Texas Instruments BQ2050HSN-A508, BQ2050HSN-A308TR, BQ2050HSN-A308, BQ2050HSN-A304TR, BQ2050HSN-A508TR Datasheet

Features

➤

Accurate measurement of avail

-

able capacity in Lithium Ion bat

-

teries

➤

Provides a low-cost battery man

­agement solution for pack
integration

-

Complete circuit can fit in as
little as

1

2

square inch of PCB

-

Low operating current (120µA
typical)

-

Less than 100nA of data
retention current

➤

High-speed (5kb) single-wire
communication interface (HDQ
bus) for critical battery
parameters

➤ Monitors and controls charge FET

in Li-Ion pack protection circuit

➤ Direct drive of remaining capacity

LEDs

➤ Measurements automatically

compensated for rate and
temperature

➤ 16-pin narrow SOIC

General Description

The bq2050H Lithium Ion Power
Gauge™ IC is intended for battery­pack or in-system installation to
maintain an accurate record of
available battery capacity. The IC
monitors a voltage drop across a
sense resistor connected in series
between the negative battery termi

­nal and ground to determine
charge and discharge activity of
the battery. Compensations for bat

­tery temperature, self discharge,
and rate of discharge are applied to
the charge counter to provide avail

­able capacity information across a
wide range of operating conditions.
Battery capacity is automatically re

­calibrated, or “learned,” in the
course of a discharge cycle from full
to empty.

Nominal available capacity may be
directly indicated using a five­segment LED display. These seg-

ments are used to graphically indi

­cate available capacity. The
bq2050H also supports a simple
single-line bidirectional serial link
to an external processor (common
ground). The 5kb HDQ bus interface
reduces communications overhead
in the external microcontroller.

Internal registers include available
capacity, temperature, scaled avail

­able energy, battery ID, battery
status, and Li-Ion charge FET
status. The external processor may
also overwrite some of the bq2050H
power gauge data registers.

The bq2050H can operate from the
batteries in the pack. The REF out

­put and an external transistor allow
a simple, inexpensive voltage regu­lator to supply power to the circuit
from the cells.

1

bq2050H

LCOM LED common output

SEG

1

/PROG1LED segment 1/

program 1 input

SEG

2

/PROG2LED segment 2/

program 2 input

SEG

3

/PROG3LED segment 3/

program 3 input

SEG

4

/PROG4LED segment 4/

program 4 input

SEG

5

/PROG5LED segment 5/

program 5 input

CFC Charge FET control

output

1

PN2050H1.eps

16-Pin Narrow SOIC

2

3

4

5

6

7

8

16

15

14

13

12

11

10

9

V

CC

REF

PSTAT

HDQ

RBI

SB

DISP

SR

LCOM

SEG1/PROG

1

SEG2/PROG

2

SEG3/PROG

3

SEG4/PROG

4

SEG5/PROG

5

CFC

V

SS

V

SS

System ground

SR Sense resistor input

DISP

Display control input

SB Battery sense input

RBI Register backup input

HDQ Serial communications

input/output

PSTAT Protector status input

REF Voltage reference output

V

CC

Supply voltage

Pin Connections

SLUS150–MAY 1999 D

Low-Cost Lithium Ion Power Gauge™ IC

Pin Names

Pin Descriptions

LCOM

LED common output

This open-drain output switches V

CC

to
source current for the LEDs. The switch is
off during initialization to allow reading of
the soft pull-up or pull-down program resis

­tors. LCOM is also high impedance when the
display is off.

SEG

1

–

SEG

5

LED display segment outputs (dual func

­tion with PROG

1

–PROG5)

Each output may activate an LED to sink
the current sourced from LCOM.

PROG

1

–

PROG

2

Programmed full count selection inputs
(dual function with SEG

1

–SEG2)

These three-level input pins define the pro

­grammed full count (PFC) thresholds de

­scribed in Table 2.

PROG

3

–

PROG

4

Power gauge scale selection inputs (dual
function with SEG

3

–SEG4)

These three-level input pins define the scale
factor described in Table 2.

PROG

5

Self-discharge rate selection (dual func­tion with SEG

5

)

This three-level input pin defines the
self-discharge and battery compensation fac­tors as shown in Table 1.

CFC

Charge FET control output

This pin can be used as an additional control
to the charge FET of the Li-Ion pack protec

­tion circuitry.

