JPH05127787A - Circuit and method for monitoring battery voltage - Google Patents

Abstract

PURPOSE:To not only prevent the overdischarge of the power source battery and prolong the life of the power source battery, but also make the drivable time by the power source battery long by placing a battery voltage detecting function in effective operation even in low-power-consumption mode. CONSTITUTION:A voltage comparator IC2 detects a drop in the output voltage of the battery BT1 according to the output voltage of the battery BT1 and the output voltage of a voltage stabilizing circuit A1. A microprocessor IC1 opens an AND gate IC3 and then enters the low-power-consumption mode. Once the voltage comparator IC2 outputs a detection signal to a reset terminal START through the AND gate IC3, the microprocessor IC1 resets the low-power- consumption mode and turns OFF an FETQ1. Then the microprocessor IC1 enters the low-power-consumption mode again.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a power supply control circuit mounted in a portable OA device (for example, a personal computer, a word processor, etc.) which can use a battery as a driving power supply, and more particularly to prevent over-discharge of the battery The present invention relates to a battery voltage monitoring circuit that operates.

[0002]

2. Description of the Related Art Portable OA equipment, which has been widely used in recent years, is provided with a battery voltage monitoring circuit in order to prevent over-discharge of a battery used as a driving power source. The battery voltage monitoring circuit cuts off the supply of power to the inside of the OA equipment when detecting the voltage drop of the battery. In order to realize this function, an A / D installed inside the microprocessor (controller) that controls the output of the power supply and the charge control
A D converter and software are used.

FIG. 6 shows a battery voltage monitoring circuit provided in a conventional office automation equipment. The output of the battery BT ₅₁ is the voltage stabilization circuit A ₅₁ and the FET (Field-Effect Trangistor) Q.
It is supplied to the memory holding circuit via ₅₁ . FET Q
The conduction of ₅₁ , that is, the power supply to the memory holding circuit is controlled by the microprocessor IC _{51 with the} configuration described below.

That is, in the FET Q ₅₁ , the source terminal connected to the output of the voltage stabilizing circuit A ₅₁ is a resistor R _53.
Is connected to the gate terminal via. The gate terminal is
Output terminal of microprocessor IC ₅₁ via resistor R ₅₄
Connected to OUT ₅₁ . The microprocessor IC ₅₁ is
Set the potential of the output terminal OUT ₅₁ to High level,
Cut off the conduction of FET Q ₅₁ .

The output voltage of the battery BT ₅₁ is divided by a resistor R ₅₁ and a variable resistor R ₅₂ connected in series and supplied to an A / D converter incorporated in the microprocessor IC ₅₁ . .. As a result, the microprocessor IC ₅₁ sets the potential of the output terminal OUT ₅₁ to Hi based on the digital value output from the A / D converter.
Set to gh level.

The operation flow of the battery voltage monitoring circuit having the above configuration will be described with reference to FIG. First, the microprocessor IC ₅₁ sets the potential of the output terminal OUT ₅₁ to Low (step 51: the step below is represented by S).
As a result, the FET Q ₅₁ becomes conductive, and the battery BT ₅₁
Power is supplied to the memory holding circuit. Next, S5
2, the microprocessor IC ₅₁ is a divided voltage battery
Input the output voltage of BT ₅₁ , and perform A / D conversion. In S53,
It is determined whether the output voltage of the battery BT ₅₁ is below the specified level. If the output voltage exceeds the specified level, the process returns to S52.

On the other hand, when the output voltage falls below the specified level,
The microprocessor IC ₅₁ sets the potential of the output terminal OUT ₅₁ to H level.
The high level is set (S54). By this, F
Since the ETQ ₅₁ is no longer conductive, the power supply to the memory holding circuit is cut off, and the microprocessor IC ₅₁ operates in the low current consumption mode (sometimes called the standby mode).
(S55). As a result, over-discharge of the battery BT ₅₁ is prevented.

[0008]

However, in the above-mentioned conventional configuration, when the microprocessor IC ₅₁ shifts to the low current consumption mode due to the stop of the operation of the load side of the OA equipment or the like, the A / D conversion function is I have to stop. That is, in the low current consumption mode, since the battery voltage detection function does not work, the microprocessor IC ₅₁ cannot control the conduction of the FET Q ₅₁ . Therefore, even if the output voltage of the battery BT ₅₁ drops during the period of the low current consumption mode, the microprocessor IC ₅₁ shuts off the power supply to the memory holding circuit and outputs the output of the battery BT ₅₁ . You will be out of control. As a result, there is a problem that the battery BT ₅₁ may be over-discharged.

