CN203606948U - Energy-saving and environment-friendly infrared remote control signal generating circuit - Google Patents
Energy-saving and environment-friendly infrared remote control signal generating circuit Download PDFInfo
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- CN203606948U CN203606948U CN201320859439.0U CN201320859439U CN203606948U CN 203606948 U CN203606948 U CN 203606948U CN 201320859439 U CN201320859439 U CN 201320859439U CN 203606948 U CN203606948 U CN 203606948U
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Abstract
The utility model relates to an energy-saving and environment-friendly infrared remote control signal generating circuit. The energy-saving and environment-friendly infrared remote control signal generating circuit comprises a key matrix, a modulation signal generating module and an infrared signal transmitting module which are sequentially and electrically connected, and is characterized in that a first power end of the modulation signal generating module is electrically connected with a battery and an input end of a direct current (DC)-DC conversion module; a second power end of the modulation signal generating module and a power end of the infrared signal transmitting module are electrically connected with an output end of the DC-DC conversion module; the modulation signal generating module is electrically connected with the DC-DC conversion module and is used for output control so as to enable the DC-DC conversion module to be switched between a dormant state and a normal work state. After the energy-saving and environment-friendly infrared remote control signal generating circuit is adopted, the electric quantity of the battery is fully utilized, and the energy consumption and the cost of a circuit system are effectively reduced; furthermore, the stability of remote control signal intensity and remote control distance can be improved.
Description
Technical field
The utility model relates to electronic circuit and Infrared Ray Remote Control Technology, is specifically related to a kind of infrared remote-controlled signal circuit for generating of energy-conserving and environment-protective.
Background technology
Infrared remote-controlled signal circuit for generating typically refers to and produces and launch infrared remote-controlled signal, realizes the circuit of the infrared radio control to controlled device, is widely used in the fields such as household electrical appliances, toy, Industry Control.
Figure 1 shows that the circuit block diagram of traditional infrared remote-controlled signal circuit for generating, mainly comprise electric battery, oscillator, key-press matrix, modulation signal generation module and infrared signal transmitter module etc.Wherein, modulation signal generation module generally comprises low-frequency oscillation unit, clock and carrier wave generation unit, key-press matrix scanning element, coded modulation unit and output driver element etc., and its electronic circuit block scheme as shown in Figure 2; Infrared signal transmitter module is generally by infrarede emitting diode IR_LED, current-limiting resistance R
lC, switch T
sWcomposition, or by infrarede emitting diode IR_LED and constant current source I
cCScomposition, respectively as shown in Fig. 3-1,3-2.
In Fig. 1, electric battery provides supply voltage V for infrared remote-controlled signal circuit for generating
bAT, most formed by two joint dry cells, also there is minority to adopt a button cell, the Full Charge Capacity voltage of electric battery is generally 3.0V; The output signal S of oscillator
oSC1be sent to modulation signal generation module, to produce its inner clock signal and carrier signal, S
oSC1frequency majority be 455KHz, corresponding 37.9KHz carrier frequency, also having minority is 432KHz, 440KHz, 480KHz equifrequent, the carrier frequency of corresponding 36KHz, 36.7KHz, 40KHz respectively, the most ceramic resonator that adopt of traditional oscillator, also there is the minority to adopt crystal oscillator, now also have and adopt integrated oscillator circuit; Key-press matrix is formed by connecting according to different permutation and combination by multiple buttons, and the corresponding control signal coding of each button, realizes the corresponding function of controlling; Modulation signal generation module is exported the modulation signal S of corresponding coding control signal according to the button being pressed
m, this signal removes to drive infrarede emitting diode transmitting infrared remote-controlled signal by the constant current source in switch or Fig. 3-2 in control chart 3-1.
In Fig. 1,2,3-1 and 3-2, in the time not having that a button is pressed, most of circuit are in dormant state, whether a button is pressed with monitoring to only have the normal work of low-frequency oscillation unit and key-press matrix scanning element, because oscillation frequency is low, be generally 30KHz~70KHz, its power consumption is very little, in the time of dormant state, the electric current of infrared remote-controlled signal circuit for generating consumption is generally less than 1uA; In the time monitoring that a button is pressed, key-press matrix scanning element produces sleeping/waking signal S
wP, make other circuit enter normal operating conditions, launch corresponding infrared remote-controlled signal, now flow through the instantaneous peak current I of infrarede emitting diode
lEDbe greater than 100mA.Because compole is short when the average cumulative of infrared remote controller transmitting remote signal, and most of time is all waiting for that button is pressed, and dormant state is set can extends the serviceable life of battery.
