAnd V
RThis temperature coefficient of four can be ignored, and draws B thus
OPAnd B
RPTemperature coefficient be:
A in the formula (4)
VExpression formula can be written as:
R in the formula (5)
EPIFor with the resistance R of hall sensing sheet material of the same type
EPI1, R
EPI2Value (the two equate), V
TBe thermoelectric potential, q is an electron charge, μ
N, N
D, t, L
1, W
1Be followed successively by resistance R
EPI1, R
EPI2Electron mobility, doping content, thickness, length, width.Because of I
PTATAnd V
TAll be proportional to absolute temperature, so G
MTemperature independent, promptly temperature coefficient is 0.Constant q temperature coefficient is 0, N
D, t, L
1, W
1These four temperatures coefficient all can be ignored.So A
VTemperature coefficient only and μ
NRelevant, A
VTemperature coefficient be:
Draw B by formula (6) and formula (4)
OPAnd B
RPTemperature coefficient:
Because of resistance R
EPIMaterial type identical with the hall sensing sheet, so the B that draws by formula (7)
OPAnd B
RPTemperature coefficient equal temperature coefficient poor of the temperature coefficient of electron mobility of same material and hall mobility, and the temperature coefficient of the temperature coefficient of the electron mobility of same material and hall mobility equates, so B
OPAnd B
RPTemperature coefficient be zero.
Fig. 4 a-c is other several embodiment of Hall voltage differential amplifier circuit among Fig. 3 (drawing the frame of broken lines part).Wherein, the input of the difference of Fig. 4 a constitutes changing into by two PNP transistors; The difference input of Fig. 4 b constitutes changing into by two PMOS transistors that are operated in subthreshold region; And the input of the difference of Fig. 4 c constitutes changing into by two nmos pass transistors that are operated in subthreshold region.Its bias current and load resistance still be the PTAT current source and with the resistance of hall sensing sheet material of the same type, its essence all is to realize the temperature coefficient and the μ of the gain of Hall voltage differential amplifier
HThe temperature coefficient equal and opposite in direction, the function of opposite in sign.
In Fig. 4 a, the PTAT current source is connected between the output of two transistorized emitters of PNP and pressurizer, and two load resistances are connected between transistorized collector electrode of each PNP and the ground wire, the transistorized base stage of each PNP is connected to the hall sensing sheet respectively, and two inputs of hysteresis comparator link to each other with the transistorized collector electrode of each PNP respectively.
In Fig. 4 b, the PTAT current source is connected between the output of two transistorized source electrodes of PMOS and pressurizer, and two load resistances are connected between each PMOS transistor drain and the ground wire, the transistorized grid of each PMOS is connected to the hall sensing sheet respectively, and two inputs of hysteresis comparator link to each other with each PMOS transistor drain respectively.
In Fig. 4 c, the PTAT current source is connected between the source electrode and ground wire of two nmos pass transistors, and two load resistances are connected between the output of the drain electrode of each nmos pass transistor and pressurizer, the grid of each nmos pass transistor is connected to the hall sensing sheet respectively, and two inputs of hysteresis comparator link to each other with the drain electrode of each nmos pass transistor respectively.
The utility model is right by the input of PTAT current offset difference, realizes the G to temperature constant
MUse again with the resistance of hall sensing sheet material of the same type and do the right load of difference input, realize that thus the temperature coefficient of gain of Hall voltage differential amplifier and the temperature coefficient of hall mobility have equal and opposite in direction, the characteristic of opposite in sign, the two is cancelled out each other and obtains the B of zero temperature
OPAnd B
RPThe actual realization of the utility model simple controllable does not have specific (special) requirements to technology, and it does not deposit process drift influences conforming problem.
Above embodiment only is used for explanation but does not limit the utility model.The utility model also has various deformation and improvement within the scope of the claims.Simple, the equivalence that every foundation claims of the present utility model and description are done changes and modifies, and all falls into the claim protection range of the utility model patent.
Claims (5)
1. Hall switch circuit with temperature-compensating, comprise pressurizer, be connected the output of described pressurizer and the hall sensing sheet between the ground wire, two Hall voltage differential amplifiers that input links to each other with described hall sensing sheet respectively, the hysteresis comparator that links to each other with the output of described Hall voltage differential amplifier, and the output unit that links to each other with the output of described hysteresis comparator, it is characterized in that, described Hall voltage differential amplifier comprises that the difference input of being made up of two transistors is right, the described difference of setovering is imported the right current source that is proportional to absolute temperature, and is serially connected in the load resistance that one and described hall sensing sheet on each right transistor of described difference input are made with material respectively.