V

SS

Ground

SR

Sense resistor input

The voltage drop (V

SR

) across the sense re

­sistor R

S

is monitored and integrated over

time to interpret charge and discharge activ

­ity. The SR input is tied between the nega

­tive terminal of the battery and the sense re

­sistor. V

SR<VSS

indicates discharge, and

V

SR>VSS

indicates charge. The effective

voltage drop, V

SRO

, as seen by the bq2050H

is V

SR+VOS

.

DISP

Display control input

DISP

high disables the LED display. DISP

tied to VCCallows PROGXto connect di

-

rectly to V

CC

or VSSinstead of through a

pull-up or pull-down resistor. DISP

floating
allows the LED display to be active during
charge. DISP

low activates the display. See

Table 1.

SB

Secondary battery input

This input monitors the battery cell voltage
potential through a high-impedance resis

­tive divider network for end-of-discharge
voltage (EDV) thresholds and battery-removed
detection.

RBI

Register backup input

This pin is used to provide backup potential to
the bq2050H registers during periods when
V

CC

≤

3V. A storage capacitor or a battery

can be connected to RBI.

HDQ

Serial communication input/output

This is the open-drain bidirectional commu­nications port.

PSTAT

Protector status input

This input provides overvoltage status from
the Li-Ion protector circuit. It should con­nect to V

SS

when not used.

REF

Voltage reference output for regulator

REF provides a voltage reference output for
an optional micro-regulator.

V

CC

Supply voltage input

2

bq2050H

Functional Description

General Operation

The bq2050H determines battery capacity by moni

­toring the amount of current input to or removed
from a rechargeable battery. The bq2050H meas

­ures discharge and charge currents, measures bat

­tery voltage, estimates self-discharge, monitors the
battery for low battery-voltage thresholds, and com

­pensates for temperature and discharge rate. Cur

­rent measurement is measured by monitoring the
voltage across a small-value series sense resistor be

­tween the negative battery terminal and ground.
Scaled available energy is estimated using the re

­maining average battery voltage during the dis

­charge cycle and the remaining nominal available

capacity. The scaled available energy measurement
is corrected for environmental and operating condi

-

tions.

Figure 1 shows a typical battery pack application of the
bq2050H using the LED display capability as a charge­state indicator. The bq2050H is configured to display
capacity in relative display mode. The relative display
mode uses the last measured discharge capacity of the
battery as the battery “full” reference. A push-button
display feature is available for momentarily enabling
the LED display.

The bq2050H monitors the charge and discharge cur

-

rents as a voltage across a sense resistor. (See R

S

in Fig

­ure 1.) A filter between the negative battery terminal
and the SR pin is required.

3

bq2050H

FG2050H1.eps

CFC

SEG5/PROG

5

SEG4/PROG

4

SEG3/PROG

3

SEG2/PROG

2

SEG1/PROG

1

SR

DISP

SB

V

CC

REF

bq2050H

Power Gauge IC

LCOM

V

SS

RBI

HDQ

V

CC

C1

C2

Q1
ZVNL110A

R

1

R

S

RB

1

RB

2

See note 4

Load

Charger

1. Indicates optional.

2. Programming resistors and ESD-protection diodes are not shown.

3. RC on SR is required.

4. A series diode is required on RBI if the bottom series cell is used as the backup source.
If the cell is used, the backup capacitor is not required, and the anode is connected to the
positive terminal of the cell.

100K

PSTAT

Notes:

0.1µF

Figure 1. Battery Pack Application Diagram—LED Display

Voltage Thresholds

In conjunction with monitoring VSRfor charge/discharge
currents, the bq2050H monitors the battery potential
through the SB pin. The voltage is determined through
a resistor-divider network per the following equation:

RB1
RB2

4N=−1

where N is the number of cells, RB1 is connected to the
positive battery terminal, and RB2 is connected to the
negative battery terminal. The single-cell battery volt

­age is monitored for the end-of-discharge voltage (EDV)
thresholds. The EDV threshold levels are used to deter

­mine when the battery has reached an “empty” state.

The EDV thresholds for the bq2050H are programmable
with the default values fixed at:

EDV1 (first) = 0.76V

EDVF (final) = EDV1-0.025V = 0.735V

If V

SB

is below either of the two EDV thresholds, the as

­sociated flag is latched and remains latched, independ­ent of V

SB

, until the next valid charge. The VSBvalue is

also available over the serial port.

During discharge and charge, the bq2050H monitors
V

SR

for various thresholds used to compensate the
charge counter. EDV monitoring is disabled if the dis­charge rate is greater than 2C (OVLD Flag = 1) and re­sumes

1

2

second after the rate falls below 2C.

