參數資料
型號: MIC2592B-2BTQ
廠商: MICREL INC
元件分類: 電源管理
英文描述: Dual-Slot PCI Express Hot-Plug Controller
中文描述: 1-CHANNEL POWER SUPPLY SUPPORT CKT, PQFP48
封裝: TQFP-48
文件頁數: 27/31頁
文件大?。?/td> 1916K
代理商: MIC2592B-2BTQ
March 2005
27
M9999-033105
MIC2592B
Applications Information
Sense Resistor Selection
The 12V and the 3.3V supplies employ internal current sens-
ing circuitry to detect overcurrent conditions that may trip the
circuit breaker. An external sense resistor is used to monitor
the current that passes through the external MOSFET for
each slot of the 12V and 3.3V rails. The sense resistor is
nominally valued at:
V
THILIMIT
I
LIMIT
Micrel
R
SENSE(NOM)
=
where V
is the typical (or nominal) circuit breaker
THILIMIT
threshold voltage (50mV) and I
is the nominal inrush
load current level to trip the internal circuit breaker.
To accommodate worse-case tolerances in the sense re-
sistor (for a ±1% initial tolerance, allow ±3% tolerance for
variations over time and temperature) and circuit breaker
threshold voltages, a slightly more detailed calculation must
be used to determine the minimum and maximum hot swap
load currents.
As the MIC2592B’s minimum current limit threshold voltage
is 45mV, the minimum hot swap load current is determined
where the sense resistor is 3% high:
45mV
(1.03 × R
SENSE(NOM)
)
LIMIT
I
LIMIT(MIN)
=
=
43.7mV
R
SENSE(NOM)
be greater than the application circuit’s upper steady-state
load current boundary. Once the lower value of R
SENSE
has
been calculated, it is good practice to check the maximum
hot swap load current (I
) which the circuit may
let pass in the case of tolerance build-up in the opposite
direction. Here, the worse-case maximum is found using a
V
threshold of 55mV and a sense resistor 3%
low in value:
55mV
(0.97 × R
SENSE(NOM)
)
LIMIT(MAX)
THILIMIT(MAX)
I
LIMIT(MAX)
=
=
56.7mV
R
SENSE(NOM)
to operate up to approximately 1.25x the steady-state hot
swap load currents. For example, if one of the 12V slots of the
MIC2592B circuit must pass a minimum hot swap load current
of 1.5A without nuisance trips, R
SENSE
should be set to:
45mV
1.5A
R
SENSE(NOM)
=
= 30mΩ
where the nearest 1% standard value is 30.1m. At the other
tolerance extremes, I
LIMIT(MAX)
for the circuit in question is
then simply:
56.7mV
30.1mΩ
I
LIMIT(MAX)
=
= 1.88A
With a knowledge of the application circuit’s maximum hot
swap load current, the power dissipation rating of the sense
resistor can be determined using P = I
2
R. Here, the current
is I
= 1.88A and the resistance R
=
(1.03)(R
) = 31.00m. Thus, the sense resistor’s
maximum power dissipation is:
P
MAX
= (1.88A)
2
X (31.00m) = 0.110W
LIMIT(MAX)
SENSE(MAX)
SENSE(NOM)
A 0.25W sense resistor is a good choice in this application.
PCB Layout Suggestions and Hints
4-Wire Kelvin Sensing
Because of the low value required for the sense resistor,
special care must be used to accurately measure the volt-
age drop across it. Specifically, the measurement technique
across R
SENSE
must employ 4-wire Kelvin sensing. This is
simply a means of ensuring that any voltage drops in the
power traces connected to the resistors are not picked up
by the signal conductors measuring the voltages across the
sense resistors.
Figure 13 illustrates how to implement 4-wire Kelvin sensing.
As the figure shows, all the high current in the circuit (from
V
IN
through R
SENSE
and then to the drain of the N-channel
power MOSFET) flows directly through the power PCB traces
and through R
SENSE
. The voltage drop across R
SENSE
is
sampled in such a way that the high currents through the
power traces will not introduce significant parasitic voltage
drops in the sense leads. It is recommended to connect
the hot swap controller’s sense leads directly to the sense
resistor’s metalized contact pads. The Kelvin sense signal
traces should be symmetrical with equal length and width,
kept as short as possible, and isolated from any noisy signals
and planes.
Additionally, for designs that implement Kelvin sense con-
nections that exceed 1" in length and/or if the Kelvin (signal)
traces are vulnerable to noise possibly being injected onto
these signals, the example circuit shown in Figure 14 can
be implemented to combat noisy environments. This circuit
implements a 1.6 MHz low-pass filter to attenuate higher
frequency disturbances on the current sensing circuitry.
