TS6001AIG325T TOUCHSTONE [Touchstone Semiconductor Inc], TS6001AIG325T Datasheet - Page 8
TS6001AIG325T
Manufacturer Part Number
TS6001AIG325T
Description
A 7ppm/oC, 0.08 o/o Precision +2.5V Voltage Reference in SOT23
Manufacturer
TOUCHSTONE [Touchstone Semiconductor Inc]
Datasheet
1.TS6001AIG325T.pdf
(12 pages)
TS6001
Supply Current
The TS6001 exhibits excellent dc line regulation as
its supply current changes slightly as a function of
the applied supply voltage. Because of a unique bias
loop design, the change in its supply current as a
function of supply voltage (its ΔI
0.1μA/V. Since the TS6001 is a series-mode
reference, load current is drawn from the supply
voltage only when required. In this case, circuit
efficiency is maintained at all applied supply
voltages. Reducing power dissipation and extending
battery life are the net benefits of improved circuit
efficiency.
When the applied supply voltage is less than the
minimum specified input voltage of the TS6001 (for
example,
transition),
calibration routine and can draw up to 200μA above
its nominal, steady-state supply current. This internal
calibration sequence also dominates the TS6001’s
turn-on time. To ensure reliable power-up behavior,
the input power source must have sufficient reserve
power to provide the extra supply current drawn
during the power-up transition.
Voltage Reference Turn-On Time
With a (V
200mV and I
combined turn-on and settling time to within 0.1% of
its 2.5V final value is approximately 340μs.
Output Voltage Hysteresis
Reference output voltage thermal hysteresis is the
change in the reference’s +25°C output voltage after
temperature cycling from +25°C to +85°C to +25°C
and from +25°C to -40°C to +25°C. Thermal
hysteresis is caused by differential package stress
impressed upon the TS6001’s internal bandgap core
transistors and depends on whether the reference IC
was previously at a higher or lower temperature. At
100ppm,
hysteresis is equal to 0.25mV with respect to a 2.5V
output voltage.
Connecting Two or More TS6001s in Stacked
V
In many applications, it is desired to combine the
outputs of two or more precision voltage references,
especially if the combined output voltage is not
available or is an uncommon output voltage. One
such technique for combining (or “stacking”) the
Page 8
OUT
Arrangements
IN
during
the
– V
the
LOAD
OUT
TS6001’s
TS6001
) voltage differential larger than
the
= 0mA, the TS6001’s typical
power-up
performs
typical
IN
/ΔV
or
IN
) is less than
an
temperature
“cold-start”
internal
outputs of precision voltage references is illustrated
in Figure 3.
In this example and powered by an unregulated
supply voltage (V
precision voltage references are used. The GND
terminal of REFA is connected to the OUT terminal
of REFB. This connection produces two output
voltages, V
the terminal voltage of REFB and V
V
implementing this stacked arrangement with a pair
of TS6001-2.5s, V
Although the TS6001-2.5s do not specifically require
input bypass capacitors, it is good engineering
practice to bypass both references from V
global GND terminal (at REFB). If either or both
reference ICs are required to drive a load
capacitance, it is also good engineering practice to
route the load capacitor’s return lead to each
reference’s corresponding REF’s GND terminal. The
circuit’s minimum input supply voltage, V
determined by V
(75mV, typically).
How to Configure the TS6001 into a General-
Purpose Current Source
In many low-voltage applications, a general-purpose
current source is needed with very good line
regulation. The TS6001-2.5 can be configured as a
grounded-load, floating current source as shown
Figure 4. In this example, the TS6001-2.5’s output
voltage is bootstrapped across an external resistor
(R1 + P1) which, in turn, sets the output current. The
circuit’s total output current is I
I
QSC
Figure 3: Connecting Two TS6001-2.5s in a
REFOUT1
is the TS6001 supply current (up to 35µA). For
plus the OUT terminal voltage of REFB. By
Stacked V
REFOUT1
REFOUT2
REFOUT2
and V
IN
REFOUT
≥ +5.2V), two TS6001-2.5
and REFB’s dropout voltage
is 5V and V
REFOUT2
Arrangement
OUT
, where V
= I
TS6001DS r1p0
REFOUT1
SET
+I
REFOUT2
QSC
REFOUT1
IN
is 2.5V.
where
to the
RTFDS
IN
, is
is
is
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