RBI Input

The RBI input pin is intended to be used with a storage
capacitor or external supply to provide backup potential
to the internal bq2050H registers when V

CC

drops below

3.0V. V

CC

is output on RBI when VCCis above 3.0V. If us

­ing an external supply (such as the bottom series cell) as
the backup source, an external diode is required for isola

­tion.

Reset

The bq2050H can be reset by removing VCCand ground

­ing the RBI pin for 15 seconds or by commands over the
serial port. The serial port reset command sequence re

­quires writing 00h to register PPFC (address = 1Eh) and
then writing 00h to register LMD (address = 05h).

Temperature

The bq2050H internally determines the temperature in
10°C steps centered from approximately -35°C to +85°C.
The temperature steps are used to adapt charge and dis

­charge rate compensations, self-discharge counting, and
available charge display translation. The temperature
range is available over the serial port in 10°C incre

­ments as shown in the following table:

Layout Considerations

The bq2050H measures the voltage differential between
the SR and V

SS

pins. VOS(the offset voltage at the SR
pin) is greatly affected by PC board layout. For optimal
results, the PC board layout should follow the strict rule
of a single-point ground return. Sharing high-current
ground with small signal ground causes undesirable
noise on the small signal nodes. Additionally:

■

The capacitors (C1 and C2) should be placed as
close as possible to the V

CC

and SB pins,

respectively, and their paths to V

SS

should be as
short as possible. A high-quality ceramic capacitor
of 0.1µF is recommended for V

CC

.

■

The sense-resistor capacitor should be placed as close
as possible to the SR pin.

■

The sense resistor (RS) should be as close as possible to
the bq2050H.

4

bq2050H

TMP (hex) Temperature Range

0x < -30°C

1x -30°C to -20°C

2x -20°C to -10°C

3x -10°C to 0°C

4x 0°C to 10°C

5x 10°C to 20°C

6x 20°C to 30°C

7x 30°C to 40°C

8x 40°C to 50°C

9x 50°C to 60°C

Ax 60°C to 70°C

Bx 70°C to 80°C

Cx > 80°C

Gas Gauge Operation

The operational overview diagram in Figure 2 illustrates
the operation of the bq2050H. The bq2050H accumu

­lates a measure of charge and discharge currents, as
well as an estimation of self-discharge. The accumu

­lated charge and discharge currents are adjusted for
temperature and rate to provide the indication of com

­pensated available capacity to the host system or user.

The main counter, Nominal Available Capacity (NAC),
represents the available battery capacity at any given
time. Battery charging increments the NAC register,
while battery discharging and self-discharge decrement
the NAC register and increment the DCR (Discharge
Count Register).

The Discharge Count Register is used to update the Last
Measured Discharge (LMD) register only if a complete
battery discharge from full to empty occurs without any
partial battery charges. Therefore, the bq2050H adapts
its capacity determination based on the actual condi

­tions of discharge.

The battery's initial capacity equals the Programmed
Full Count (PFC) shown in Table 2. Until LMD is up

­dated, NAC counts up to but not beyond this threshold
during subsequent charges. This approach allows the
gas gauge to be charger-independent and compatible
with any type of charge regime.

1. Last Measured Discharge (LMD) or learned

battery capacity:

LMD is the last measured discharge capacity of the
battery. On initialization (application of V

CC

or bat

-

tery replacement), LMD = PFC. During subsequent
discharges, the LMD is updated with the latest
measured capacity in the Discharge Count Register
representing a discharge from full to below EDV1.
A qualified discharge is necessary for a capacity
transfer from the DCR to the LMD register. The
LMD also serves as the 100% reference threshold
used by the relative display mode.

5

bq2050H

FG2050H2.eps

Temperature

Compensation

Charge
Current

Discharge

Current

Self-Discharge

Timer

Nominal

Available

Charge

(NAC)

Last

Measured

Discharged

(LMD)

Discharge

Count

Register

(DCR)

<

Qualified

Transfer

+

Rate and

Temperature

Compensation

Temperature

Compensation

Temperature Step,
Other Data

+

--

+

Inputs

Main Counters

and Capacity

Reference (LMD)

Outputs

Serial

Port

Compensated
Available Charge
LED Display, etc.

Rate and

Temperature

Compensation

Figure 2. Operational Overview

2. Programmed Full Count (PFC) or initial bat

-

tery capacity:

The initial LMD and gas gauge rate values are pro

-

grammed by using PROG

1

–PROG4. The bq2050H
is configured for a given application by selecting a
PFC value from Table 2. The correct PFC may be
determined by multiplying the rated battery capac

-

ity in mAh by the sense resistor value:

Battery capacity (mAh)*sense resistor (Ω) =

PFC (mVh)

Selecting a PFC slightly less than the rated capac

­ity provides a conservative capacity reference until
the bq2050H “learns” a new capacity reference.

