MAX1711 Maxim, MAX1711 Datasheet - Page 21
MAX1711
Manufacturer Part Number
MAX1711
Description
High-Speed / Digitally Adjusted Step-Down Controllers for Notebook CPUs
Manufacturer
Maxim
Datasheet
1.MAX1711.pdf
(28 pages)
Available stocks
Company
Part Number
Manufacturer
Quantity
Price
Company:
Part Number:
MAX17112ETB+
Manufacturer:
ATMEL
Quantity:
2 987
Company:
Part Number:
MAX17112ETB+T
Manufacturer:
MAXIM
Quantity:
13 270
Part Number:
MAX17112ETB+T
Manufacturer:
MAXIM/美信
Quantity:
20 000
Part Number:
MAX17113ETL
Manufacturer:
MAXIM/美信
Quantity:
20 000
Company:
Part Number:
MAX17113ETL+
Manufacturer:
MAXIM
Quantity:
2 163
Part Number:
MAX17113ETL+
Manufacturer:
MAXIM/美信
Quantity:
20 000
Company:
Part Number:
MAX17113ETL+T
Manufacturer:
MAXIM
Quantity:
6 726
Part Number:
MAX17113ETL+T
Manufacturer:
MAXIM/美信
Quantity:
20 000
Company:
Part Number:
MAX17114
Manufacturer:
FUJITSU
Quantity:
8 311
Part Number:
MAX17114ETM+CB2
Manufacturer:
MAXIM/美信
Quantity:
20 000
propagation delays introduce an error to the TON K-fac-
tor. This error is higher at higher frequencies (Table 5).
Also, keep in mind that transient response performance
of buck regulators operated close to dropout is poor,
and bulk output capacitance must often be added (see
V
Dropout Design Example: V
2V, f = 300kHz. The required duty is (V
(V
worst-case on-time is (V
2.075V / 3V · 3.35µs-V · 90% = 2.08µs. The IC duty-fac-
tor limitation is:
which meets the required duty.
Remember to include inductor resistance and MOSFET
on-state voltage drops (V
dropout duty-factor calculations.
Ceramic capacitors have advantages and disadvan-
tages. They have ultra-low ESR, are non-combustible,
are relatively small, and are nonpolarized. On the other
hand, they’re expensive and brittle, and their ultra-low
ESR characteristic can result in excessively high ESR
zero frequencies (affecting stability). In addition, they
can cause output overshoot when going abruptly from
full-load to no-load conditions, unless there are some
bulk tantalum or electrolytic capacitors in parallel to
Figure 8. Setting V
DUTY
SAG
BATT
MAX1710
equation in the Design Procedure ).
- V
t
ON MIN
SW
GNDS
(
FBS
All-Ceramic-Capacitor Application
) = (2V + 0.1V) / (3.0V - 0.1V) = 72.4%. The
DH
DL
FB
Step-Down Controllers for Notebook CPUs
t
ON MIN
)
OUT
absorb the stored energy in the induc-
(
t
______________________________________________________________________________________
OFF MAX
with a Resistor-Divider
)
(
V
BATT
OUT
)
SW
1k
2 08
) when doing worst-case
BATT
.
+ 0.075) / V
s
= 3V min, V
R1
R2
500
ns
OUT
High-Speed, Digitally Adjusted
BATT
80 6
+ V
. %
OUT
· K =
SW
V
OUT
) /
=
tor. In some cases, there may be no room for electrolyt-
ics, creating a need for a DC-DC design that uses noth-
ing but ceramics.
The all-ceramic-capacitor application of Figure 7 has the
same basic performance as the 7A Standard Application
Circuit, but replaces the tantalum output capacitors with
ceramics. This design relies on having a minimum of
5mΩ parasitic PC board trace resistance in series with
the capacitor in order to reduce the ESR zero frequency.
This small amount of resistance is easily obtained by
locating the MAX1710/MAX1711 circuit two or three inch-
es away from the CPU, and placing all the ceramic
capacitors close to the CPU. Resistance values higher
than 5mΩ just improve the stability (which can be
observed by examining the load-transient response
characteristic as shown in the Typical Operating
Characteristics ). Avoid adding excess PC board trace
resistance, as there’s an efficiency penalty. 5mΩ is suffi-
cient for the 7A circuit.
Output overshoot determines the minimum output
capacitance requirement. In this example, the switching
frequency has been increased to 550kHz and the induc-
tor value has been reduced to 0.5µH (compared to
300kHz and 2µH for the standard 7A circuit) in order to
minimize the energy transferred from inductor to capaci-
tor during load-step recovery. Even so, the amount of
overshoot is high enough (80mV) that for the MAX1710,
it’s wise to disable OVP or use the MAX1711 with its fixed
2.25V overvoltage protection threshold to avoid tripping
the fault latch (see the overshoot equation in the Output
Capacitor Selection section). The efficiency penalty for
operating at 550kHz is about 2% to 3%, depending on
the input voltage.