However, individual system analysis should be used to de-
termine if filtering is necessary and to select the appropriate
cutoff frequency for each specific application.
Other Layout Considerations
Figure 15 is a suggested PCB layout diagram for the MIC2592B
power traces, Kelvin sense connections, and capacitor com-
ponents. In this illustration, only the 12V Slot B is shown but
a similar approach is suggested for both slots of each Main
power rail (12V and 3.3V). Many hot swap applications will
require load currents of several amperes. Therefore, the
power (12VIN and Return, 3VIN and Return) trace widths
(W) need to be wide enough to allow the current to flow while
the rise in temperature for a given copper plate (e.g., 1oz.
or 2oz.) is kept to a maximum of 10°C to 25°C. The return
(or power ground) trace should be the same width as the
positive voltage power traces (input/load) and isolated from
any ground and signal planes so that the controller’s power
is common mode. Also, these traces should be as short as
possible in order to minimize the IR drops between the input
and the load. As indicated in the Pin Description section, an
external connection must be made that ties together both
channel inputs ((+) Kelvin sense) of each Main power rail (i.e.,
3VINA and 3VINB, 12VINA and 12VINB must be externally
connected). These connections should be implemented di-
rectly at the chip. Insure that the voltage drop between the
two (+) Kelvin sense inputs for each rail is no greater than
0.2mV by using a common power path for the two inputs
相關PDF資料
PDF描述
MIC2592B-2YTQ Dual-Slot PCI Express Hot-Plug Controller
MIC2592B-3BTQ Dual-Slot PCI Express Hot-Plug Controller
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相關代理商/技術參數
參數描述
MIC2592B-2BTQ TR 功能描述:IC PCI HOT PLUG CTLR DUAL 48TQFP RoHS:否 類別:集成電路 (IC) >> PMIC - 熱交換 系列:- 產品培訓模塊:Obsolescence Mitigation Program 標準包裝:100 系列:- 類型:熱插拔開關 應用:通用 內部開關:是 電流限制:可調 電源電壓:9 V ~ 13.2 V 工作溫度:-40°C ~ 150°C 安裝類型:表面貼裝 封裝/外殼:10-WFDFN 裸露焊盤 供應商設備封裝:10-TDFN-EP(3x3) 包裝:管件
MIC2592B-2YTQ 功能描述:熱插拔功率分布 Dual-slot PCI-Express Hot Swap Power Controller - Lead Free RoHS:否 制造商:Texas Instruments 產品:Controllers & Switches 電流限制: 電源電壓-最大:7 V 電源電壓-最小:- 0.3 V 工作溫度范圍: 功率耗散: 安裝風格:SMD/SMT 封裝 / 箱體:MSOP-8 封裝:Tube
MIC2592B-2YTQ TR 功能描述:熱插拔功率分布 Dual-slot PCI-Express Hot Swap Power Controller - Lead Free RoHS:否 制造商:Texas Instruments 產品:Controllers & Switches 電流限制: 電源電壓-最大:7 V 電源電壓-最小:- 0.3 V 工作溫度范圍: 功率耗散: 安裝風格:SMD/SMT 封裝 / 箱體:MSOP-8 封裝:Tube
MIC2593-2BTQ 功能描述:IC CTRLR HOTPLUG PCI DUAL 48TQFP RoHS:否 類別:集成電路 (IC) >> PMIC - 熱交換 系列:- 產品培訓模塊:Obsolescence Mitigation Program 標準包裝:100 系列:- 類型:熱插拔開關 應用:通用 內部開關:是 電流限制:可調 電源電壓:9 V ~ 13.2 V 工作溫度:-40°C ~ 150°C 安裝類型:表面貼裝 封裝/外殼:10-WFDFN 裸露焊盤 供應商設備封裝:10-TDFN-EP(3x3) 包裝:管件
MIC2593-2BTQ TR 功能描述:IC PCI HOT PLUG CTLR DUAL 48TQFP RoHS:否 類別:集成電路 (IC) >> PMIC - 熱交換 系列:- 產品培訓模塊:Obsolescence Mitigation Program 標準包裝:100 系列:- 類型:熱插拔開關 應用:通用 內部開關:是 電流限制:可調 電源電壓:9 V ~ 13.2 V 工作溫度:-40°C ~ 150°C 安裝類型:表面貼裝 封裝/外殼:10-WFDFN 裸露焊盤 供應商設備封裝:10-TDFN-EP(3x3) 包裝:管件
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