2. Hall switch circuit as claimed in claim 1, it is characterized in that, described difference input is to being made up of two NPN transistor, described current source is connected between the emitter and ground wire of described two NPN transistor, described load resistance is connected between the output of the collector electrode of each NPN transistor and described pressurizer, the base stage of each NPN transistor is connected to described hall sensing sheet respectively, and two inputs of described hysteresis comparator link to each other with the collector electrode of each NPN transistor respectively.
3. Hall switch circuit as claimed in claim 1, it is characterized in that, described difference input is to being made up of two PNP transistors, described current source is connected between the output of described two transistorized emitters of PNP and described pressurizer, described load resistance is connected between transistorized collector electrode of each PNP and the ground wire, the transistorized base stage of each PNP is connected to described hall sensing sheet respectively, and two inputs of described hysteresis comparator link to each other with the transistorized collector electrode of each PNP respectively.
4. Hall switch circuit as claimed in claim 1, it is characterized in that, described difference input is to being made up of two PMOS transistors that are operated in subthreshold region, described current source is connected between the output of described two transistorized source electrodes of PMOS and described pressurizer, and described load resistance is connected between each PMOS transistor drain and the ground wire, the transistorized grid of each PMOS is connected to described hall sensing sheet respectively, and two inputs of described hysteresis comparator link to each other with each PMOS transistor drain respectively.
5. Hall switch circuit as claimed in claim 1, it is characterized in that, described difference input is to being made up of two nmos pass transistors that are operated in subthreshold region, described current source is connected between the source electrode and ground wire of described two nmos pass transistors, described load resistance is connected between the output of the drain electrode of each nmos pass transistor and described pressurizer, the grid of each nmos pass transistor is connected to described hall sensing sheet respectively, and two inputs of described hysteresis comparator link to each other with the drain electrode of each nmos pass transistor respectively.
Priority Applications (1)
Application Number | Priority Date | Filing Date | Title |
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CN2010202606920U CN201726380U (en) | 2010-07-16 | 2010-07-16 | Hall-switch circuit with temperature compensation |
Applications Claiming Priority (1)
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---|---|---|---|
CN2010202606920U CN201726380U (en) | 2010-07-16 | 2010-07-16 | Hall-switch circuit with temperature compensation |
Publications (1)
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CN201726380U true CN201726380U (en) | 2011-01-26 |
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Cited By (3)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN101886933A (en) * | 2010-07-16 | 2010-11-17 | 灿瑞半导体(上海)有限公司 | Hall switch circuit with temperature compensation |
CN102427360A (en) * | 2011-12-15 | 2012-04-25 | 湖南追日光电科技有限公司 | Circuit structure for reading orthogonal rotating current of Hall sensor |
CN102655404A (en) * | 2011-03-04 | 2012-09-05 | 苏州联科盛世科技有限公司 | Differential radio frequency switch circuit |
-
2010
- 2010-07-16 CN CN2010202606920U patent/CN201726380U/en not_active Expired - Lifetime
Cited By (5)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN101886933A (en) * | 2010-07-16 | 2010-11-17 | 灿瑞半导体(上海)有限公司 | Hall switch circuit with temperature compensation |
CN101886933B (en) * | 2010-07-16 | 2012-06-06 | 灿瑞半导体(上海)有限公司 | Hall switch circuit with temperature compensation |
CN102655404A (en) * | 2011-03-04 | 2012-09-05 | 苏州联科盛世科技有限公司 | Differential radio frequency switch circuit |
CN102655404B (en) * | 2011-03-04 | 2015-06-03 | 苏州联科盛世科技有限公司 | Differential radio frequency switch circuit |
CN102427360A (en) * | 2011-12-15 | 2012-04-25 | 湖南追日光电科技有限公司 | Circuit structure for reading orthogonal rotating current of Hall sensor |
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Legal Events
Date | Code | Title | Description |
---|---|---|---|
C14 | Grant of patent or utility model | ||
GR01 | Patent grant | ||
AV01 | Patent right actively abandoned |
Granted publication date: 20110126 Effective date of abandoning: 20120606 |