Common oscillator in the market and modulation signal generation module, the supply voltage of its normal work is generally greater than 1.8V, when adopting two joint dry cell power supplies, when battery electric quantity is Full Charge Capacity, supply voltage V
bATfor 3.0V, along with the use of remote control circuit, through after a period of time, battery electric quantity is consumed, supply voltage V
bATcan decline gradually, work as V
bATafter 1.8V, remote control circuit cisco unity malfunction, still, now the electric weight of battery is not depleted, and this has caused greatly waste.On the other hand, if infrared signal transmitter module adopts the circuit in Fig. 3-1, the instantaneous peak current I of infrarede emitting diode
lEDas shown in formula (1):
Wherein, V
ffor the forward conduction voltage of infrarede emitting diode IR_LED, R
oNfor switch T
sWequivalent conducting resistance.
The transient transmission power of infrarede emitting diode is:
P
LED=V
F*I
LED (2)
From formula (1) and (2), in the time that battery is Full Charge Capacity, supply voltage V
bATthe highest, thus instantaneous peak current I
lEDmaximum, the emissive power of infrared signal is also maximum, and farthest, under normal circumstances, remote control distance now can be considerably beyond the needed remote control distance of practical application for remote control distance, and this also causes the waste of battery electric quantity; When battery electric quantity is consumed, supply voltage V
bATcan decline, thus instantaneous peak current I
lEDreduce, the emissive power of infrared signal also can reduce, and remote control distance shortens, and remote control distance can change along with cell voltage, less stable.
The more important thing is, the forward conduction voltage of infrarede emitting diode is generally 1.1V~1.4V, even employing integrated oscillator circuit, modulation signal generation module under low pressure also can be worked, but the minimum cell voltage of the normal work of infrared signal transmitter module still can be limited to the forward conduction voltage of infrarede emitting diode, when cell voltage is during lower than the forward conduction voltage of infrarede emitting diode, infrared signal transmitter module can not be launched infrared signal.In the time adopting a joint dry cell power supply, it is very serious that situation becomes, and the electric weight of battery does not have depleted, caused greatly waste.
In sum, the shortcoming of traditional circuit is: when cell voltage does not have when depleted compared with low and battery electric quantity, and infrared remote-controlled signal circuit for generating cisco unity malfunction, remaining battery electric quantity can not be utilized, and has caused waste; And most two joint dry cells or the button cells of adopting of traditional circuit are powered, cost is high, and energy consumption is large; On the other hand, the most circuit that adopt in Fig. 3-1 of the infrared signal transmitter module of traditional circuit, its remote control distance can change along with cell voltage, less stable.
Utility model content
The utility model technical issues that need to address are, how a kind of infrared remote-controlled signal circuit for generating of energy-conserving and environment-protective is provided, can make full use of battery electric quantity and effectively reduce energy consumption, improve the stability of remote signal intensity and the stability of remote control distance simultaneously and reduce costs.
Above-mentioned technical matters of the present utility model solves like this, build a kind of infrared remote-controlled signal circuit for generating of energy-conserving and environment-protective, comprise key-press matrix, modulation signal generation module and the infrared signal transmitter module of electrical connection successively, it is characterized in that the first power end electrical connection battery of described modulation signal generation module and the input end of DC-to-dc (DC-DC) conversion module; The second source end of described modulation signal generation module and the power end of described infrared signal transmitter module are all electrically connected the output terminal of DC-DC conversion module; The control of described modulation signal generation module is electrically connected described DC-DC conversion module, for exporting to control, DC-DC conversion module is changed between dormant state and normal operating conditions.
The infrared remote-controlled signal circuit for generating of the energy-conserving and environment-protective that provide according to the utility model, comprises following two kinds of concrete forms:
(i) described DC-DC conversion module is DC-DC boost module;
(ii) described DC-DC conversion module is DC-DC buck module.
