CXSD62118单相恒定时间同步的PWM控制器驱动N通道mosfet低压芯片组RAM电源

首页 > 产品中心 > 电源管理 > DC降压型转换器 > Buck降压型芯片 >CXSD62118单相恒定时间同步的PWM控制器驱动N通道mosfet低压芯片组RAM电源

CXSD62118在功率因数调制（PFM）或脉冲宽度调制（PWM）模式下都能提供良好的瞬态响应和准确的直流电压输出。在脉冲频率模式（PFM）下，CXSD62118在轻到重负载负载下都能提供非常高的效率-
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产品简介

目录gTA嘉泰姆

1.产品概述         2.产品特点gTA嘉泰姆
3.应用范围       4.下载产品资料PDF文档 gTA嘉泰姆
5.产品封装图                     6.电路原理图             gTA嘉泰姆
7.功能概述       8.相关产品gTA嘉泰姆

一,产品概述(General Description) gTA嘉泰姆

The CXSD62118 is a single-phase, constant-on-time,synchronous PWM controller, which drives N-channel MOSFETs. The CXSD62118 steps down high voltage to generate low-voltage chipset or RAM supplies in notebook computers.gTA嘉泰姆
The CXSD62118 provides excellent transient response and accurate DC voltage output in either PFM or PWM Mode.In Pulse Frequency Mode (PFM), the CXSD62118 provides very high efficiency over light to heavy loads with loading-gTA嘉泰姆
modulated switching frequencies. In PWM Mode, the converter works nearly at constant frequency for low-noise requirements.gTA嘉泰姆
The CXSD62118 is equipped with accurate positive current-limit, output under-voltage, and output over-voltage protections, perfect for NB applications. The Power-On-Reset function monitors the voltage on VCC to prevent wrong operation during power-on. The CXSD62118 has a 1ms digital soft-start and built-in an integrated output discharge method for soft-stop. An internal integratedgTA嘉泰姆
soft-start ramps up the output voltage with programmable slew rate to reduce the start-up current. A soft-stop function actively discharges the output capacitors with controlled reverse inductor current.gTA嘉泰姆
The CXSD62118 is available in 10pin TDFN 3x3 package.gTA嘉泰姆
二.产品特点(Features)gTA嘉泰姆

Adjustable Output Voltage from +0.7V to +5.5VgTA嘉泰姆
- 0.7V Reference VoltagegTA嘉泰姆
- ±1% Accuracy Over-TemperaturegTA嘉泰姆
Operates from an Input Battery Voltage Range ofgTA嘉泰姆
+1.8V to +28VgTA嘉泰姆
Power-On-Reset Monitoring on VCC PingTA嘉泰姆
Excellent Line and Load Transient ResponsesgTA嘉泰姆
PFM Mode for Increased Light Load EfficiencygTA嘉泰姆
Selectable PWM Frequency from 4 Preset ValuesgTA嘉泰姆
Integrated MOSFET DriversgTA嘉泰姆
Integrated Bootstrap Forward P-CH MOSFETgTA嘉泰姆
Adjustable Integrated Soft-Start and Soft-StopgTA嘉泰姆
Selectable Forced PWM or Automatic PFM/PWM ModegTA嘉泰姆
Power Good MonitoringgTA嘉泰姆
70% Under-Voltage ProtectiongTA嘉泰姆
125% Over-Voltage ProtectiongTA嘉泰姆
Adjustable Current-Limit ProtectiongTA嘉泰姆
- Using Sense Low-Side MOSFET’s RDS(ON)gTA嘉泰姆
Over-Temperature ProtectiongTA嘉泰姆
TDFN-10 3x3 PackagegTA嘉泰姆
Lead Free and Green Devices AvailablegTA嘉泰姆
三,应用范围 (Applications)gTA嘉泰姆

NotebookgTA嘉泰姆
Table PCgTA嘉泰姆
Hand-Held PortablegTA嘉泰姆
AIO PCgTA嘉泰姆
四.下载产品资料PDF文档 gTA嘉泰姆