On the other hand, when the microprocessor IC _{51 is set} to the normal operation mode in order to activate the battery voltage detecting function, the power consumption increases to several mW to several tens mW. Therefore, the battery BT ₅₁ is discharged more quickly, and the duration of the normal operation mode is shortened.

The object of the present invention is to solve the above problems.
It is an object of the present invention to provide a battery voltage monitoring circuit and a battery voltage monitoring method capable of preventing the battery from being over-discharged by operating the battery voltage detection function even in the low current consumption mode.

[0011]

In order to solve the above-mentioned problems, a battery voltage monitoring circuit according to the invention of claim 1 detects the voltage of a power supply battery, and when the voltage falls below a specified level, In the battery voltage monitoring circuit that shuts off the output of the power battery, (1) Compare the voltage of the power battery with the specified level,
A comparing means (for example, a voltage comparator) that detects that the voltage is below a specified level and outputs a detection signal; and (2)
Output control means for shutting off the output of the power supply battery (for example,
(3) a mode switch for setting the output control means to the low current consumption mode and canceling the low current consumption mode based on the detection signal during the detection period in the comparison means. (4) The output control means shuts off the output of the power supply battery based on the release of the low current consumption mode.

In order to solve the above-mentioned problems, a battery voltage monitoring method according to a second aspect of the present invention includes (1) after turning on the battery voltage monitoring function in the normal operation mode, (2)
The normal operation mode is switched to the low current consumption mode, and (3) the voltage of the power supply battery falls below the specified level.
After releasing the above low current consumption mode, (4) controlling the output of the power supply battery, (5) turning off the battery voltage monitoring function, and (6) switching the normal operation mode to the low current consumption mode again. It has a feature.

[0013]

According to the structure of claim 1, the comparison means compares the voltage of the power supply battery with the specified level during the period when the output control means is set to the low current consumption mode. The mode switching means releases the low current consumption mode of the output control means based on the detection signal (external signal) indicating that the voltage has dropped below the specified level. As a result, the output control means is activated, and necessary processing such as shutting off the output of the power supply battery can be performed.

Therefore, even during the setting period of the low current consumption mode, it is detected that the voltage of the power supply battery has fallen below the specified level, so that overdischarge of the power supply battery is prevented and the life of the power supply battery is extended. Not only can this be done, but the drivable time of the power supply battery can also be lengthened.

According to the structure of claim 2, after the battery voltage monitoring function is turned on in the normal operation mode,
Since the normal operation mode is switched to the low current consumption mode,
The battery voltage detection function works effectively even in the low current consumption mode. In addition, since the low current consumption mode is canceled and the normal operation mode is restored based on the voltage of the power supply battery falling below the specified level, the output control of the power supply battery and the battery voltage monitoring function are promptly performed. OFF control can be performed. Furthermore, after the battery voltage monitoring operation is completed, the mode is switched to the low current consumption mode again, so that the drivable time of the power supply battery can be lengthened.

[0016]

DESCRIPTION OF THE PREFERRED EMBODIMENTS The following will describe one embodiment of the present invention with reference to FIGS.

FIG. 1 shows an example of the configuration of the battery voltage monitoring circuit. The output of the battery BT ₁ is connected to a memory holding (memory backup) circuit (not shown) via a voltage stabilizing circuit A ₁ and a FET (Field-Effect Trangistor) Q ₁ . In the FET Q ₁ , the source terminal connected to the output of the voltage stabilizing circuit A ₁ is connected to the gate terminal via the resistor R ₃ , and the gate terminal is the microprocessor IC.
It is connected to the _first output terminal OUT _1. This allows FE
The conduction of T Q ₁ , that is, the power supply to the memory holding circuit is controlled by the voltage level of the output terminal OUT ₁ applied to the gate terminal. The drain terminal of the FET Q ₁ is connected to the memory holding circuit described above.

