Portable optical code reader with a device for controlling the charge state of the reader battery

A portable optical code reader, in particular for bar codes, having at least one supply battery; an electronic circuit with a microprocessor; and optoelectronic lighting and receiving devices cooperating with the microprocessor to read an optical code, in particular a bar code. The microprocessor also estimates the charge of the battery on the basis of the maximum charge storable in the battery, of measured recharge units supplied when recharging the battery, and of charge units estimated to have been consumed during operation of the reader.

If you were to search for Portable optical code reader with a device for controlling the charge state of the reader battery using relaxed search criteria, these patents would come up:

What is claimed is:

1. An optical code reader comprising:

an opto-electronic light source capable of illuminating portions of an optical code;

a sensing means capable of sensing light diffused or reflected by an optical code;

an electronic circuit capable of communicating with said opto-electronic light source and said sensing means thereby to read an optical code, wherein said electronic circuit includes a control means including a timing means for generating a timereference value;

a rechargeable power supply source for supplying power to said optical code reader as charge units, said rechargeable power supply having a maximum charge unit storage limit;

wherein said optical code reader includes multiple operating modes corresponding to multiple power consumption rates, said power consumption rates being stored as power consumption values in a memory; and

wherein during operation, in each of said operating modes, said timing means generates a time reference value corresponding to a measured mode operating time interval for each of said operating modes, said time reference values thereafter beingutilized in conjunction with said power consumption values stored in said memory to estimate the charge units remaining in said rechargeable supply source without drawing current from said rechargeable supply source.

2. The optical code reader of claim 1 wherein said power consumption rates are determined and stored in said memory as said power consumption values during a calibration step.

3. The optical code reader of claim 1 wherein said control means further includes a calculating means for calculating an estimated number of charge units consumed during operation of said optical code reader, said calculating means utilizingsaid time reference values and said power consumption values in making said calculations; and

wherein said control means is capable of comparing said estimated number of consumed charge units to said maximum charge unit storage limit thereby to provide an indication of an estimation of the actual charge state of the rechargeable powersupply source.

4. The optical code reader of claim 3 wherein said multiple operating modes include a high power consumption mode having a high power consumption rate stored in said memory as a high power consumption value during which said optoelectronic lightsource and said sensing means are active;

and wherein an estimated number of charge units consumed in said high power consumption mode is calculated by said calculating means utilizing the product of said stored high power consumption value and the corresponding said measured timereference value.

5. The optical code reader of claim 3 wherein said calculating means calculates said estimated number of charge units consumed as the product of said time reference values and the respective said power consumption values.

6. The optical code reader of claim 3 wherein said multiple operating modes include a low-power consumption mode having a low-power consumption rate stored in said memory as a low-power consumption value during which said opto-electronic lightsource and said sensing means are at rest;

and wherein an estimated number of charge units consumed in said low-power consumption mode is calculated by said calculating means utilizing the product of said stored low-power consumption value and the corresponding said measured timereference value.

7. The optical code reader of claim 6 further including a detecting means for detecting an exit from said low-power consumption mode to a different power consumption mode.

8. The optical code reader of claim 3 further including a display means capable of displaying information; and

a discriminating means capable of determining whether said display means is active in the current operating mode;

wherein said multiple operating modes include a maximum-power consumption mode having a maximum-power consumption rate stored in said memory as a maximum-power consumption value during which said display means is active; and

wherein in the event said display means is determined to be active therefore indicating entry into said maximum-power consumption mode, an estimated number of charge units consumed in said maximum-power consumption mode is calculated by saidcalculating means utilizing the product of said stored maximum-power consumption value and the corresponding said measured time reference value.

9. The optical code reader of claim 4 wherein said timing means comprises a first and second clock means;

said first clock means provided for measuring said mode operating time intervals in said low-power consumption state; and

said second clock means provided for measuring said mode operating time intervals in said high-power consumption state, said second clock means having a greater resolving time than said first clock means.

10. The optical code reader of claim 3 further including a recharging mode during which said rechargeable power supply source is supplied with charge units from a battery charger and said calculating means is capable of determining an estimationof the actual charge state of the rechargeable power supply source;

wherein during said charge estimation step, said calculating means calculates the charge state of said rechargeable power supply source utilizing the measured values of said charge units supplied by said battery charger and the estimated numbersof said charge units consumed during operation.

11. The optical code reader of claim 10 wherein said control means provides for adding, with opposite signs, the values of said charge units supplied during said recharging step to the values of said charge units consumed during operation,thereby to calculate an estimate of the actual charge contained in said rechargeable power supply source.

12. The optical code reader of claim 10 further including a detecting means for determining when said rechargeable power supply source has reached said maximum charge unit storage limit.

13. The optical code reader as claimed in claim 10 further including a detecting means for detecting an exit from said low-power consumption mode to a different power consumption mode, said detecting means further providing for detecting thestart of said recharging step and for sequentially enabling said calculating means for calculating the number of said charge units consumed during said low-power consumption state and for calculating the number of said charge units supplied during saidrecharging step.

14. The optical code reader of claim 3 wherein said calculating means includes means for calculating the maximum charge storable in said rechargeable power supply source.

15. The optical code reader of claim 14 wherein said means for calculating the maximum charge comprises:

a cycle start means which is enabled when the rechargeable power supply source reaches its maximum limit;

a discharging means for discharging said rechargeable power supply source by feeding a discharge current to a load, said load being defined by said electronic circuit;

a measuring means for measuring said discharge current;

a detecting means for determining when said rechargeable power supply source has been completely discharged;

a clock means for determining the duration of the discharge interval of said rechargeable power supply source; and

a discharge calculating means which is enabled when said rechargeable power supply source has been completely discharged and which calculates the value of maximum charge storable based on the value of said discharge current and said dischargeinterval.

16. An optical code reader comprising:

an opto-electronic light source capable of illuminating portions of an optical code;

a sensing means capable of sensing light diffused or reflected by an optical code;

an electronic circuit capable of communicating with said opto-electronic light source and said sensing means thereby to read an optical code, wherein said electronic circuit includes a control means;

a rechargeable power supply source for supplying power to said optical code reader as charge units, said rechargeable power supply having a maximum charge unit storage limit;

wherein said optical code reader includes at least one operating mode corresponding to a power consumption rate, said power consumption rate being stored as power consumption value in a memory; and

wherein during operation, in said operating mode, said power consumption value stored in said memory is utilized to estimate the charge units remaining in said rechargeable supply source without drawing current from said rechargeable supplysource.

17. The optical code reader of claim 16 wherein said control means further includes a measuring means for measuring the value of current supplied to said recharge power supply source in the course of recharging said rechargeable power supplysource, thereby to aid in estimating the number of charge units contained in said rechargeable power supply source.

18. The optical code reader of claim 16 wherein said control means comprises a microprocessor means for decoding an electric signal from said sensing means which is derived from a scan of an optical code.

19. The optical code reader of claim 16 wherein said rechargeable power supply source comprises at least one rechargeable battery.

20. The optical code reader of claim 12 wherein said power consumption values are measured only once during said calibration step and are thereafter memorized permanently.