Compaq Lithium ion battery User Manual

Lithium-ion battery technology:  
Getting the most from Smart Batteries  
Battery cycle life  
Battery cycle life is the total number of discharge-charge cycles (Figure 1) a battery yields before it  
can no longer hold a useful amount of charge. Estimating the cycle life of a rechargeable Li-Ion  
battery is difficult because cycle life is affected by the average operating temperature of the battery  
and its energy discharge rate. Basically, higher temperatures and higher energy discharge rates  
decrease battery cycle life. The operating temperature of the battery depends on the air temperature  
as well as the heat generated by the notebook itself and by its immediate environment, such as a  
docking station. The energy discharge (drainage) rate depends on the type of applications running  
on the notebook and by its power management settings. For example, running compute-intensive  
applications such as CAD, gaming, and DVD movies drains the battery faster and decreases its cycle  
life more than running word processing applications.  
Figure 1. A cycle for a rechargeable lithium-ion battery is the cumulative amount of discharge approximately equal to its full  
charge capacity. For example, 10 occurrences of a 10% depth of discharge or 2 occurrences of a 50% depth of discharge  
represent one cycle.  
Battery capacity  
Battery capacity is expressed in ampere-hours (Ah). Battery energy, expressed in watt-hours (Wh), is  
the product of the battery capacity (Ah) and the battery voltage (V). The operating voltage range of a  
Li-Ion battery pack remains relatively constant throughout its useful life; however, its capacity begins to  
decrease in a roughly linear manner as soon as it is put into service. New batteries are classified by  
their rated capacity. Over time, the actual battery capacity decreases due to electrochemical  
inefficiencies within each cell. This loss in capacity (aging) is irreversible; it cannot be restored by  
cycling the battery. Gradually, less and less active material is available within each cell to  
electrochemically store a charge. Consequently, the user experiences reduced computer run time.  
A practical way to express the actual capacity of a battery over time is called full charge  
capacity (FCC). FCC is expressed as a percentage of the initial rated capacity of the battery. FCC is  
influenced by the typical discharge load on the battery and by the user profile. Under normal  
discharge loads, Li-Ion batteries have a lifespan of between 300 and 500 cycles. With moderate use,  
Li-Ion batteries are expected to deliver approximately 80% of their rated capacity after 300 cycles or  
about one year of use (Figure 2). This estimate covers typical users who completely cycle the battery  
each working day by running low to medium power applications (word processing, e-mail, and  
spreadsheets) in wired or wireless modes.  
Figure 2. Full charge capacity with moderate use is about 80% after 300 cycles.  
3
 
Warranty period  
HP provides a 12-month warranty for Li-Ion batteries. The warranty period is based upon the  
expectation that the battery will deliver 80% of its initial capacity after 300 cycles at low to moderate  
power loads. High power loads may cause a battery to reach 80% of initial capacity in less than the  
12-month warranty period. Li-Ion batteries will continue to operate below the 80% capacity threshold;  
however, the capacity (run time) delivered between charges will continue to decrease.  
Table 1 summarizes FCC projections after one year based on 2 user profiles and various power  
loads. The first profile is for a mobile user who fully discharges and charges the battery almost every  
working day (300 cycles per year) in a normal environment. The second profile is for a stationary  
user who only cycles the battery once per week in a high-temperature environment, such as in a  
docking station. As shown in the table, the additional heat generated by running high power  
applications or by using a docking station accelerates the loss of capacity.  
Table 1. Full charge capacity projections after one year of use  
Full charge capacity (% of initial capacity) after one year  
Power load (applications)  
Mobile user  
Stationary user (with docking station)  
Battery cycled daily (25ºC, 77ºF)  
Battery cycled weekly (>35ºC, 95ºF)  
Low (word processing, Internet, e-mail)  
>80%  
80%  
80%  
70%  
Moderate (wireless, spreadsheets,  
database management)  
High* (CAD, 3D games, DVDs, high  
60%  
50%  
LCD brightness)  
*High power applications may also reduce the battery cycle life by as much as 25%.  
4
 