需要详细的PDF规格书请扫一扫微信联系我们，还可以获得免费样品以及技术支持！gTA嘉泰姆

QQ截图20160419174301.jpg gTA嘉泰姆

五,产品封装图 (Package)gTA嘉泰姆

gTA嘉泰姆

六.电路原理图gTA嘉泰姆

gTA嘉泰姆

七,功能概述gTA嘉泰姆

Input Capacitor Selection (Cont.)gTA嘉泰姆
higher than the maximum input voltage. The maximum RMS current rating requirement is approximatelygTA嘉泰姆

IOUT/2,where IOUT is the load current. During power-up, the input capacitors have to handle great gTA嘉泰姆

amount of surge current.For low-duty notebook appliactions, ceramic capacitor is recommended. ThegTA嘉泰姆

capacitors must be connected be-tween the drain of high-side MOSFET and the source of low-side gTA嘉泰姆

MOSFET with very low-impeadance PCB layoutgTA嘉泰姆
MOSFET SelectiongTA嘉泰姆
The application for a notebook battery with a maximum voltage of 24V, at least a minimum 30V MOSFETsgTA嘉泰姆

should be used. The design has to trade off the gate charge with the RDS(ON) of the MOSFET:gTA嘉泰姆
For the low-side MOSFET, before it is turned on, the body diode has been conducting. The low-side MOSFETgTA嘉泰姆

driver will not charge the miller capacitor of this MOSFET.In the turning off process of the low-side MOSFET,gTA嘉泰姆

the load current will shift to the body diode first. The high dv/dt of the phase node voltage will charge the gTA嘉泰姆

miller capaci-tor through the low-side MOSFET driver sinking current path. This results in much less switchinggTA嘉泰姆

loss of the low-side MOSFETs. The duty cycle is often very small in high battery voltage applications, and the gTA嘉泰姆

low-side MOSFET will conduct most of the switching cycle; therefore, when using smaller RDS(ON) of the low-side MOSFET, the con-verter can reduce power loss. The gate charge for this MOSFET is usually the gTA嘉泰姆

secondary consideration. The high-side MOSFET does not have this zero voltage switch- ing condition;gTA嘉泰姆

in addition, because it conducts for less time compared to the low-side MOSFET, the switching gTA嘉泰姆

loss tends to be dominant. Priority should be given to the MOSFETs with less gate charge, so gTA嘉泰姆

that both the gate driver loss and switching loss will be minimized.gTA嘉泰姆

The selection of the N-channel power MOSFETs are determined by the R DS(ON), reversinggTA嘉泰姆

transfer capaci-tance (CRSS) and maximum output current requirement. The losses in the gTA嘉泰姆

MOSFETs have two components:conduction loss and transition loss. For the high-side and gTA嘉泰姆

low-side MOSFETs, the losses are approximately given by the following equations:gTA嘉泰姆

Phigh-side = IOUT (1+ TC)(RDS(ON))D + (0.5)( IOUT)(VIN)( tSW)FSWgTA嘉泰姆
Plow-side = IOUT (1+ TC)(RDS(ON))(1-D)gTA嘉泰姆
Where I is the load current OUTgTA嘉泰姆
TC is the temperature dependency of RDS(ON)gTA嘉泰姆
FSW is the switching frequencygTA嘉泰姆
tSW is the switching intervalgTA嘉泰姆
D is the duty cyclegTA嘉泰姆
Note that both MOSFETs have conduction losses while the high-side MOSFET includes an additional gTA嘉泰姆

transition loss.The switching interval, tSW, is the function of the reverse transfer capacitance CRSS. gTA嘉泰姆

The (1+TC) term is a factor in the temperature dependency of the RDS(ON) and can be extracted gTA嘉泰姆

from the “RDS(ON) vs. Temperature” curve of the power MOSFET.gTA嘉泰姆
Layout ConsiderationgTA嘉泰姆
In any high switching frequency converter, a correct layout is important to ensure proper operation gTA嘉泰姆

of the regulator.With power devices switching at higher frequency, the resulting current transient will gTA嘉泰姆

cause voltage spike across the interconnecting impedance and parasitic circuit elements. As an example,gTA嘉泰姆

consider the turn-off transition of the PWM MOSFET. Before turn-off condition, the MOSFET is carryinggTA嘉泰姆

the full load current. During turn-off,current stops flowing in the MOSFET and is freewheeling by the gTA嘉泰姆

