KR102116362B1 - Apparatus and method for outputting audio - Google Patents

Abstract

Disclosed is an audio output device and method. In the audio output method of the audio output device according to the present invention, when power is supplied, calculating a temperature value of the voice coil of the audio output device using a preset heat transfer model algorithm, and audio according to the calculated temperature value of the voice coil And determining a gain value for adjusting the output level of the signal to adjust the output level for the audio signal and outputting the audio signal whose output level is adjusted. Accordingly, the audio output device may protect the voice coil from overheating, and control the gain value according to the temperature change of the voice coil differently to output an audio signal with a sound quality of a certain level or higher.

Description

Audio output device and method {Apparatus and method for outputting audio}

The present invention relates to an audio output device and method, and more particularly, to an audio output device and method capable of controlling the internal temperature of the audio output device.

In general, an audio output device such as a speaker needs to be supplied with power having a size corresponding to the output level in order to increase the output level of the audio signal. In this case, current flows into the voice coil wound on the diaphragm that transmits vibration to the atmosphere, and the temperature of the voice coil rises. Therefore, when the audio signal is output at a high output level for a long time, the temperature of the voice coil rises to the melting point of the coating film coated on the voice coil, resulting in a problem that the voice coil is destroyed.

Therefore, in order to improve this problem, the conventional audio output device separates the audio signals converted into digital signals for each frequency band, and then increases the size of the output signal through which the audio signals separated for each frequency band are output through the amplifier. Estimate. Thereafter, the audio output device estimates the temperature of the voice coil by applying the magnitude value of the output signal to the audio signal to the predefined heating model algorithm. Then, the audio output device controls the temperature rise of the voice coil by reducing or increasing the gain value for adjusting the output level of the audio signal according to whether the estimated temperature of the voice coil is greater than or equal to a preset threshold.

However, in general, since the voice coil has a very small heat capacity, if an audio signal is not input even when the temperature is high, it falls to the ambient air temperature level in a short time. On the other hand, since the heat capacity of the permanent magnet that generates vibrations by the current flowing through the voice coil is about 200 times larger than that of the voice coil, it takes more time for the temperature of the permanent magnet to rise and fall than for the voice coil.

Therefore, in the conventional voice coil temperature improvement method, when the audio output device is powered up and restarted while the voice coil maintains a temperature higher than the temperature at the normal temperature level, the voice coil temperature estimated through the above method And the error of the actual voice coil temperature. Accordingly, there is a problem in that the control timing of the gain value for adjusting the output level of the audio signal is delayed due to the error, which may cause overheating of the voice coil.

It has been devised to solve the above-described problem, and an object of the present invention is to protect the voice coil of the audio output device from overheating.

Furthermore, an object of the present invention is to control the gain value according to the temperature change of the voice coil differently so that sound quality of a certain level or more is maintained.

In the audio output method of the audio output device according to an embodiment of the present invention for achieving the above object, when the power is supplied, the temperature of the voice coil of the audio output device using a predetermined heat transfer model algorithm Calculating a value, determining a gain value for adjusting the output level of the audio signal according to the calculated temperature value of the voice coil, adjusting the output level for the audio signal, and adjusting the output level of the audio signal It includes the step of outputting.

And, further comprising the step of setting the initial temperature value of the voice coil using the heat transfer model algorithm, the adjusting step, the temperature value of the voice coil calculated based on the set initial temperature value The gain value may be determined according to whether or not it exists in a predetermined threshold section.

In addition, the initial temperature value may be a temperature value for the voice coil at a time when power is re-supplied to the audio output device after the power initially supplied is cut off.

And, the heat transfer model algorithm is derived from the following equation, T (s) / P (s) = (R _TV R _TM (C _TV + C _TM ) s + (R _TV + R _TM )) / ((R _TV R _TM C _TV C _TM ) s ² + (R _TV C _TV + R _TM C _TM ) s + 1), where P (s) is the output power for outputting the audio signal, T (s) is the The temperature value of the voice coil, R _TV is the thermal resistance of the voice coil, C _TV is the thermal capacity of the voice coil, R _TM is the thermal resistance of the permanent magnet, C _TM can be the thermal capacity of the permanent magnet.

In addition, the adjusting step, determining whether the temperature value of the voice coil is present in a preset first threshold section and the determination result, if the preset first threshold section is exceeded, a preset reference gain value And determining a lower first gain value as a gain value for adjusting the output level of the audio signal.

And, in the determining, if the temperature value of the voice coil is present in a preset heat-resistant limit section, determine a second gain value lower than the first gain value as a gain value for adjusting the output level of the audio signal. Can be.

In addition, the heat-resistant limit section is a temperature section above the melting point of the voice coil, and the second gain value is the temperature value of the voice coil existing in the heat-resistant limit section and the highest temperature value of the first critical section. It may be a value lowered to a size proportional to the temperature difference for.

And, the measuring step, the temperature of the voice coil is continuously measured, the adjusting step, in the state that the audio signal is output at an output level adjusted based on the first or second gain value, Determining whether the temperature value of the voice coil is less than a preset second threshold section, and as a result of the determination, when the temperature value of the voice coil is between the first to second critical sections, the first or second The method may further include determining a third gain value higher than the first gain value as a gain value for adjusting the output level of the audio signal when the second gain value is maintained and less than the second threshold period.