The output voltage of the battery BT ₁ is divided by a resistor R ₁ and a variable resistor R ₂ connected in series and supplied to the (−) input terminal of the voltage comparator IC ₂ . on the other hand,
The output of the voltage stabilizing circuit A ₁ is a resistor R ₄ connected in series.
The voltage is divided by the resistor R ₅ and supplied to the (+) input terminal of the voltage comparator IC ₂ . In addition, voltage comparator IC
_The specified level detected by ₂ is arbitrarily set by the values of the resistors R ₁ and R ₂ .

The output of the voltage comparator IC ₂ is the AND gate IC
₃ is connected to one input terminal. AND gate IC
The other input terminal of ₃ is connected to the output terminal OUT ₂ of the microprocessor IC ₁ , and the output of the AND gate IC ₃ is connected to the return terminal START of the microprocessor IC ₁ . As a result, the AND gate IC ₃ is opened / closed by the potential of the output terminal OUT ₂ .

The operation flow of the battery voltage monitoring circuit having the above structure will be described with reference to FIG. First, the microprocessor IC ₁ sets the potential of the output terminal OUT ₁ to the Low level (step 1: the step below is represented by S). As a result, the FET Q ₁ becomes conductive, and power is supplied from the battery BT ₁ to the memory holding circuit. Next, in S2, the microprocessor IC ₁ outputs the output terminal OUT ₂
To the high level. This opens the AND gate IC ₃ , so that the output of the voltage comparator IC ₂ is
It is sent to the return terminal START via the gate IC ₃ . This is nothing but the fact that the battery voltage monitoring circuit is turned on.

After that, the microprocessor IC ₁ shifts to the low current consumption mode (S3). Therefore, during the battery voltage monitoring period, the power consumption of microprocessor IC ₁ is
It can be suppressed to several tens to several hundreds μW. In this state, if the output the voltage of the battery BT ₁ is defined level or higher, the voltage comparator IC ₂ (-) since the potential of the input terminal (+) higher than the potential of the input terminal, the voltage comparator IC ₂ outputs Is L
ow level. Therefore, the potential of the recovery terminal START also becomes Low level, and the microprocessor IC ₁ continues to hold the low current consumption mode.

However, when the output voltage of the battery BT ₁ becomes lower than the specified level, the potential of the (−) input terminal becomes (+).
Since it becomes lower than the potential of the input terminal, the output of the voltage comparator IC ₂ becomes High level. Therefore, the recovery terminal STAR
Since the potential of T 2 also becomes High level, the microprocessor IC ₁ returns to the normal operation mode (S5).

At S6, the microprocessor IC ₁
The potential of the output terminal OUT ₁ is set to High level. As a result, the gate terminal of the FET Q ₁ becomes High level, and the conduction of the FET Q ₁ is cut off. That is, the power supply to the memory holding circuit is cut off. Further, the microprocessor IC ₁ sets the potential of the output terminal OUT ₂ to L at S7.
Since it is set to the ow level, the AND gate IC ₃ is closed. This is nothing but the fact that the battery voltage monitoring circuit is turned off. After the processes of S6 and S7 described above, the microprocessor IC ₁ shifts to the low current consumption mode again (S8).

As described above, when the output voltage of the battery BT ₁ falls below the specified level, the power supply to the memory holding circuit is cut off by the control operation of the microprocessor IC ₁ . As a result, the battery BT ₁ is prevented from being over-discharged. In addition, during the period when the battery voltage monitoring circuit is in the ON state and after the battery voltage monitoring operation is completed, the microprocessor IC
_{Since 1} becomes the low current consumption mode, it is possible to extend the drivable time of the OA equipment by the battery BT ₁ .

In the above embodiment, the case where the power supply to the memory holding circuit is cut off is shown, but the present invention is not limited to this, and (1) the output voltage of the battery BT ₁ is lowered. Emits a warning sound to inform the user that (2)
In the case of a device that can be equipped with a plurality of batteries, various processes such as battery switching can be set by an electronic switch.

Another embodiment of the present invention will be described below with reference to FIGS. 3 and 4. In addition,
For convenience of explanation, members having the same functions as those of the members shown in the drawings of the above-described embodiments are designated by the same reference numerals, and the description thereof will be omitted.