low side MOSFET and parasitic diode. Any parasitic inductance of the circuit generates a large voltage gTA嘉泰姆

spike during the switching interval. In general, using short and wide printed circuit traces shouldgTA嘉泰姆

minimize interconnect-ing impedances and the magnitude of voltage spike.gTA嘉泰姆
Besides, signal and power grounds are to be kept sepa-rating and finally combined using ground gTA嘉泰姆

plane construc-tion or single point grounding. The best tie-point between the signal ground and the gTA嘉泰姆

power ground is at the nega-tive side of the output capacitor on each channel, where there is less gTA嘉泰姆

noise. Noisy traces beneath the IC are not recommended. Below is a checklist for your layout:gTA嘉泰姆
· Keep the switching nodes (UGATE, LGATE, BOOT,and PHASE) away from sensitive small signal gTA嘉泰姆

nodes since these nodes are fast moving signals.Therefore, keep traces to these nodes as short asgTA嘉泰姆
possible and there should be no other weak signal traces in parallel with theses traces on any layer.gTA嘉泰姆

Layout Consideration (Cont.)gTA嘉泰姆
· The signals going through theses traces have both high dv/dt and high di/dt with high peak gTA嘉泰姆

charging and discharging current. The traces from the gate drivers to the MOSFETs (UGATE and gTA嘉泰姆

LGATE) should be short and wide.gTA嘉泰姆
· Place the source of the high-side MOSFET and the drain of the low-side MOSFET as close as gTA嘉泰姆

possible.Minimizing the impedance with wide layout plane be-tween the two pads reduces the gTA嘉泰姆

voltage bounce of the node. In addition, the large layout plane between the drain of the gTA嘉泰姆

MOSFETs (VIN and PHASE nodes) can get better heat sinking.gTA嘉泰姆

The GND is the current sensing circuit reference ground and also the power ground of the gTA嘉泰姆

LGATE low-side MOSFET. On the other hand, the GND trace should be a separate trace andgTA嘉泰姆

independently go to the source of the low-side MOSFET. Besides, the cur-rent sense resistor gTA嘉泰姆

should be close to OCSET pin to avoid parasitic capacitor effect and noise coupling.gTA嘉泰姆

· Decoupling capacitors, the resistor-divider, and boot capacitor should be close to their pins. gTA嘉泰姆

(For example,place the decoupling ceramic capacitor close to the drain of the high-side MOSFETgTA嘉泰姆

as close as possible.)gTA嘉泰姆
· The input bulk capacitors should be close to the drain of the high-side MOSFET, and the outputgTA嘉泰姆

bulk capaci-tors should be close to the loads. The input capaci-tor’s ground should be close to thegTA嘉泰姆

grounds of the output capacitors and low-side MOSFET.gTA嘉泰姆
· Locate the resistor-divider close to the FB pin to mini-mize the high impedance trace. In addition, gTA嘉泰姆

FB pin traces can’t be close to the switching signal traces (UGATE, LGATE, BOOT, and PHASE).gTA嘉泰姆