The infrared remote-controlled signal circuit for generating of the energy-conserving and environment-protective that provide according to the utility model, described infrared remote-controlled signal circuit for generating also comprises the oscillator being electrically connected with modulation signal generation module.
The infrared remote-controlled signal circuit for generating of the energy-conserving and environment-protective that provide according to the utility model, described modulation signal generation module comprises key-press matrix scanning element, coded modulation unit and the output driver element of electrical connection successively; Described key-press matrix scanning element is also electrically connected low-frequency oscillation unit and clock and carrier wave generation unit, and described clock and carrier wave generation unit are also electrically connected described coded modulation unit; Described key-press matrix scanning element is also controlled electrical connection described coded modulation unit, output driver element and clock and carrier wave generation unit; The power end of described low-frequency oscillation unit and the power end of described key-press matrix scanning element are all electrically connected the first power end V of modulation signal generation module
bAT, power end, the output power end of driver element and the power end of clock and carrier wave generation unit of described coded modulation unit is all electrically connected the second source end V of modulation signal generation module
dD.
The infrared remote-controlled signal circuit for generating of the energy-conserving and environment-protective that provide according to the utility model, it is the dry cell of a joint 1.5V that described battery includes, but are not limited to.
The infrared remote-controlled signal circuit for generating of the energy-conserving and environment-protective that the utility model provides, compared with prior art, has following advantage:
1, under low-voltage, still can work, can make full use of battery electric quantity;
2, the additional waste while reducing high voltage, the energy consumption of reduction infrared signal transmitter module;
3, the stable operating voltage of infrared signal transmitter module, has ensured the stability of remote signal intensity and the stability of remote control distance;
4, only adopt a joint dry cell power supply, reduced Circuits System cost.
Accompanying drawing explanation
Further the utility model is elaborated below in conjunction with the drawings and specific embodiments.
Fig. 1 is the circuit block diagram of traditional infrared remote-controlled signal circuit for generating;
Fig. 2 is the circuit block diagram of modulation signal generation module in Fig. 1;
Fig. 3-1st, the electrical block diagram of infrared signal transmitter module the first embodiment in Fig. 1;
Fig. 3-2nd, the electrical block diagram of infrared signal transmitter module the second embodiment in Fig. 1;
Fig. 4 is the circuit block diagram of infrared remote-controlled signal circuit for generating of the present utility model;
Fig. 5 is the circuit block diagram of modulation signal generation module in Fig. 4;
Fig. 6 is the circuit block diagram of the utility model the first embodiment;
Fig. 7 is the circuit block diagram of the utility model the second embodiment.
Embodiment
First, principle of work of the present utility model is described:
The infrared remote-controlled signal circuit for generating of energy-conserving and environment-protective of the present utility model, can improve the electric weight utilization factor of battery and the stability of remote control distance, and reduce energy consumption and cost, its circuit block diagram as shown in Figure 4, the key distinction of this circuit and traditional circuit is to have increased a DC-DC conversion module, by cell voltage V
bATtransform to needed voltage V
dD, and voltage V
dDas the main supply voltage of infrared remote-controlled signal circuit for generating.
DC-DC conversion module can keep voltage V
dDinvariable in the certain limit of cell voltage, such as: V worked as
bATduring for 0.7V~1.5V, V
dDconstant is 1.5V, and like this, in the time that cell voltage is lower, infrared remote-controlled signal circuit for generating still can normally be worked, and can make full use of battery electric quantity, and battery electric quantity is exhausted.
In order to save battery electric quantity, when other circuit is during in dormant state, DC-DC conversion module is also designed in dormant state, makes its not consumes power, therefore need to be by the sleeping/waking signal S of modulation signal generation module inside
wPoutput to DC-DC conversion module; For monitoring under dormant state, whether a button is pressed, and modulation signal generation module must adopt cell voltage V under dormant state
bATpower supply is V so modulation signal generation module has two supply voltages
bATand V
dD, as shown in Figures 4 and 5.