The battery voltage monitoring circuit of the present embodiment is equivalent to the first battery voltage detecting section composed of the resistor R ₁ , the variable resistor R ₂ , the voltage comparator IC ₂ and the AND gate IC ₃ of the above embodiment. The second battery voltage detection unit having the above configuration is provided. That is, as shown in FIG. 3, in the second battery voltage detecting unit, the output voltage of the battery BT ₁ is newly divided by the resistor R ₈ and the variable resistor R ₉ connected in series, and the second voltage comparison is performed. vessels IC ₅ (-) is supplied to the input terminal. On the other hand, the output of the voltage stabilizing circuit A ₁ divided by the resistors R ₄ and R ₅ connected in series as in the above embodiment is supplied to the (+) input terminal of the voltage comparator IC ₅ . .. In the present embodiment, the second voltage comparator
The voltage detected by IC ₅ is the first voltage comparator
It is set higher than the voltage detected by IC ₂ .

Further, the output of the voltage comparator IC ₅ is connected to one input terminal of the second AND gate IC ₆ and
The other input of gate IC ₆ is a microprocessor IC
Connected to the output terminal OUT _{3 of 1} . The outputs of the first AND gate IC ₃ and the second AND gate IC ₆ are connected to the respective input terminals of the OR gate IC ₄ . The output of the OR gate IC ₄ is the microprocessor IC ₁
It is connected to the recovery terminal START of. This makes it possible to detect the decrease in the output voltage of the battery BT ₁ in two stages.

The output of the voltage stabilizing circuit A ₁ is connected to the output terminal OUT ₄ of the microprocessor IC ₁ via the resistor R ₇ and the light emitting diode LED ₁ . FET Q ₁ that turns ON / OFF the power supply to the memory holding circuit
In, the gate terminal is connected to the output terminal OUT ₁ of the microprocessor IC ₁ via the resistor R ₆ .

The operation flow of the battery voltage monitoring circuit having the above configuration will be described with reference to FIG. First, the microprocessor IC ₁ sets the potential of the output terminal OUT ₁ to the Low level (S11). As a result, the FET Q ₁ becomes conductive, and power is supplied from the battery BT ₁ to the memory holding circuit. Next, in S12, the microprocessor IC ₁
The potential of the output terminal OUT ₄ is set to High level. As a result, the light emitting diode LED ₁ is turned off. continue,
In S13, the microprocessor IC ₁ sets the potential of the output terminal OUT ₃ to the High level. This allows the voltage comparator
The output of IC ₅ is AND gate IC ₆ and OR gate IC ₄
Sent to the return terminal START via. This monitoring circuit for a first predetermined level detected by the voltage comparator IC ₅ to the output voltage of the battery BT ₁ (hereinafter, IC ₅
It is nothing but the ON state of the battery voltage monitoring circuit on the side).

Thereafter, the microprocessor IC ₁ shifts to the low current consumption mode (S14). In this state, if the output voltage of the battery BT ₁ is equal to or higher than the first specified level, the potential of the (−) input terminal of the voltage comparator IC ₅ is higher than that of the (+) input terminal. The output of IC ₅ becomes Low level. On the other hand, voltage comparator
The monitoring circuit for the second specified level detected by IC ₂ (hereinafter referred to as the battery voltage monitoring circuit on the IC ₂ side) is still off. Therefore, since the outputs of the AND gate IC ₃ and the AND gate IC ₆ both become Low level, the potential of the restoration terminal START also becomes Low level.
As a result, the microprocessor IC ₁ maintains the low current consumption mode.

However, when the output voltage of the battery BT ₁ becomes lower than the first specified level, the potential of the (−) input terminal of the voltage comparator IC ₅ becomes lower than the potential of the (+) input terminal, so that the voltage comparator IC The output of ₅ becomes High level. Therefore, the high level output of the AND gate IC ₆ is OR
It is supplied to the return terminal START via the gate IC _4, and the potential of the return terminal START becomes High level. As a result, the microprocessor IC ₁ returns to the normal operation mode (S16).

In step S17, the microprocessor IC is
₁ sets the potential of the output terminal OUT ₄ to the Low level. Thus, current flows through the light emitting diodes LED _1, the light emitting diode LED ₁ is lit as a warning lamp, battery BT ₁ to the user
Notify that the voltage has dropped.