Further, the third gain value may be changed to a width smaller than the change width to the first gain value.

On the other hand, according to another embodiment of the present invention for achieving the above object, the audio output device is an input unit for receiving an audio signal, a signal processing unit for performing signal processing for the audio signal, an output for outputting the signal-processed audio signal When power is supplied, the temperature value of the voice coil is calculated using a preset heat transfer model algorithm, and a gain value for adjusting the output level of the audio signal is determined according to the calculated temperature value of the voice coil. It includes a control unit for adjusting the output level for the signal-processed audio signal.

In addition, the controller sets the initial temperature value of the voice coil using the heat transfer model algorithm, and whether the temperature value of the voice coil calculated based on the set initial temperature value exists in a predetermined threshold section. The gain value may be determined according to whether or not it is.

In addition, the initial temperature value may be a temperature value for the voice coil at a time when power is re-supplied to the audio output device after the power initially supplied is cut off.

And, the heat transfer model algorithm is derived from the following equation, T (s) / P (s) = (R _TV R _TM (C _TV + C _TM ) s + (R _TV + R _TM )) / ((R _TV R _TM C _TV C _TM ) s ² + (R _TV C _TV + R _TM C _TM ) s + 1), where P (s) is the output power for outputting the audio signal, T (s) is the The temperature value of the voice coil, R _TV is the thermal resistance of the voice coil, C _TV is the thermal capacity of the voice coil, R _TM is the thermal resistance of the permanent magnet, C _TM can be the thermal capacity of the permanent magnet.

In addition, when the temperature value of the voice coil exceeds a preset first threshold period, the controller may determine a first gain value lower than a preset reference gain value as a gain value for adjusting the output level of the audio signal. .

The controller may determine a second gain value lower than the first gain value as a gain value for adjusting the output level of the audio signal when the temperature value of the voice coil is in a preset heat resistance limit section. .

In addition, the heat-resistant limit section is a temperature section above the melting point of the voice coil, and the second gain value is the temperature value of the voice coil existing in the heat-resistant limit section and the highest temperature value of the first critical section. It may be a value lowered to a size proportional to the temperature difference for.

Then, in the state in which an audio signal is output at an output level adjusted based on the first or second gain value, the control unit calculates a temperature value of the voice coil to determine whether or not it is less than a preset second threshold section. Judging, if the temperature value of the voice coil is between the first to second threshold periods, the first or second gain value is maintained, and if it is less than the second threshold period, it is higher than the first gain value The third gain value may be determined as a gain value for adjusting the output level of the audio signal.

Further, the third gain value may be changed to a width smaller than the change width to the first gain value.

As described above, according to various embodiments of the present invention, while the audio output device protects the voice coil from overheating, the gain value according to the temperature change of the voice coil is differently controlled to output an audio signal with a sound quality of a certain level or higher. Can be.

1 is a block diagram of an audio output device according to an embodiment of the present invention,
Figure 2 is a circuit diagram showing the heat transfer of the audio output device according to an embodiment of the present invention,
Figure 3 is an exemplary view showing the temperature change of the voice coil of the audio output device according to an embodiment of the present invention,
Figure 4 is an exemplary diagram for determining a gain value according to the temperature rise of the voice coil in the audio output device according to an embodiment of the present invention,
5 is an exemplary diagram for determining a gain value according to a decrease in temperature of a voice coil in an audio output device according to an embodiment of the present invention;
6 is an exemplary view showing a gain value changed according to a change in temperature of a voice coil in an audio output device according to an embodiment of the present invention;
7 is a first example of determining a gain value according to the temperature rise of the voice coil in the audio output device according to an embodiment of the present invention;
8 is a second exemplary view for determining a gain value according to a temperature rise degree of a voice coil in an audio output device according to another embodiment of the present invention;
9 is a flowchart of an audio output method of an audio output device according to an embodiment of the present invention,
10 is a flowchart of a method for determining a gain value according to a temperature rise of a voice coil in an audio output device according to an embodiment of the present invention,
11 is a flowchart of a method for determining a gain value according to a decrease in temperature of a voice coil in an audio output device according to an embodiment of the present invention.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 is a block diagram of an audio output device according to an embodiment of the present invention.

As shown in FIG. 1, the audio output device 100 is a terminal device that outputs an audio signal, and may be, for example, a speaker. The audio output device 100 may include an input unit 110, a signal processing unit 120, an output unit 130, a control unit 140, and a power supply unit 150.

The input unit 110 receives an audio signal from an audio source device (not shown), and the signal processing unit 120 processes the audio signal input through the input unit 110 in a form that can be output through the output unit 130. . Specifically, the audio signal input through the input unit 110 may be an analog signal. Accordingly, the signal processing unit 120 converts the analog type audio signal into a digital signal, and separates the audio signal converted into a digital signal into frequency bands. Thereafter, the signal processing unit 120 converts each audio signal separated for each frequency band into an analog audio signal. Accordingly, the output unit 130 may amplify the audio signal processed in an analog form and output it as an audible signal.

As described above, since signal processing of the input audio signal and amplifying and outputting the signal-processed audio signal are known techniques, detailed descriptions thereof will be omitted.