The utility model has the advantage of, adopt DC-DC conversion module not only can make full use of battery electric quantity, battery electric quantity is exhausted, and work as V
dDbe greater than V
ftime, the minimum cell voltage of the normal work of circuit is no longer limited to the forward conduction voltage of infrarede emitting diode, thereby makes to adopt a joint dry cell power supply to become possibility.In the case of the conversion efficiency of DC-DC conversion module is higher (being greater than 86%), adopt a joint dry cell power supply not only can make full use of battery electric quantity, extend the serviceable life of battery, and can reduce the use amount of battery, reach and reduce costs, the object of energy-conserving and environment-protective.
Adopt a joint dry cell power supply and adopt DC-DC conversion module to carry out supply voltage conversion, can be by voltage V
dDbe designed to lower voltage.In the time of transmitting remote signal, the electric current of circuitry consumes is mainly the electric current I that flows through light emitting diode
lED, now the power consumption of circuit is:
P
DD=V
DD*I
LED (3)
From formula (3), V
dDwhen lower, the power consumption of circuit also can reduce, and this is another advantage of the present utility model.
The second, be elaborated with circuit in conjunction with specific embodiments:
The first embodiment
First preferred embodiment of the present utility model as shown in Figure 6, in this circuit, adopts a joint dry cell power supply, and adopt DC-DC boost module to carry out supply voltage conversion, and oscillator adopts integrated oscillator circuit to adapt to low pressure applications.In the time that battery is Full Charge Capacity, cell voltage V
bATthe highest, be 1.5V, if V
dDbe designed to be less than 1.5V, such as: V
dDfor 1.25V, work as V
bATduring for 1.25V~1.5V, V
dDor can be along with V
bATchange, if infrared signal transmitter module adopts the circuit of Fig. 3-1, its remote control distance also can change along with cell voltage, so, V
dDcan only be designed to 1.5V.
Although Fig. 6 circuit has solved the problem that traditional circuit exists, reach the object of energy-conserving and environment-protective, it is optimum that its power consumption does not also reach, because V
dDcan only be designed to equal the Full Charge Capacity voltage of battery, and the minimum power supply voltage, V of the normal work of the utility model circuit
dDonly be limited to the forward conduction voltage V of infrarede emitting diode
f, V
fbe generally 1.2V, so as long as V
dDmeet formula (4), circuit just can normally be worked, and from analysis above, in the time of transmitting remote signal, reduces V
dDcan reduce the power consumption of circuit.
V
F+I
LED*R
S≤V
DD≤V
BATF (4)
Wherein, R
s=R
lC+ R
oNor Rs is constant current source I
cCSinternal resistance, V
bATFthe Full Charge Capacity voltage of battery.
The second embodiment
Second preferred embodiment of the present utility model as shown in Figure 7, in this circuit, adopts a joint dry cell power supply, and adopt DC-DC buck module to carry out supply voltage conversion, and oscillator adopts integrated oscillator circuit to adapt to low pressure applications.V
dDbe designed to meet formula (4), such as: 1.21V, as cell voltage V
bATbe greater than V
dDtime, DC-DC buck module works in decompression mode, and supply voltage is transformed to lower voltage to reduce power consumption, as cell voltage V
bATbe less than V
dDtime, DC-DC buck module works in boost mode, and supply voltage is transformed to higher voltage to guarantee that infrared remote-controlled signal circuit for generating still can normally be worked and battery electric quantity be exhausted in the time that cell voltage is lower.DC-DC buck module can guarantee voltage V
dDin the certain limit of cell voltage, keep low voltage invariable, such as: V worked as
bATduring for 0.7V~1.5V, V
dDconstant is 1.21V.
Two preferred embodiments of the present utility model respectively have its advantage, and the circuit of the first preferred embodiment is relatively simple, but its power consumption does not also reach optimum, and the power consumption optimum of the second preferred embodiment, but circuit is more more complex.
Because the utility model circuit can adopt a joint dry cell power supply, and in the time that the conversion efficiency of DC-DC conversion module is higher, can extend the serviceable life of battery, therefore the utility model can reduce the use amount of battery, only CONTINENTAL AREA OF CHINA, every year just can be less with more than one hundred million batteries.
Technical characterictic of the present utility model is: in infrared remote-controlled signal circuit for generating, adopted DC-DC conversion module, when cell voltage does not have when depleted compared with low and battery electric quantity, infrared remote-controlled signal circuit for generating still can normally be worked, and can make full use of battery electric quantity, and battery electric quantity is exhausted.