Example: Selecting a PFC Value

Given:

Sense resistor = 0.05

Ω

Number of cells = 2
Capacity = 1000mAh, Li-Ion battery, coke-anode
Current range = 50mA to 1A
Relative display mode
Self-discharge =

NAC

512

per day @ 25°C
Voltage drop over sense resistor = 2.5mV to 50mV
Nominal discharge voltage = 3.6V

Therefore:

1000mAh*0.05Ω= 50mVh

6

bq2050H

PROG

x

Pro-

grammed

Full

Count

(PFC)

PROG

4

= L PROG4= Z or H

Units

12

PROG

3

= H PROG3= Z PROG3= L PROG3= H PROG3= Z PROG3= L

-- -

SCALE =

1/80

SCALE =

1/160

SCALE =

1/320

SCALE =

1/640

SCALE =

1/1280

SCALE =

1/2560

mVh/
count

H H 49152 614 307 154 76.8 38.4 19.2 mVh

H Z 45056 563 282 141 70.4 35.2 17.6 mVh

H L 40960 512 256 128 64.0 32.0 16.0 mVh

Z H 36864 461 230 115 57.6 28.8 14.4 mVh

Z Z 33792 422 211 106 53.0 26.4 13.2 mVh

Z L 30720 384 192 96.0 48.0 24.0 12.0 mVh

L H 27648 346 173 86.4 43.2 21.6 10.8 mVh

L Z 25600 320 160 80.0 40.0 20.0 10.0 mVh

L L 22528 282 141 70.4 35.2 17.6 8.8 mVh

V

SR

equivalent to 2

counts/s (nom.)

90 45 22.5 11.25 5.6 2.8 mV

Table 2. bq2050H Programmed Full Count mVh, VSRGain Selections

Pin

Connection

PROG5Compensation/Self-Discharge

(See Tables 3 and 4)

DISP

Display State

H Coke anode/disabled LEDs disabled

Z Coke anode/

NAC

512

LEDs on when charging

L Graphite anode/

NAC

512

LEDs on for 4 s

Table 1. Self-Discharge and Capacity Compensation

Select:

PFC = 30720 counts or 48mVh
PROG

1

= float

PROG

2

= low

PROG

3

= high

PROG

4

= float

PROG

5

= float

The initial full battery capacity is 48mVh (960mAh)
until the bq2050H “learns” a new capacity with a
qualified discharge from full to EDV1.

3. Nominal Available Capacity (NAC):

NAC counts up during charge to a maximum value
of LMD and down during discharge and self-dis

­charge to 0. NAC is reset to 0 on initialization and
on the first valid charge following discharge to
EDV1. To prevent overstatement of charge during
periods of overcharge, NAC stops incrementing
when NAC = LMD.

4. Discharge Count Register (DCR):

The DCR counts up during discharge independent
of NAC and could continue increasing after NAC
has decremented to 0. Prior to NAC = 0 (empty
battery), both discharge and self-discharge in­crement the DCR. After NAC = 0, only discharge
increments the DCR. The DCR resets to 0 when
NAC = LMD. The DCR does not roll over but stops
counting when it reaches FFh.

The DCR value becomes the new LMD value on the
first charge after a valid discharge to V

EDV1

if all

the following conditions are met:

■

No valid charge initiations (charges greater than
2 NAC updates where V

SRO>VSRQ

) occurred

during the period between NAC = LMD and EDV1.

■

The self-discharge is less than 6% of NAC.

■

The temperature is≥0°C when the EDV1 level
is reached during discharge.

■

VDQ is set

The valid discharge flag (VDQ) indicates whether
the present discharge is valid for LMD update. If
the DCR update value is less than 0.94 ∗ LMD, LMD
will only be modified by 0.94 ∗ LMD. This prevents
invalid DCR values from corrupting LMD.

5. Scaled Available Energy (SAE):

SAE is useful in determining the available energy
within the battery, and may provide a more useful
capacity reference in battery chemistries with
sloped voltage profiles during discharge. SAE may
be converted to an mWh value using the following
formula:

E(mWh) =

(SAEH SAEL)∗+ ∗256

12. ∗∗

∗

SCALE (R + R )

RR

B1 B2

SB2

where RB1,RB2, and RSare resistor values in
ohms, as shown in Figure 1. SCALE is the selected
scale from Table 2.

6. Compensated Available Capacity (CACT)

CACT counts similarly to NAC, but contains the available
capacity compensated for discharge rate and temperature.