The control unit 140 controls overall operations of the components constituting the audio output device 100. Particularly, when external power is supplied through the power supply unit 150, the control unit 140 calculates the temperature value of the voice coil using a preset heat transfer model algorithm. Here, the voice coil is a coil wound directly connected to the diaphragm of the audio output device 100 such as a speaker, and serves to vibrate the diaphragm with vibrations generated from the magnetic field and permanent magnets by the current flowing through the voice coil. Accordingly, when the diaphragm is vibrated, the air in the air vibrates, and a sound for the audio signal can be output. Meanwhile, in the voice coil, the temperature of the coil may be increased by the current flowing in the coil.

Accordingly, when the external power is supplied, the controller 140 may estimate the temperature of the current voice coil by periodically calculating the temperature value of the voice coil using a heat transfer model algorithm. When the temperature value of the voice coil is calculated, the control unit 140 determines a gain value for adjusting the output level of the audio signal to be output through the output unit 130 according to the calculated temperature value of the voice coil and determines Adjust the output level for the signal-processed audio signal based on the gain value.

More specifically, when the first power is supplied to the audio output device 100 through the power supply unit 150, the control unit 140 sets an initial temperature value of the voice coil using a heat transfer model algorithm. Thereafter, the control unit 140 may determine a gain value for adjusting the output level of the audio signal according to whether the temperature value of the calculated voice coil is present in a predetermined threshold section based on the initial temperature value of the set voice coil. have.

Here, the initial temperature value is a voice at a time when power is re-supplied through the power supply unit 150 in a state in which power supply is cut off after power is initially supplied to the audio output device 100 through the power supply unit 150. It can be the measured temperature on the coil.

In addition, the aforementioned heat transfer model algorithm is an algorithm for calculating the temperature value of the voice coil based on the power supplied to the audio output device 100. The heat transfer model algorithm may express the relationship between the electrical energy for the power supplied to the audio output device 100 and the temperature of the voice coil as a continuous-time transfer function, derived from Equation 1 below. Can be.

Here, P (s) is the output power for the audio signal, T (s) is the temperature value generated by the current flowing into the voice coil according to the supplied power, R _TV is the thermal resistance of the voice coil, C _TV is the voice The heat capacity of the coil, R _TM may be the heat resistance of the permanent magnet, and C _TM may be the heat capacity of the permanent magnet. However, the present invention is not limited to this, and it is possible to calculate the temperature value of the voice coil using another known heat transfer model algorithm.

On the other hand, in Math 1, the initial values of the thermal resistance (R _TV ) and heat capacity (C _TV ) of the voice coil, and the thermal resistance (R _TM ) of the permanent magnet and heat capacity (C _TM ) of the permanent magnet are at room temperature (ambient temperature) It can be set on the basis of. That is, the temperature of the voice coil before the first power is supplied to the audio output device 100 may be the same as the normal temperature, and the thermal resistance of the voice coil may be calculated so that the temperature value of the voice coil equal to the normal temperature may be calculated. R _TV ) and the heat capacity (C _TV ) and the initial values of the heat resistance (R _TM ) of the permanent magnet and the heat capacity (C _TM ) of the permanent magnet may be set.

Then, when the first power is supplied, the controller 140 calculates the output power P (s) for outputting an audio signal according to the power supply. When the output power (P (s)) is calculated, the controller 140 calculates the calculated output power (P (s)), the thermal resistance (R _TV ) and heat capacity (C _TV ) of the preset voice coil, and the permanent magnet. By applying the thermal resistance (R _TM ) and the heat capacity (C _TM ) values of the permanent magnet to Equation 1 described above, it is possible to calculate the temperature (T (s)) of the voice coil by time.

That is, the voice coil is heated by the inflow current, and the temperature of the voice coil can be increased for a certain period of time, and since the specific time has elapsed, the amount of heat generated by the voice coil and the amount of discharge emitted to the outside become constant, so the temperature of the voice coil is constant Can be maintained. On the other hand, if the power supply to the audio output device 100 is blocked while the temperature of the voice coil is raised or maintained at a constant level, the temperature of the voice coil gradually decreases according to the time when the power supply is cut off.

Accordingly, when the power supply from the power supply unit 150 is cut off while the temperature (T (s)) of the voice coil for each hour is being calculated, the control unit 140 is based on a heat transfer model algorithm represented by Equation (1). The temperature of the voice coil is estimated to calculate the temperature value of the voice coil, and the temperature value of the voice coil calculated when the power is re-supplied is set as the initial temperature value.

In order to estimate the temperature of the voice coil, the controller 140 converts Equation 1 expressed in relation to the heat transfer model algorithm into a heat transfer model algorithm related to a discrete-time transfer function and converts the discrete. The initial temperature value of the voice coil may be set by calculating the temperature value of the estimated voice coil based on the heat transfer model algorithm related to the discrete-time transfer function.

Here, the discrete time transfer function may be implemented in the form of a second order IIR filter. In general, the II filter is structure-dependent, but includes two or four delay memories. Therefore, if the initial value of the delay memory is 0, the temperature of the voice coil may be equal to room temperature. However, as described above, after the power supply is cut off in a state where the temperature of the voice coil is high, the temperature of the voice coil at the time when the power is re-supplied may still remain high. Therefore, when estimating the temperature of the voice coil at the time when the power is re-supplied, it is very likely that a difference from the actual temperature of the voice coil will occur.