八,相关产品 更多同类产品...... gTA嘉泰姆

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Part_No gTA嘉泰姆	Package gTA嘉泰姆	ArchigTA嘉泰姆 tectugTA嘉泰姆	PhasegTA嘉泰姆	No.ofgTA嘉泰姆 PWMgTA嘉泰姆 OutputgTA嘉泰姆	Output gTA嘉泰姆 CurrentgTA嘉泰姆 (A) gTA嘉泰姆	InputgTA嘉泰姆 Voltage (V) gTA嘉泰姆		ReferencegTA嘉泰姆 VoltagegTA嘉泰姆 (V) gTA嘉泰姆	Bias gTA嘉泰姆 VoltagegTA嘉泰姆 (V) gTA嘉泰姆	QuiescentgTA嘉泰姆 CurrentgTA嘉泰姆 (uA) gTA嘉泰姆
Part_No gTA嘉泰姆	Package gTA嘉泰姆	ArchigTA嘉泰姆 tectugTA嘉泰姆	PhasegTA嘉泰姆	No.ofgTA嘉泰姆 PWMgTA嘉泰姆 OutputgTA嘉泰姆	Output gTA嘉泰姆 CurrentgTA嘉泰姆 (A) gTA嘉泰姆	mingTA嘉泰姆	maxgTA嘉泰姆	ReferencegTA嘉泰姆 VoltagegTA嘉泰姆 (V) gTA嘉泰姆	Bias gTA嘉泰姆 VoltagegTA嘉泰姆 (V) gTA嘉泰姆	QuiescentgTA嘉泰姆 CurrentgTA嘉泰姆 (uA) gTA嘉泰姆
CXSD6273gTA嘉泰姆	SOP-14gTA嘉泰姆 QSOP-16gTA嘉泰姆 QFN4x4-16gTA嘉泰姆	VM gTA嘉泰姆	1 gTA嘉泰姆	1 gTA嘉泰姆	30gTA嘉泰姆	2.9 gTA嘉泰姆	13.2gTA嘉泰姆	0.9gTA嘉泰姆	12 gTA嘉泰姆	8000gTA嘉泰姆
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CXSD6296A\|B\|C\|DgTA嘉泰姆	SOP8PgTA嘉泰姆	VMgTA嘉泰姆	1gTA嘉泰姆	1gTA嘉泰姆	25gTA嘉泰姆	3gTA嘉泰姆	13.2gTA嘉泰姆	0.6\|0.8gTA嘉泰姆	5~12gTA嘉泰姆	1200gTA嘉泰姆
CXSD6297gTA嘉泰姆	TDFN3x3-10gTA嘉泰姆	VMgTA嘉泰姆	1gTA嘉泰姆	1gTA嘉泰姆	25gTA嘉泰姆	4gTA嘉泰姆	13.2gTA嘉泰姆	0.8gTA嘉泰姆	5~12gTA嘉泰姆	2000gTA嘉泰姆
CXSD6298gTA嘉泰姆	TDFN3x3-10gTA嘉泰姆	COTgTA嘉泰姆	1gTA嘉泰姆	1gTA嘉泰姆	25gTA嘉泰姆	4.5gTA嘉泰姆	25gTA嘉泰姆	0.6gTA嘉泰姆	5~12gTA嘉泰姆	80gTA嘉泰姆
CXSD6299\|AgTA嘉泰姆	SOP-8PgTA嘉泰姆	VMgTA嘉泰姆	1gTA嘉泰姆	1gTA嘉泰姆	25gTA嘉泰姆	4.5gTA嘉泰姆	13.2gTA嘉泰姆	0.8gTA嘉泰姆	5~12gTA嘉泰姆	16000gTA嘉泰姆
CXSD62100gTA嘉泰姆	TQFN3x3-10gTA嘉泰姆	VMgTA嘉泰姆	1gTA嘉泰姆	1gTA嘉泰姆	25gTA嘉泰姆	4.5gTA嘉泰姆	13.2gTA嘉泰姆	0.6gTA嘉泰姆	5~12gTA嘉泰姆	2500gTA嘉泰姆