Further, the microprocessor IC ₁ sets the potential of the output terminal OUT ₃ to the Low level and the AND gate IC ₆
Is closed, the battery voltage monitoring circuit on the IC ₅ side is turned off (S18), the potential of the output terminal OUT ₂ is set to the high level, the AND gate IC ₃ is opened, and the battery voltage monitoring circuit on the IC ₂ side is turned on. (S19). After this processing, the microprocessor IC ₁ shifts to the low current consumption mode again (S20). The light emitting diode LED ₁ continues to light to inform the user of the voltage drop of the battery BT ₁ .

Eventually, when the output voltage of the battery BT ₁ becomes equal to or lower than the second specified level, the potential of the (−) input terminal of the voltage comparator IC ₂ becomes lower than the potential of the (+) input terminal, so that the voltage comparator IC The output of ₂ becomes High level (S2
1). Therefore, the high level output of the AND gate IC ₃ is supplied to the restoration terminal START via the OR gate IC _4, and the potential of the restoration terminal START becomes high level. As a result, the microprocessor IC ₁ returns to the normal operation mode again (S22).

At step S23, the microprocessor IC
₁ sets the electric potential of the output terminal OUT ₄ to the high level to turn off the light emitting diode LED ₁ , and at S24, the output terminal
Set OUT ₄ potential to High level. As a result, FE
Since the gate terminal of T Q ₁ becomes High level, FE
The conduction of T Q ₁ is cut off. That is, the power supply to the memory holding circuit is cut off. In addition, a microprocessor
In S25, IC ₁ sets the potential of the output terminal OUT ₂ to Low.
Since the level is set, the AND gate IC ₃ is closed and the battery voltage monitoring function on the IC ₂ side is stopped. Microprocessor IC ₁
Finally shifts to the low current consumption mode (S29), and the battery voltage monitoring operation ends.

Needless to say, the output voltage of the battery BT ₁ can be monitored in more stages by increasing the number of voltage comparators and AND gates.

Another embodiment of the present invention will be described below with reference to FIG. For convenience of explanation, members having the same functions as those of the members shown in the drawings of the above-described embodiment are designated by the same reference numerals, and the description thereof will be omitted.

The battery voltage monitoring circuit of this embodiment is constructed so that the output voltage of the battery BT ₁ can be monitored in multiple stages while using a single voltage comparator IC ₂ .

The voltage dividing resistor for the output voltage of the battery BT ₁ is composed of two systems. That is, in the first system, the output voltage of the battery BT ₁ is connected to the (−) input terminal of the voltage comparator IC ₂ via the resistor R ₁ and the source terminal of the FET Q ₂ via the resistor R _11. It is connected to the. The gate terminal of FET Q ₂ is a microprocessor IC
₁ is connected to the output terminal OUT ₅ and the drain terminal is grounded. Also in the second system, the resistances R ₁₁ and F of the first system
ET Q ₂ and the output terminal OUT ₅ are connected to resistors R ₁₂ and
A similar configuration is obtained by replacing the FET Q ₃ and the output terminal OUT ₆ .

[0041] The configuration of the voltage comparator IC ₂ (+) input terminal, configured to transmit the output of the voltage comparator IC ₂ to the return terminal START, the light emitting diodes LED ₁ and FET Q ₁ configuration around the above-described Since it is similar to the example, its description is omitted.

In the above configuration, FETs Q ₂ and F
The ET Q ₃ functions as an electronic switch that switches the detection voltage of the voltage comparator IC ₂ according to a command from the microprocessor IC ₁ . That is, the microprocessor IC ₁ sets the potential of the output terminal OUT ₅ to the Low level and the output terminal OUT ₆
When the electric potential of is set to the high level, the FET Q ₂ is turned on and the FET Q ₃ is turned off. This allows the voltage comparator
The output voltage of the battery BT ₁ is divided by the resistors R ₁ and R ₁₁ and applied to the (−) input terminal of the IC ₂ .

On the contrary, the microprocessor IC ₁ outputs
If the potential of OUT ₅ is set to High level and the potential of the output terminal OUT ₆ is set to Low level, the voltage comparator IC ₂ (-)
The output voltage of the battery BT ₁ is divided by the resistors R ₁ and R ₁₂ and applied to the input terminal.

As described above, if the combination of the resistance and the FET is used to monitor the decrease in the output voltage of the battery BT ₁ in multiple stages, the number of voltage comparators can be reduced, and the configuration of the battery voltage monitoring circuit can be simplified. can do.