Therefore, as described above, when the power is re-supplied through the power supply unit 150, the control unit 140 uses the discrete time transfer function algorithm converted in relation to the heat transfer model algorithm to voice the time when power is re-supplied. The temperature value of the coil can be calculated, and the calculated temperature value can be set as an initial temperature value.

2 is a circuit diagram showing heat transfer of an audio output device according to an embodiment of the present invention, and FIG. 3 is an exemplary view showing a temperature change of a voice coil of an audio output device according to an embodiment of the present invention.

As shown in FIG. 2, when power is supplied to the audio output device 100, current may flow into the voice coil to generate heat in the voice coil A, and some of the heat generated in the A section is It is transferred to the permanent magnet B based on the heat resistance (R _TV ) and heat capacity (C _TV ) of the voice coil. In addition, a part of the heat transferred to the section B related to the permanent magnet may be released into the atmosphere C based on the thermal resistance (R _TV ) and heat capacity (C _TV ) of the permanent magnet. However, since the heat emitted from the voice coil (A) for a certain period of time is greater than the heat emitted to the atmosphere (C) through the permanent magnet (B), the temperature of the voice coil (A) may be continuously increased, and the voice coil ( The size of the heat emitted from the voice coil (A) and the heat emitted to the atmosphere (C) through the permanent magnet (B) from the point when the temperature of A) is increased may be constant.

That is, as illustrated in FIG. 3, when the first power is supplied to the audio output device 100, the temperature value of the voice coil is constantly raised to the a section and can be maintained constant in the a ′ section. That is, since the heat emitted from the voice coil during the time corresponding to the section a is larger than the heat emitted to the atmosphere through the permanent magnet, the temperature value of the voice coil during the section a may be continuously increased. In addition, since the heat generated from the voice coil and the heat emitted to the atmosphere through the permanent magnet from each other after the time corresponding to the section a have been equal to each other, the temperature of the voice coil after the time corresponding to the section a has passed is the calculated temperature. It can be maintained at the value T.

On the other hand, if the power supply to the audio output device 100 is cut off after the section a ', the temperature of the voice coil may be continuously decreased, and when the power is re-supplied after the power supply is cut off, the power is re-supplied The temperature value T 'estimated as the temperature of the voice coil of may be set as the initial temperature value of the voice coil.

As described above, when the initial temperature value of the voice coil is set, the control unit 140 adjusts the output level of the audio signal according to whether the temperature value of the voice coil calculated based on the set initial temperature value exists in a predetermined threshold section. You can determine the gain value to adjust.

According to an embodiment, when the temperature value of the pre-calculated voice coil exceeds a preset first threshold period, the controller 140 adjusts the output level of the audio signal to a first gain value lower than a preset reference gain value. Determine by gain value. Here, the first critical section may be a section in which the function of the voice coil can be safely maintained.

As described above, when the gain value for adjusting the output level for the audio signal is determined as the first gain value lower than the reference gain value, the control unit 140 is lower than the preset output level of the audio signal based on the first gain value. Adjust to the output level. Therefore, the output unit 130 outputs an audio signal at an output level lower than a preset output level. Accordingly, the temperature of the voice coil may drop below a preset first critical section.

On the other hand, when the temperature value of the pre-calculated voice coil is present in the preset heat-resistant limit section, the control unit 140 determines a second gain value lower than the first gain value as a gain value for adjusting the output level for the audio signal. Can be. Here, the heat-resistant limit section may be a temperature section above the melting point of the voice coil. In addition, the second gain value may be a value lowered to a size proportional to the temperature difference between the temperature value of the voice coil existing in the heat-resistant limit section and the highest temperature value of the first critical section.

Generally, the voice coil is coated for insulation. Therefore, when the temperature of the voice coil is maintained for a certain period of time in the heat resistance limit section, the function of the voice coil is lost by the combustion of the coating treated on the voice coil due to overheating. Therefore, when the temperature of the voice coil is present in the heat resistance limit section, the controller 140 has a size proportional to the temperature difference between the temperature value of the voice coil present in the heat resistance limit section and the highest temperature value in the first critical section. By determining the second gain value and lowering the output level of the audio signal, it is possible to reduce the temperature of the voice coil below the heat resistance limit section.

As described above, in the state where the audio signal is output at the output level adjusted based on the first or second gain value, the controller 140 periodically calculates the temperature value of the voice coil, and calculates the temperature value of the calculated voice coil. It is determined whether or not it is less than the predetermined second threshold section. Here, the second threshold section may be a section in which an audio sound quality is affected when an audio signal is output at a low output level.

Therefore, the control unit 140 periodically determines whether the temperature value of the detected voice coil is less than a preset second threshold period, and if the temperature value of the voice coil exists between the first to second threshold periods, the predetermined value is determined. The first or second gain value is maintained. On the other hand, as a result of the determination, if the temperature value of the pre-detected voice coil is less than the second threshold section, the control unit 140 adjusts the third gain value higher than the predetermined first gain value to adjust the output level of the audio signal. Decide. Here, it is preferable that the third gain value is changed to a width smaller than the change width of the first gain value. Accordingly, when the temperature value of the voice coil that is previously detected is less than the second threshold period, the control unit 140 determines the third gain value with a width that has a smaller change width than the first gain value.