CXSD62101\|LgTA嘉泰姆	TDFN3x3-10gTA嘉泰姆	COTgTA嘉泰姆	1gTA嘉泰姆	1gTA嘉泰姆	30gTA嘉泰姆	3gTA嘉泰姆	25gTA嘉泰姆	0.8gTA嘉泰姆	5~12gTA嘉泰姆	2000gTA嘉泰姆
CXSD62102gTA嘉泰姆	TQFN3x3-16gTA嘉泰姆	COTgTA嘉泰姆	1gTA嘉泰姆	1gTA嘉泰姆	30gTA嘉泰姆	1.8gTA嘉泰姆	28gTA嘉泰姆	0.6gTA嘉泰姆	5gTA嘉泰姆	600gTA嘉泰姆
CXSD62102AgTA嘉泰姆	TQFN 3x3 16gTA嘉泰姆	COTgTA嘉泰姆	1gTA嘉泰姆	1gTA嘉泰姆	30gTA嘉泰姆	1.8gTA嘉泰姆	28gTA嘉泰姆	0.6gTA嘉泰姆	5gTA嘉泰姆	600gTA嘉泰姆
CXSD62103gTA嘉泰姆	QFN4x4-24gTA嘉泰姆	VMgTA嘉泰姆	2gTA嘉泰姆	1gTA嘉泰姆	50gTA嘉泰姆	4.5gTA嘉泰姆	13.2gTA嘉泰姆	0.6gTA嘉泰姆	5~12gTA嘉泰姆	5000gTA嘉泰姆
CXSD62104gTA嘉泰姆	TQFN4x4-24gTA嘉泰姆	COTgTA嘉泰姆	1gTA嘉泰姆	2gTA嘉泰姆	15gTA嘉泰姆	6gTA嘉泰姆	25gTA嘉泰姆	2gTA嘉泰姆	NgTA嘉泰姆	550gTA嘉泰姆
CXSD62105gTA嘉泰姆	TQFN4x4-24gTA嘉泰姆	COTgTA嘉泰姆	1gTA嘉泰姆	2gTA嘉泰姆	15gTA嘉泰姆	6gTA嘉泰姆	25gTA嘉泰姆	2gTA嘉泰姆	NgTA嘉泰姆	550gTA嘉泰姆
CXSD62106\|AgTA嘉泰姆	TQFN4x4-4gTA嘉泰姆 TQFN3x3-20gTA嘉泰姆	COTgTA嘉泰姆	1gTA嘉泰姆	2gTA嘉泰姆	20gTA嘉泰姆	3gTA嘉泰姆	28gTA嘉泰姆	0.75gTA嘉泰姆	5gTA嘉泰姆	800gTA嘉泰姆
CXSD62107gTA嘉泰姆	TQFN3x3-16gTA嘉泰姆	COTgTA嘉泰姆	1gTA嘉泰姆	1gTA嘉泰姆	20gTA嘉泰姆	1.8gTA嘉泰姆	28gTA嘉泰姆	0.75gTA嘉泰姆	5gTA嘉泰姆	400gTA嘉泰姆
CXSD62108gTA嘉泰姆	QFN3.5x3.5-14gTA嘉泰姆 TQFN3x3-16gTA嘉泰姆	COTgTA嘉泰姆	1gTA嘉泰姆	1gTA嘉泰姆	20gTA嘉泰姆	1.8gTA嘉泰姆	28gTA嘉泰姆	0.75gTA嘉泰姆	5gTA嘉泰姆	400gTA嘉泰姆
CXSD62109gTA嘉泰姆	TQFN3x3-16gTA嘉泰姆	COTgTA嘉泰姆	1gTA嘉泰姆	2gTA嘉泰姆	20gTA嘉泰姆	1.8gTA嘉泰姆	28gTA嘉泰姆	0.75gTA嘉泰姆	5gTA嘉泰姆	400gTA嘉泰姆
CXSD62110gTA嘉泰姆	QFN3x3-20gTA嘉泰姆 TQFN3x3-16gTA嘉泰姆	COTgTA嘉泰姆	1gTA嘉泰姆	2gTA嘉泰姆	20gTA嘉泰姆	3gTA嘉泰姆	28gTA嘉泰姆	1.8\|1.5\|0.5gTA嘉泰姆	5gTA嘉泰姆	740gTA嘉泰姆
CXSD62111gTA嘉泰姆	TQFN4x4-24gTA嘉泰姆 \|QFN3x3-20gTA嘉泰姆	CMgTA嘉泰姆	1gTA嘉泰姆	2gTA嘉泰姆	15gTA嘉泰姆	5gTA嘉泰姆	28gTA嘉泰姆	0.5gTA嘉泰姆	NgTA嘉泰姆	3000gTA嘉泰姆
CXSD62112gTA嘉泰姆	TDFN3x3-10gTA嘉泰姆	COTgTA嘉泰姆	1gTA嘉泰姆	1gTA嘉泰姆	20gTA嘉泰姆	1.8gTA嘉泰姆	28gTA嘉泰姆	0.5gTA嘉泰姆	5gTA嘉泰姆	250gTA嘉泰姆