From the above: infrared remote-controlled signal circuit for generating of the present utility model, adopt DC-DC conversion module to improve the electric weight utilization factor of battery and the stability of remote control distance, and reduce energy consumption, extend the serviceable life of battery, and can reduce the use amount of battery, the shortcoming that has overcome conventional art, reaches and reduces costs, the object of energy-conserving and environment-protective.
The foregoing is only preferred embodiment of the present utility model, all equalizations of doing according to the utility model claim scope change and modify, and all should belong to the covering scope of the utility model claim.
Claims (7)
1. the infrared remote-controlled signal circuit for generating of energy-conserving and environment-protective, comprise key-press matrix, modulation signal generation module and the infrared signal transmitter module of electrical connection successively, it is characterized in that the first power end electrical connection battery of described modulation signal generation module and the input end of DC-DC conversion module; The second source end of described modulation signal generation module and the power end of described infrared signal transmitter module are all electrically connected the output terminal of DC-DC conversion module; The control of described modulation signal generation module is electrically connected described DC-DC conversion module, for exporting to control, DC-DC conversion module is changed between dormant state and normal operating conditions.
2. signal generating circuit according to claim 1, is characterized in that, described DC-DC conversion module is DC-DC boost module.
3. signal generating circuit according to claim 1, is characterized in that, described DC-DC conversion module is DC-DC buck module.
4. according to signal generating circuit described in claim 1-3 any one, it is characterized in that, described infrared remote-controlled signal circuit for generating also comprises the oscillator being electrically connected with modulation signal generation module.
5. signal generating circuit according to claim 4, is characterized in that, described modulation signal generation module comprises key-press matrix scanning element, coded modulation unit and the output driver element of electrical connection successively; Described key-press matrix scanning element is also electrically connected low-frequency oscillation unit and clock and carrier wave generation unit, and described clock and carrier wave generation unit are also electrically connected described coded modulation unit; Described key-press matrix scanning element is also controlled electrical connection described coded modulation unit, output driver element and clock and carrier wave generation unit; The power end of described low-frequency oscillation unit and the power end of described key-press matrix scanning element are all electrically connected the first power end (V of modulation signal generation module
bAT), power end, the output power end of driver element and the power end of clock and carrier wave generation unit of described coded modulation unit is all electrically connected the second source end (V of modulation signal generation module
dD).
6. according to signal generating circuit described in claim 1-3 any one, it is characterized in that, described battery is the dry cell of a joint 1.5V.
7. according to signal generating circuit described in claim 1-3 any one, it is characterized in that, infrared signal transmitter module comprises infrared-emitting diode, resistance and the ground of electrical connection successively.
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CN201320859439.0U CN203606948U (en) | 2013-12-24 | 2013-12-24 | Energy-saving and environment-friendly infrared remote control signal generating circuit |
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CN201320859439.0U CN203606948U (en) | 2013-12-24 | 2013-12-24 | Energy-saving and environment-friendly infrared remote control signal generating circuit |
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Cited By (1)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN103700247A (en) * | 2013-12-24 | 2014-04-02 | 泉芯电子技术(深圳)有限公司 | Energy-saving and environment-friendly infrared remote control signal generating circuit |
-
2013
- 2013-12-24 CN CN201320859439.0U patent/CN203606948U/en not_active Withdrawn - After Issue
Cited By (2)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN103700247A (en) * | 2013-12-24 | 2014-04-02 | 泉芯电子技术(深圳)有限公司 | Energy-saving and environment-friendly infrared remote control signal generating circuit |
CN103700247B (en) * | 2013-12-24 | 2016-06-29 | 泉芯电子技术(深圳)有限公司 | A kind of infrared remote-controlled signal circuit for generating of energy-conserving and environment-protective |
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Legal Events
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---|---|---|---|
C14 | Grant of patent or utility model | ||
GR01 | Patent grant | ||
AV01 | Patent right actively abandoned |
Granted publication date: 20140521 Effective date of abandoning: 20160629 |
|
C25 | Abandonment of patent right or utility model to avoid double patenting |