When the third gain value is determined, the control unit 140 adjusts the output level higher than the preset output level of the audio signal based on the predetermined third gain value. Accordingly, the output unit 130 may output the audio signal at an output level higher than the previous output level, so that the temperature of the voice coil may rise above a predetermined second threshold period. In addition, the output unit 130 outputs an audio signal at an output level adjusted to a third gain value determined as a width having a smaller change width than the first gain value, so that the temperature of the voice coil is a stabilization section for a long time. It can be maintained within a critical section. In addition, by outputting an audio signal at an output level adjusted to a third gain value determined by a width having a smaller change width than the first gain value, it is possible to minimize a problem that may affect the audio quality due to the gain change.

4 is an exemplary diagram for determining a gain value according to a temperature rise of a voice coil in an audio output device according to an embodiment of the present invention.

As shown in (a) of FIG. 4, when power is supplied to the audio output device 100 and current flows into the voice coil, the temperature of the voice coil may rise in proportion to the time when the current flows. For example, when power is continuously supplied while the temperature of the voice coil at the time when power is supplied to the audio output device 100 is the same as the standby temperature, the temperature of the voice coil may rise to a temperature higher than the standby temperature.

That is, the temperature of the voice coil may rise to a preset heat-resistant limit section 410, and when the temperature of the voice coil rises to the heat-resistant limit section 410, the heat generation amount of the voice coil and the amount of discharge emitted to the outside become constant and the voice coil The temperature of can be kept constant. Accordingly, the control unit 140 continuously monitors the temperature change of the voice coil to determine whether the temperature of the voice coil exceeds a first threshold period preset as a stabilization period. That is, when power is supplied through the power supply unit 150, the control unit 140 calculates the temperature value of the voice coil in units of time using a preset heat transfer model algorithm, and the calculated temperature value of the voice coil is preset. It may be determined whether or not the first threshold period is exceeded.

As a result of the determination, when the temperature value of the voice coil exceeds a preset first threshold period, the controller 140 determines a gain value for adjusting the output level of the audio signal as a first gain value lower than a preset reference gain value. .

That is, as shown in FIG. 4B, the preset reference gain value may be 0 dB. Accordingly, when the temperature value of the voice coil at a time point exceeding the preset first threshold period is detected, the control unit 140 may determine a first gain value in which the preset reference gain value is reduced by α magnitude from 0 dB. As described above, when the first gain value is determined, the control unit 140 adjusts to an output level lower than a preset output level of the audio signal based on the determined first gain value. Accordingly, the output unit 130 outputs an audio signal at an output level lower than the preset output level, so that the temperature of the voice coil can be reduced to less than or equal to the preset first threshold period.

On the other hand, when the temperature of the voice coil falls below a predetermined first threshold period, the control unit 140 calculates the temperature value of the voice coil in units of time, as described above, and calculates the temperature of the voice coil. If the value is less than or equal to the predetermined first threshold period, it is possible to maintain the adjusted output level in relation to the predetermined first gain value. Accordingly, the output unit 130 may output an audio signal at an output level adjusted with respect to the predetermined first gain value.

5 is an exemplary diagram for determining a gain value according to a decrease in temperature of a voice coil in an audio output device according to an embodiment of the present invention.

As shown in (a) of FIG. 5, when the audio signal is output at a low output level adjusted with respect to the predetermined first gain value, the temperature of the voice coil may drop. Accordingly, the control unit 140 continuously monitors the temperature change of the voice coil to determine whether the temperature of the voice coil is lowered below a preset second threshold section as a section in which audio sound quality is affected. That is, the controller 140 may calculate the temperature value of the voice coil in units of time using a preset heat transfer model algorithm, and determine whether the calculated temperature value of the voice coil is less than a preset second threshold section. .

As a result of the determination, if the temperature value of the voice coil exists or is less than or equal to the preset second threshold section, the controller 140 sets a gain value (hereinafter referred to as a third gain value) higher than the preset first gain value. Determine the gain value to adjust the output level.

That is, as shown in (b) of FIG. 5, the controller 140 determines a third gain value increased by α by a predetermined first reference value as a gain value for adjusting the output level of the audio signal. As described above, when the third gain value is determined, the control unit 140 adjusts the output level higher than a preset output level of the audio signal based on the determined third gain value. Accordingly, the output unit 130 outputs the audio signal at an output level higher than the preset output level, so that the temperature of the voice coil becomes high, so that the temperature can be maintained higher than the preset second threshold section.

6 is an exemplary view showing a gain value changed according to a temperature change of a voice coil in an audio output device according to an embodiment of the present invention.

As shown in FIG. 6, when the temperature of the voice coil exceeds the first threshold period, a gain value reduced by α magnitude based on a preset reference gain value may be determined as a gain value for adjusting the output level of the audio signal. have. If the temperature of the voice coil while the audio signal is being output with the output level adjusted based on the gain value still exceeds the first threshold period, the gain value further reduced by the amount of α based on the predetermined gain value It may be determined as a gain value for adjusting the output level of the audio signal.