CXSD62113\|CgTA嘉泰姆	TQFN3x3-20gTA嘉泰姆	COTgTA嘉泰姆	1gTA嘉泰姆	2gTA嘉泰姆	15gTA嘉泰姆	6gTA嘉泰姆	25gTA嘉泰姆	2gTA嘉泰姆	NgTA嘉泰姆	550gTA嘉泰姆
CXSD62113EgTA嘉泰姆	TQFN 3x3 20gTA嘉泰姆	COTgTA嘉泰姆	2gTA嘉泰姆	2gTA嘉泰姆	11gTA嘉泰姆	6gTA嘉泰姆	25gTA嘉泰姆	2gTA嘉泰姆	NgTA嘉泰姆	550gTA嘉泰姆
CXSD62114gTA嘉泰姆	TQFN3x3-20gTA嘉泰姆	COTgTA嘉泰姆	2gTA嘉泰姆	2gTA嘉泰姆	11gTA嘉泰姆	5.5gTA嘉泰姆	25gTA嘉泰姆	2gTA嘉泰姆	NgTA嘉泰姆	280gTA嘉泰姆
CXSD62115gTA嘉泰姆	QFN4x4-24gTA嘉泰姆	VMgTA嘉泰姆	2gTA嘉泰姆	1gTA嘉泰姆	60gTA嘉泰姆	3.1gTA嘉泰姆	13.2gTA嘉泰姆	0.85gTA嘉泰姆	12gTA嘉泰姆	5000gTA嘉泰姆
CXSD62116A\|B\|CgTA嘉泰姆	SOP-8PgTA嘉泰姆	VMgTA嘉泰姆	1gTA嘉泰姆	1gTA嘉泰姆	20gTA嘉泰姆	2.9gTA嘉泰姆	13.2gTA嘉泰姆	0.8gTA嘉泰姆	12gTA嘉泰姆	16000gTA嘉泰姆
CXSD62117gTA嘉泰姆	SOP-20gTA嘉泰姆	VMgTA嘉泰姆	2gTA嘉泰姆	2gTA嘉泰姆	30gTA嘉泰姆	10gTA嘉泰姆	13.2gTA嘉泰姆	1gTA嘉泰姆	12gTA嘉泰姆	5000gTA嘉泰姆
CXSD62118gTA嘉泰姆	TDFN3x3-10gTA嘉泰姆	COTgTA嘉泰姆	1gTA嘉泰姆	1gTA嘉泰姆	25gTA嘉泰姆	1.8gTA嘉泰姆	28gTA嘉泰姆	0.7gTA嘉泰姆	5gTA嘉泰姆	250gTA嘉泰姆
CXSD62119gTA嘉泰姆	TQFN3x3-20gTA嘉泰姆	COTgTA嘉泰姆	2gTA嘉泰姆	1gTA嘉泰姆	40gTA嘉泰姆	1.8gTA嘉泰姆	25gTA嘉泰姆	REFIN SettinggTA嘉泰姆	5gTA嘉泰姆	700gTA嘉泰姆
CXSD62120gTA嘉泰姆	QFN 3x3 20gTA嘉泰姆 TQFN 3x3 16gTA嘉泰姆	COTgTA嘉泰姆	1gTA嘉泰姆	2gTA嘉泰姆	20gTA嘉泰姆	3gTA嘉泰姆	28gTA嘉泰姆	1.8\|1.5 1.35\|1.2 0.5gTA嘉泰姆	5gTA嘉泰姆	800gTA嘉泰姆
CXSD62121AgTA嘉泰姆	TQFN3x3 20gTA嘉泰姆	COTgTA嘉泰姆	1gTA嘉泰姆	2gTA嘉泰姆	15gTA嘉泰姆	3gTA嘉泰姆	28gTA嘉泰姆	0.75gTA嘉泰姆	5gTA嘉泰姆	220gTA嘉泰姆
CXSD62121BgTA嘉泰姆	TQFN3x3 20gTA嘉泰姆	COTgTA嘉泰姆	1gTA嘉泰姆	2gTA嘉泰姆	15gTA嘉泰姆	3gTA嘉泰姆	28gTA嘉泰姆	0.75gTA嘉泰姆	5gTA嘉泰姆	220gTA嘉泰姆
CXSD62121gTA嘉泰姆	TQFN3x3-20gTA嘉泰姆	COTgTA嘉泰姆	1gTA嘉泰姆	2gTA嘉泰姆	20gTA嘉泰姆	3gTA嘉泰姆	28gTA嘉泰姆	0.75gTA嘉泰姆	5gTA嘉泰姆	180gTA嘉泰姆

gTA嘉泰姆

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