A battery voltage monitoring function according to the present invention,
It is also possible to reduce the power consumption at a fixed rate by using the A / D conversion function (voltage detection by software) in the conventional microprocessor together.

[0046]

As described above, the battery voltage monitoring circuit according to the invention of claim 1 compares the voltage of the power supply battery with a specified level, detects that the voltage is below the specified level, and outputs a detection signal. Comparing means for outputting, output control means for shutting off the output of the power supply battery, during the detection period in the comparing means, the output control means is set to a low current consumption mode, based on the detection signal, A mode switching unit that releases the low current consumption mode is provided, and the output control unit shuts off the output of the power supply battery based on the release of the low current consumption mode.

Therefore, the battery voltage monitoring circuit can effectively operate the battery voltage detection function even when the output control means is set to the low current consumption mode. Also, based on the detection signal output in the low current consumption mode, the low current consumption mode is released and the output of the power supply battery is cut off, so it is possible to prevent over-discharge of the power supply battery and extend the life of the power supply battery. Not only can this be achieved, but also the drivable time of the power supply battery can be lengthened.

In the battery voltage monitoring method according to the second aspect of the present invention, as described above, in the normal operation mode, after the battery voltage monitoring function is turned on, the normal operation mode is switched to the low current consumption mode and the power supply battery is used. Based on the voltage below the specified level, the low current consumption mode is released, the output of the power supply battery is controlled, the battery voltage monitoring function is turned off, and the normal operation mode is set to the low current consumption mode again. The configuration is switched to.

Therefore, the battery voltage detection function can be effectively operated in the low current consumption mode. Moreover, since the normal operation mode is restored based on the voltage of the power supply battery falling below the specified level, output control of the power supply battery and OFF control of the battery voltage monitoring function can be performed quickly. Furthermore, after the battery voltage monitoring operation is completed, the mode is switched to the low current consumption mode again, so that there is an effect that the drivable time of the power supply battery can be lengthened.

[Brief description of drawings]

FIG. 1 is a circuit diagram showing a configuration of a battery voltage monitoring circuit according to the present invention.

FIG. 2 is a flowchart showing an operation of the battery voltage monitoring circuit of FIG.

FIG. 3 is a circuit diagram showing a configuration of another battery voltage monitoring circuit according to the present invention.

FIG. 4 is a flowchart showing an operation of the battery voltage monitoring circuit of FIG.

FIG. 5 is a circuit diagram showing a configuration of still another battery voltage monitoring circuit according to the present invention.

FIG. 6 is a circuit diagram showing a configuration of a conventional battery voltage monitoring circuit.

7 is a flowchart showing the operation of the battery voltage monitoring circuit of FIG.

[Explanation of symbols]

BT ₁ battery (power supply battery) IC ₁ microprocessor (output control means and mode switching means) IC ₂ voltage comparator (comparison means) IC ₅ voltage comparator (comparison means) Q ₁ FET (output control means)

─────────────────────────────────────────────────── ─── Continuation of the front page (51) Int.Cl. ⁵ Identification code Internal reference number FI Technical indication H02H 3/24 A 9061-5G H02J 7/00 302 D 9060-5G 7165-5B G06F 1/00 341 Q

Claims (2)

[Claims] 1. A battery voltage monitoring circuit that detects the voltage of a power supply battery and shuts off the output of the power supply battery when the voltage falls below a specified level, and compares the voltage of the power supply battery with the specified level. A comparison unit that detects that the voltage has dropped below a specified level and outputs a detection signal, an output control unit that shuts off the output of the power supply battery, and a low output control unit during the detection period of the comparison unit. A mode switching unit that sets the current consumption mode and releases the low current consumption mode based on the detection signal; and the output control unit outputs the power supply battery based on the release of the low current consumption mode. A battery voltage monitoring circuit characterized by shutting off. 2. In the normal operation mode, after the battery voltage monitoring function is turned on, the normal operation mode is switched to the low current consumption mode, and when the voltage of the power supply battery falls below a specified level, A battery voltage monitoring method characterized by releasing the current consumption mode and controlling the output of the power supply battery, turning off the battery voltage monitoring function, and switching the normal operation mode to the low current consumption mode again.