If the temperature of the voice coil while the audio signal is being output is lower than the first critical section based on the gain value further reduced by the α size, the gain value is further reduced by the α size. Thus, the adjusted output level can be maintained. If the adjusted output level is maintained based on the gain value further reduced by α magnitude, and the temperature of the voice coil during the audio signal output falls to the second critical section, the gain value increased by β magnitude outputs the audio signal. It can be determined by the gain value for adjusting the level. Here, it is preferable that the change width of β is smaller than the change width of α. For example, when the temperature of the voice coil is dropped below the first threshold section, the gain value for adjusting the output level of the audio signal is -0.5 dB based on the preset reference gain value of 0 dB. Can be In addition, when the temperature of the voice coil is raised above the second threshold section, the gain value for adjusting the output level of the audio signal may be a gain value of +0.25 dB increased based on the predetermined gain value.

As described above, according to the temperature change of the voice coil, by adjusting the width at the time of decreasing and increasing the gain value for adjusting the output level of the audio signal, not only the change in gain is minimized, but also the voice coil The temperature may be maintained continuously in the first critical section, which is the stabilization section.

7 is a first exemplary view for determining a gain value according to a temperature rise degree of a voice coil in an audio output device according to an embodiment of the present invention, and FIG. 8 is an audio output device according to another embodiment of the present invention This is a second example of determining a gain value according to the degree of temperature rise of the voice coil.

As shown in (a) of FIG. 7, when the temperature of the voice coil is gradually increased for t ′ time and is between the heat-resistant limit section 410 and the first threshold section 420, the output level of the audio signal is adjusted The gain value for doing so can be reduced step by step. That is, when the temperature of the voice coil is gradually increased during the t 'time and is between the heat-resistant limit section 410 and the first threshold section 420, as shown in FIG. 7B, the output level of the audio signal The gain value for adjusting can be determined as a gain value that is gradually reduced by x size based on a reference gain value of 0 dB.

As described above, if the gain value for adjusting the output level of the audio signal is reduced stepwise, the output level of the audio signal can be adjusted stepwise based on the gain value reduced in each step. In addition, by outputting the audio signal at the output level adjusted in steps, the temperature of the voice coil is gradually lowered.

On the other hand, as shown in Figure 8 (a), when the temperature of the voice coil is rapidly increased within a t '' time faster than the t 'time of Figure 7 (a) reaches the heat resistance limit section 410 near , The gain value for adjusting the output level of the audio signal can be rapidly reduced.

That is, when the temperature of the voice coil is rapidly increased within a time t '' time faster than the t 'time and is located in the heat resistance limit section 410, as shown in (b) of FIG. 8, the output level of the audio signal is increased. The gain value for adjustment may be determined as a gain value reduced to x 'size based on the reference gain value 0 dB. Here, the size of 'x' may be a size proportional to the temperature difference between the temperature value of the voice coil existing in the heat-resistant limit section 410 and the highest temperature value of the preset first critical section.

As described above, when the temperature of the voice coil rises rapidly to the heat-resistant limit section 410, by adjusting the output level of the audio signal based on the gain value reduced to x 'size based on the reference gain value of 0 dB, The temperature can be quickly lowered below the heat resistance limit section 410.

So far, each configuration of the audio output device 100 for adjusting the temperature of the voice coil by adjusting the gain value for adjusting the output level of the audio signal according to the temperature change of the voice coil according to the present invention has been described in detail. Hereinafter, an audio output method of the audio output device 100 according to the present invention will be described in detail.

9 is a flowchart of an audio output method of an audio output device according to an embodiment of the present invention.

As shown in FIG. 9, the audio output device 100 sets an initial temperature value of the voice coil using a preset heat transfer model algorithm (S910). Here, the initial temperature value may be a temperature value for the voice coil at the time when power is re-supplied to the audio output device 100 after the power initially supplied to the audio output device 100 is cut off. In addition, the heat transfer model algorithm is an algorithm for calculating the temperature value of the voice coil, and since it has been described in detail above, the detailed description will be omitted below.

That is, when the first power is supplied, the audio output device 100 calculates the temperature value of the voice coil using a heat transfer model algorithm. Thereafter, when the power supply is cut off, the audio output device 100 may calculate the temperature value of the voice coil corresponding to the time when the power supply is cut off based on the heat transfer model algorithm represented by Equation (1), and the power supply is The temperature value of the voice coil calculated at the time of re-supply can be set as the initial temperature value.

As described above, when external power is supplied while the initial temperature value of the voice coil is set, the audio output device 100 calculates the temperature value of the voice coil using the above-described heat transfer model algorithm (S920). Thereafter, the audio output device 100 determines a gain value for adjusting the output level of the audio signal according to the calculated temperature value of the voice coil, and adjusts the output level of the audio signal based on the determined gain value (S930) . Specifically, the audio output device 100 may determine a gain value for adjusting the output level of the audio signal according to whether the temperature value of the voice coil calculated based on the preset initial temperature value exists in the preset threshold section. In addition, the output level of the audio signal can be adjusted based on the gain value.

When the output level of the audio signal is adjusted, the audio output device 100 outputs the audio signal based on the adjusted output level (S940). As described above, the audio output device 100 according to the present invention determines the gain value for adjusting the output level of the audio signal according to the change in the internal temperature of the voice coil that is generated by the current flowing into the voice coil, and thus the temperature of the voice coil. Can be maintained at a certain level.