Charge Counting

Charge activity is detected based on a positive voltage
on the SR input. If charge activity is detected, the
bq2050H increments NAC at a rate proportional to V

SR

and, if enabled, activates an LED display.

The bq2050H counts charge activity when the voltage at
theSRinput(V

SRO

) exceeds the minimum charge

threshold (V

SRQ

). A valid charge is detected when NAC
has been updated twice without discharging or reaching
the digital magnitude filter time-out. Once a valid
charge is detected, charge counting continues until V

SR

,

including offset, falls below V

SRQ

.

Discharge Counting

Discharge activity is detected based on a negative volt­age on the SR input. All discharge counts where V

SRO

is less than the minimum discharge threshold (V

SRD

)
cause the NAC register to decrement and the DCR to
increment.

Self-Discharge Counting

The bq2050H continuously decrements NAC and incre

-

ments DCR for self-discharge based on time and tempera

-

ture.

Charge/Discharge Current

The bq2050H current-scale registers, VSRH and VSRL,
can be used to determine the battery charge or dis

-

charge current. See the Current Scale Register descrip

-

tion for details.

Count Compensations

Compensated Available Capacity

Compensated Available Capacity compensation is based
on the rate of discharge, temperature, and negative
electrode type. Tables 3A and 3B outline the correction
factor typically used for graphite-anode Li-Ion batteries,
and Tables 4A and 4B outline the factors typically used for
coke-anode Li-Ion batteries. The compensation factor is
applied to NAC to derive the CACD and CACT values.

7

bq2050H

The CACD value is the available charge compensated
for the rate of discharge. At high discharge rates, CACD
is reduced. The reduction is maintained until a valid
charge is detected. The CACT value is the available
charge compensated for the rate of discharge and tem

-

perature. The CACT value is used to drive the LED dis

-

play.

Charge Compensation

The bq2050H also monitors temperature during charge.
If the temperature is <0°C, NAC will only increment up
to 0.94 * LMD, inhibiting VDQ from being set. This
keeps a “learn” cycle from occurring when the battery is
charged at very low temperatures. If the temperature
rises above 0°C, NAC will be allowed to count up to NAC
= LMD.

Self-Discharge Compensation

The self-discharge compensation is programmed for a
nominal rate of

1

512

∗ NAC per day. This is the rate that

NAC is reduced for a battery within the 20–30°C tem

­perature range. This rate varies across 8 ranges from
<10°C to >70°C, as shown in Table 5.

Self-discharge may be disabled by connecting PROG

5

=H.

Digital Magnitude Filter

The bq2050H has a digital filter to eliminate charge and
discharge counting below a set threshold. The minimum
charge (V

SRQ

) and discharge (V

SRD

) threshold for the

bq2050H is 250µV.

Pack Protection Supervision

The bq2050H can monitor the charge FET in a Li-Ion
pack protector circuit as shown in Figure 3. If the bat

­tery voltage is too high or the temperature is out of the
0—60°C range, the bq2050H disables the charge FET
with the CFC output, which turns off the charge to the
pack.

The PSTAT input is used to monitor the protector state. If
PSTAT is above 2.5V, bit 5 of FLGS1 is set to 1. If PSTAT
is below 0.5V, bit 5 of FLGS1 is cleared to zero. Using this
input, the system can monitor the state of the charge con

-

8

bq2050H

Temperature Range

Typical Rate

PROG

5

= Z or L

< 10°C

NAC

2048

10–20°C

NAC

1024

20–30°C

NAC

512

30–40°C

NAC

256

40–50°C

NAC

128

50–60°C

NAC

64

60–70°C

NAC

32

> 70°C

NAC

16

Table 5. Self-Discharge Compensation

Approximate Discharge

Rate

Available Capacity

Reduction

<

0.5C 0

≥

0.5C

0.05 ∗ LMD

Table 3A. Graphite Anode

Temperature

Available Capacity

Reduction

≥

10°C 0

0°C to 10°C

0.05 ∗ LMD

-20°C to 0°C

0.15 ∗ LMD

≤

-20°C

0.37 ∗ LMD

Table 3B. Graphite Anode

Approximate Discharge

Rate

Available Capacity

Reduction

<

0.5C 0

≥

0.5C

0.10 ∗ LMD

Table 4A. Coke Anode

Temperature

Available Capacity

Reduction

≥

10°C 0

0°C to 10°C

0.10 ∗ LMD

-20°C to 0°C

0.30 ∗ LMD

≤

-20°C

0.60 ∗ LMD

Table 4B. Coke Anode