Smart Battery Technology  
Estimating battery run time is further complicated by the inaccuracy of the system that monitors and  
reports the battery charge status to the user. Some notebooks estimate the battery charge state based  
on manufacturer testing of the specific product model with a particular configuration. This method is  
inaccurate when another battery with a different state-of-charge is inserted, because charge status of  
each battery is estimated based on its history in the system.  
To aid users in monitoring and managing Li-Ion batteries, HP Compaq notebooks provide accurate  
and instantaneous status information using Smart Battery Technology. HP Smart Battery Technology  
is based on the Smart Battery System (SBS), which was established by major battery manufacturers  
in 1995 to promote an industry standard for rechargeable battery technology1. The SBS features a  
Smart Battery that maintains and reports its own status, thus providing users with accurate information,  
whether they use different batteries in the same notebook or the same battery in different notebooks.  
Smart Battery calibration  
Repeated short discharges and recharges cause increasing inaccuracy between the state-of-charge  
of the battery and the Power Meter readings. Periodically, the battery needs to be calibrated to  
"relearn" its usable capacity so it can synchronize its charge status with the Power Meter. The  
calibration procedure maximizes the notebook run time by giving the user an accurate estimate of the  
remaining battery charge. Calibration also prevents data loss that can occur during the Hibernation  
process if sufficient power is not available to complete critical save-to-disk operations.  
Smart Batteries calibrate their FCC each time they undergo a full discharge-charge cycle, whether  
they are recharged in the notebook or in a stand-alone charger/conditioner. Calibration using the  
notebook is less convenient because it can take up to 4 hours; however, it can lead to more relevant  
results than using a stand-alone charger. Calibration results using the notebook are more relevant  
because the battery relearns its FCC while undergoing a realistic power load. In a stand-alone  
charger, the battery is discharged using a fixed load. If the fixed load is less than the load typically  
experienced by the notebook, the learned capacity of the battery may be higher than its actual  
capacity. In other words, the newly calibrated battery may not deliver the run time predicted by the  
Power Meter if it is subjected to a greater load than the load used to calibrate the battery.  
The accuracy of today’s Smart Battery IC enables precise calibration when the battery is discharged  
to about 5% of its remaining capacity. Consequently, the user can set the battery alarm at 5% of  
remaining capacity so that the Smart Battery will calibrate its capacity during normal use. The user  
simply has to periodically discharge the battery until the 5% capacity alarm is received. The need to  
perform this procedure will vary with individual use. In general, a Li-Ion battery should be calibrated a  
minimum of once every 3 months. A battery that is seldom discharged completely should be  
calibrated about once a month.  
1 For more information about the Smart Battery System, go to http://www.sbs-forum.org/.  
5
   
Battery care practices  
After reading the information presented in this paper, users should be aware of conditions that  
negatively impact battery run time and lifespan. In summary:  
Li-Ion battery cells suffer gradual, irreversible capacity loss with each discharge-charge cycle. Such  
aging occurs more rapidly as temperature and discharge loads increase.  
The self-discharge rate of a Li-Ion battery is higher if the battery is left in an unpowered notebook.  
During prolonged storage or non-use, the battery charge will decrease below its recommended  
low-voltage level. Leaving the battery in a depleted condition for an extended period will accelerate  
the decrease in FCC.  
Leaving the battery at a high level of charge in a high-temperature environment for extended  
periods (for example, running a notebook computer in a docking station under a heavy load) will  
also accelerate the loss of capacity.  
Running high-end applications using the battery accelerates the loss of capacity. For example,  
playing 3D games will lower FCC faster than using word processing applications.  
Recommendations for battery use and storage are covered in the HP User Guides for each model.  
Additional battery care practices are as follows:  
Store Li-Ion batteries between 20°C and 25°C (68°F and 77°F) with 30% to 50% charge.  
Do not leave batteries exposed to high temperatures for extended periods. Prolonged exposure  
to heat (for example, inside a hot car) will accelerate the deterioration of Li-Ion cells.  
Remove the battery if the notebook will be stored (turned off and not plugged into AC power)  
for more than 2 weeks.  
Remove the battery from the notebook if the notebook will be plugged into AC power continuously  
(via a wall adapter or docking station) for more than 2 weeks.  
Use the type of battery with the highest capacity (Ah) rating if the notebook will run high-end  
applications on battery power.  
Periodically calibrate the battery based on the usage model. Under normal usage, batteries should  
be calibrated a minimum of once every 3 months; however, a battery that is rarely discharged fully  
should be calibrated about once a month.  
6
 
For more information  
For additional information, refer to the resources detailed below.  
Resource description*  
Web address  
Commercial Notebook  
Batteries: Performance  
Optimization white paper  
contains instructions on  
calibrating Li-Ion batteries  
Smart Battery System  
Implementers Forum  
*The information provided by these resources may not apply to all systems.  
© Copyright 2004 Hewlett-Packard Development Company, L.P.  
The information contained herein is subject to change without notice. The only  
warranties for HP products and services are set forth in the express warranty  
statements accompanying such products and services. Nothing herein should  
be construed as constituting an additional warranty. HP shall not be liable for  
technical or editorial errors or omissions contained herein.  
5982-3550ENUS, 01/2004  
 

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