Hereinafter, a method of determining a gain value for adjusting an output level of an audio signal according to a temperature change of a voice coil in the audio output device 100 according to the present invention will be described in detail.

10 is a flowchart of a method for determining a gain value according to a temperature rise of a voice coil in an audio output device according to an embodiment of the present invention.

As illustrated in FIG. 10, the audio output device 100 periodically calculates the temperature value of the voice coil using a heat transfer model algorithm (S1010). When the temperature value of the voice coil is calculated, the audio output device 100 determines whether the calculated temperature value of the voice coil exceeds a predetermined first threshold period (S1020). Here, the first critical section may be a section in which the function of the voice coil can be safely maintained.

As a result of the determination, if the temperature value of the voice coil does not exceed the preset first threshold period, the audio output device 100 may output the audio signal at the output level of the preset audio signal. On the other hand, when it is determined that the temperature value of the voice coil exceeds a preset first threshold period, the audio output device 100 determines whether the temperature value of the voice coil is within the heat resistance limit period (S1030). Here, the heat-resistant limit section may be a temperature section above the melting point of the voice coil.

As a result of the determination, when the temperature value of the voice coil is within the heat-resistant limit section, the audio output device 100 determines a first gain value lower than a preset reference gain value as a gain value for adjusting the output level of the audio signal (S1040). ). That is, when the false value of the voice coil is between the first threshold period and the heat resistance limit period, the audio output device 100 uses a first gain value lower than a preset reference gain value as a gain value for adjusting the output level of the audio signal. Can decide.

On the other hand, if it is determined in step S1030 that the temperature value of the voice coil is in the heat resistance limit section, the audio output device 100 sets the output level for the audio signal to a second gain value lower than the first gain value determined in step S1040. It is determined as a gain value for adjustment (S1050). As described above, when the gain value for adjusting the audio output level is determined as the first or second gain value through step S1040 or step S1050, the audio output device 100 performs an audio signal based on the first or second gain value. Adjusts the output level of and outputs an audio signal with the adjusted audio output level (S1060).

As described above, when the temperature of the voice coil is present in the first threshold section or the heat resistance limit section, the audio output device 100 according to the present invention lowers the gain value for adjusting the output level of the audio signal from a preset gain value. By determining the first or second gain value, it can be adjusted to an output level lower than a preset output level of the audio signal. Therefore, the audio output device 100 may drop the temperature of the voice coil below the first or heat resistance limit period by outputting an audio signal at an output level adjusted based on the first or second gain value.

11 is a flowchart of a method for determining a gain value according to a decrease in temperature of a voice coil in an audio output device according to an embodiment of the present invention.

As illustrated in FIG. 11, when the audio output device 100 adjusts the output level of the audio signal based on the gain value determined through FIG. 10 described above, the temperature of the voice coil may gradually decrease. Therefore, the audio output device 100 periodically calculates the temperature value of the voice coil by using the above-described heat transfer model algorithm while the audio signal is being output at the output level adjusted based on the predetermined gain value (S1110). ). Thereafter, the audio output device 100 determines whether the calculated temperature value of the voice coil falls below a preset second threshold section (S1120). Here, the second threshold section may be a section in which an audio sound quality is affected when an audio signal is output at a low output level.

As a result of the determination, when the temperature value of the voice coil is higher than the preset second threshold period, the audio output device 100 maintains the predetermined gain value. That is, when the temperature value of the voice coil is present between the first and second critical periods, the audio output device 100 maintains a predetermined gain value. On the other hand, as a result of the determination, when the temperature value of the voice coil is lower than the preset second threshold period, the audio output device 100 determines a third gain value higher than the predetermined gain value (S1130).

Here, it is preferable that the third gain value is changed to a width smaller than the predetermined change width of the gain value. For example, the predetermined gain value may be a gain value reduced by -0.5 dB based on 0 dB, which is a preset reference gain value. In this case, the third gain value may be a gain value increased by +0.25 dB based on a predetermined gain value.

Thereafter, the audio output apparatus 100 adjusts the output level of the audio signal based on the predetermined third gain value, and outputs the audio signal at the adjusted output level (S1140). Accordingly, the audio output device 100 outputs an audio signal at an output level higher than the previous output level, so that the temperature of the voice coil may rise above a predetermined second threshold period. As described above, according to the temperature change of the voice coil, by adjusting the width at the time of decreasing and increasing the gain value for adjusting the output level of the audio signal, not only the change in gain is minimized, but also the voice coil The temperature may be maintained continuously in the first critical section, which is the stabilization section.

So far, the present invention has been focused on the preferred embodiments.

In the above, preferred embodiments of the present invention have been illustrated and described, but the present invention is not limited to the specific embodiments described above, and it is usually in the technical field to which the present invention belongs without departing from the gist of the present invention claimed in the claims. It is of course possible to perform various modifications by a person having knowledge of, and these modifications should not be individually understood from the technical idea or prospect of the present invention.

100: audio output device 110: input unit
120: signal processing unit 130: output unit
140: control unit 150: power supply

Claims (18)

In the audio output method of the audio output device,
When power is supplied, calculating a temperature value of the voice coil of the audio output device using a heat transfer model algorithm;
Calculating a first temperature value of the voice coil using an algorithm converted from the heat transfer model algorithm when power is turned off and then re-supplying, and setting the first temperature value as an initial temperature value of the voice coil;
Adjust the output level for the audio signal by determining the gain value for adjusting the output level of the audio signal according to whether the second temperature value of the voice coil calculated based on the set initial temperature value exists in the critical section To do; And
Outputting an audio signal whose output level is adjusted;
Audio output method comprising a. delete According to claim 1,
The initial temperature value,
The audio output method characterized in that it is a temperature value for the voice coil at the time when power is re-supplied to the audio output device after the first supplied power is cut off. According to claim 1,
The heat transfer model algorithm is derived from [Equation 1] below.
Audio output method.
[Equation 1]
T (s) / P (s) = (R _TV R _TM (C _TV + C _TM ) s + (R _TV + R _TM )) / ((R _TV R _TM C _TV C _TM ) s ² + (R _TV C _TV + R _TM C _TM ) s + 1),
Here, P (s) is the output power for outputting the audio signal, T (s) is the temperature value of the voice coil, R _TV is the thermal resistance of the voice coil, C _TV is the heat capacity of the voice coil, R _TM is The thermal resistance of the permanent magnet, C _TM represents the heat capacity of the permanent magnet. According to claim 1,
The adjusting step,
Determining whether a temperature value of the voice coil exists in a preset first critical section; And
Determining a first gain value lower than a preset reference gain value as a gain value for adjusting the output level of the audio signal when the predetermined first threshold period is exceeded;
Audio output method comprising a. The method of claim 5,
The determining step,
When the temperature value of the voice coil is present in a preset heat-resistant limit section, an audio output method characterized by determining a second gain value lower than the first gain value as a gain value for adjusting the output level for the audio signal. . The method of claim 6,
The heat-resistant limit section,
The temperature range above the melting point of the voice coil,
The second gain value is,
The audio output method, characterized in that the temperature value of the voice coil existing in the heat-resistant limit section is reduced to a size proportional to a temperature difference between the highest temperature value of the first critical section. The method of claim 6,
The calculating step,
The temperature of the voice coil is continuously measured,
The adjusting step,
Determining whether the temperature value of the voice coil is less than a preset second threshold period while an audio signal is output at an output level adjusted based on the first or second gain value; And
As a result of the determination, if the temperature value of the voice coil is between the first to second threshold sections, the first or second gain value is maintained, and if it is less than the second threshold section, than the first gain value Determining a high third gain value as a gain value for adjusting the output level of the audio signal;
Audio output method further comprising a. The method of claim 8,
The third gain value,
The audio output method, characterized in that changed to a width smaller than the change width to the first gain value. An input unit that receives an audio signal;
A signal processor that performs signal processing on the audio signal;
An output unit that outputs a signal-processed audio signal;
When power is supplied, a first temperature value of a voice coil is calculated using a heat transfer model algorithm, and when the power is cut off and re-supplied, an initial temperature value is calculated based on the first temperature value, and the heat transfer model A gain value for calculating a second temperature value of the voice coil based on the initial temperature value using an algorithm, and adjusting the level of the audio signal based on whether the second temperature value exists in a predetermined threshold section A control unit for acquiring and adjusting an output level of the audio signal based on the obtained gain value;
Audio output device comprising a. delete The method of claim 10,
The initial temperature value,
Audio output device characterized in that it is a temperature value for the voice coil at the time when power is re-supplied to the audio output device after the first supplied power is cut off. The method of claim 10,
The heat transfer model algorithm is derived from the equation
Audio output device.
[Equation 1]
T (s) / P (s) = (R _TV R _TM (C _TV + C _TM ) s + (R _TV + R _TM )) / ((R _TV R _TM C _TV C _TM ) s ² + (R _TV C _TV + R _TM C _TM ) s + 1),
Here, P (s) is the output power for outputting the audio signal, T (s) is the temperature value of the voice coil, R _TV is the thermal resistance of the voice coil, C _TV is the heat capacity of the voice coil, R _TM is The thermal resistance of the permanent magnet, C _TM represents the heat capacity of the permanent magnet. The method of claim 10,
The control unit,
And when the temperature value of the voice coil exceeds a preset first threshold period, a first gain value lower than a preset reference gain value is determined as a gain value for adjusting the output level of the audio signal. . The method of claim 14,
The control unit,
When the temperature value of the voice coil is present in a preset heat-resistant limit section, an audio output device characterized by determining a second gain value lower than the first gain value as a gain value for adjusting the output level for the audio signal. . The method of claim 15,
The heat-resistant limit section,
The temperature range above the melting point of the voice coil,
The second gain value is,
Audio output device characterized in that the value reduced to a size proportional to the temperature difference between the temperature value of the voice coil and the highest temperature of the first critical section existing in the heat-resistant limit section. The method of claim 15,
The control unit,
In a state in which an audio signal is output at an output level adjusted based on the first or second gain value, the temperature value of the voice coil is calculated to determine whether or not it is less than a preset second threshold period,
If the temperature value of the voice coil is between the first and second threshold periods, the first or second gain value is maintained, and if it is less than the second threshold period, a third gain higher than the first gain value And determining a value as a gain value for adjusting the output level of the audio signal. The method of claim 17,
The third gain value,
The audio output device, characterized in that changed to a width smaller than the change width to the first gain value.

Images