Two optional 1kΩ resistors are placed in series with FB
and FBS. These resistors prevent the negative output
voltage spike (that results from tripping OVP) from
pulling SHDN low via its internal ESD diode, which tends
to clear the fault latch, causing “hiccup” restarts.
The output voltage can be adjusted with a resistor-
divider rather than the DAC if desired (Figure 8). The
drawback of this practice is that the on-time doesn’t
automatically receive correct compensation for changing
output voltage levels. This can result in variable switch-
ing frequency as the resistor ratio is changed and/or
excessive switching frequency. The equation for adjust-
ing the output voltage is:
Setting V
V
OUT
OUT
V
FB
1
with a Resistor-Divider
%
1
R
R
1
2
21
Related parts for MAX1711
Image
Part Number
Description
Manufacturer
Datasheet
Request
R
Part Number:
Description:
The DS5250 is a highly secure, four clocks-per-machine cycle, 100% 8051-instruction-set-compatible microprocessor in Maxim's secure microcontroller family
Manufacturer:
Maxim
Datasheet:
Part Number:
Description:
The MAX9263/MAX9264 chipset extends Maxim's gigabit multimedia serial link (GMSL) technology to include high-bandwidth digital content protection (HDCP) encryption for content protection of DVD and Blu-ray™ video and audio data
Manufacturer:
Maxim
Part Number:
Description:
The Maxim MXL1016 (10ns, typ) high-speed, complementary-output comparator is designed specifically to
interface directly to TTL logic while operating from
either a dual ±5V supply or a single +5V supply
Manufacturer:
Maxim
Datasheet:
Part Number:
Description:
Maxim's DG300–DG303 and DG300A–DG303A CMOS dual and quad analog switches combine low power operation with fast switching times and superior DC and AC switch characteristics
Manufacturer:
Maxim
Datasheet:
Part Number:
Description:
Maxim's DG300–DG303 and DG300A–DG303A CMOS dual and quad analog switches combine low power operation with fast switching times and superior DC and AC switch characteristics
Manufacturer:
Maxim
Datasheet:
Part Number:
Description:
Maxim's DG300–DG303 and DG300A–DG303A CMOS dual and quad analog switches combine low power operation with fast switching times and superior DC and AC switch characteristics
Manufacturer:
Maxim
Datasheet:
Part Number:
Description:
Maxim's DG300–DG303 and DG300A–DG303A CMOS dual and quad analog switches combine low power operation with fast switching times and superior DC and AC switch characteristics
Manufacturer:
Maxim
Datasheet:
Part Number:
Description:
Maxim's redesigned DG401/DG403/DG405 analog switches now feature guaranteed low on-resistance matching between switches (2Ω max) and guaranteed on-resistance flatness over the signal range (3Ω max)
Manufacturer:
Maxim
Datasheet:
Part Number:
Description:
Maxim's redesigned DG401/DG403/DG405 analog switches now feature guaranteed low on-resistance matching between switches (2Ω max) and guaranteed on-resistance flatness over the signal range (3Ω max)
Manufacturer:
Maxim
Datasheet:
Part Number:
Description:
Maxim's redesigned DG401/DG403/DG405 analog switches now feature guaranteed low on-resistance matching between switches (2Ω max) and guaranteed on-resistance flatness over the signal range (3Ω max)
Manufacturer:
Maxim
Datasheet:
Part Number:
Description:
Maxim's redesigned DG406 and DG407 CMOS analog multiplexers now feature guaranteed matching between channels (8Ω max) and flatness over the specified signal range (9Ω max)
Manufacturer:
Maxim
Datasheet:
Part Number:
Description:
Maxim's redesigned DG406 and DG407 CMOS analog multiplexers now feature guaranteed matching between channels (8Ω max) and flatness over the specified signal range (9Ω max)
Manufacturer:
Maxim
Datasheet:
Part Number:
Description:
Maxim's redesigned DG408 and DG409 CMOS analog multiplexers now feature guaranteed matching between channels (8Ω max) and flatness over the specified signal range (9Ω max)
Manufacturer:
Maxim
Datasheet:
Part Number:
Description:
Maxim's redesigned DG408 and DG409 CMOS analog multiplexers now feature guaranteed matching between channels (8Ω max) and flatness over the specified signal range (9Ω max)
Manufacturer:
Maxim
Datasheet:
Part Number:
Description:
Maxim's redesigned DG411/DG412/DG413 analog switches now feature low on-resistance matching between switches (3Ω max) and guaranteed on-resistance flatness over the signal range (Δ4Ω max)
Manufacturer:
Maxim
Datasheet: