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MSM7541GS-K

更新时间：2024-10-29 13:08:53

品牌：OKI

描述：PCM Codec, MU-Law, 1-Func, CMOS, PDSO24, 0.430 INCH, 1.27 MM PITCH, PLASTIC, SOP-24

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概述
规格参数
数据手册

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MSM7541GS-K 概述

PCM Codec, MU-Law, 1-Func, CMOS, PDSO24, 0.430 INCH, 1.27 MM PITCH, PLASTIC, SOP-24 编解码器

MSM7541GS-K 规格参数

生命周期：	Obsolete	零件包装代码：	SOIC
包装说明：	SOP,	针数：	24
Reach Compliance Code：	unknown	HTS代码：	8542.39.00.01
风险等级：	5.84	压伸定律：	MU-LAW
滤波器：	YES	JESD-30 代码：	R-PDSO-G24
长度：	15.95 mm	功能数量：	1
端子数量：	24	工作模式：	SYNCHRONOUS
最高工作温度：	85 °C	最低工作温度：	-30 °C
封装主体材料：	PLASTIC/EPOXY	封装代码：	SOP
封装形状：	RECTANGULAR	封装形式：	SMALL OUTLINE
认证状态：	Not Qualified	座面最大高度：	2.5 mm
标称供电电压：	3.3 V	表面贴装：	YES
技术：	CMOS	电信集成电路类型：	PCM CODEC
温度等级：	OTHER	端子形式：	GULL WING
端子节距：	1.27 mm	端子位置：	DUAL
宽度：	7.9 mm	Base Number Matches：	1

MSM7541GS-K 数据手册

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E2U0014-28-81

This version: Aug. 1998

Previous version: Nov. 1996

¡ Semiconductor

MSM7541/7542

¡ Semiconductor

MSM7541/7542

Single Rail CODEC

GENERAL DESCRIPTION

The MSM7541 and MSM7542 are single-channel CODEC CMOS ICs for voice signals ranging

from 300 to 3400 Hz. These devices contain filters for A/D and D/A conversion.

Designed especially for a single-power supply and low-power applications, these devices are

optimized for telephone terminals in digital wireless systems.

The MSM7541 and MSM7542 use newly designed operational amplifiers to maintain small

current deviations caused by power voltage fluctuations.

The devices use the same transmission clocks as those used in the MSM7508B and MSM7509B.

The analog output signal, which is of a differential type, directly drives a piezoelectric type

handset receiver.

FEATURES

• Single power supply: +3.0 V to +3.8 V

• Low power consumption

Operating mode:

Power save mode:

Power down mode:

23 mW Typ.

1 mW Typ.

0.04 mW Typ.

= 3.3 V

• ITU-T Companding law

MSM7541:

MSM7542:

m-law

A-law

• Built-in PLL eliminates a master clock

• Serial data rate: 64/128/256/512/1024/2048 kHz

96/192/384/768/1536/1544/200 kHz

• Adjustable transmit gain

• Adjustable receive gain

• Built-in reference voltage supply

• Built-in analog loop back test mode

• Differential type analog output. Directly drives a piezoelectric type receiver equivalent to 1.2

kW + 55 nF

• Package options:

20-pin plastic skinny DIP (DIP20-P-300-2.54-S1) (Product name : MSM7541RS)

(Product name : MSM7542RS)

24-pin plastic SOP (SOP24-P-430-1.27-K)

(Product name : MSM7541GS-K)

(Product name : MSM7542GS-K)

26-pin plastic TSOP (TSOPII26/20-P-300-1.27-K) (Product name : MSM7541TS-K)

(Product name : MSM7542TS-K)

1/20

¡ Semiconductor

MSM7541/7542

BLOCK DIAGRAM

–

AIN+

AIN–

PCMOUT

XSYNC

Active

BPF

(8th)

Conv.

Transmit

Controller

BCLOCK

Auto

Zero

GSX

TMC

PLL

R–TIM

–

VFRO

LPF

(5th)

Conv.

Receive

Controller

RSYNC

PCMIN

PDN

PWD

Logic

Power

Down

PWI

V_DD

–

AOUT–

–

SGC

Voltage

Ref.

Signal

Ground

AOUT+

2/20

¡ Semiconductor

MSM7541/7542

PIN CONFIGURATION (TOP VIEW)

AOUT+

AOUT–

PWI

20 SGC

19 AIN+

18 AIN–

17 GSX

16 TMC

AOUT+

AOUT–

24 SGC

26 SGC

25 AIN+

24 AIN–

23 GSX

22 TMC

23 AIN+ AOUT+

22 AIN– AOUT–

21 GSX

20 NC

PWI

VFRO

19 TMC

18 NC

VFRO

V_DD

17 NC

V_DD

18 NC

16 AG

DG 10

PDN 11

17 AG

PDN 10

15 BCLOCK

14 XSYNC

14 AG

16 BCLOCK

15 XSYNC

14 PCMOUT

RSYNC 11

RSYNC 12

PDN

13 BCLOCK PCMIN 12

13 PCMOUT

PCMIN 13

NC : No connect pin

24-Pin Plastic SOP

RSYNC

12 XSYNC

NC : No connect pin

26-Pin Plastic TSOP

PCMIN 10

11 PCMOUT

NC : No connect pin

20-Pin Plastic Skinny DIP

3/20

¡ Semiconductor

MSM7541/7542

PIN AND FUNCTIONAL DESCRIPTIONS

AIN+, AIN–, GSX

Transmit analog input and transmit level adjustment.

AIN+ is a non-inverting input to the op-amp; AIN– is an inverting input to the op-amp; GSX is

connected to the output of the op-amp and is used to adjust the level, as shown below.

When not using AIN– and AIN+, connect AIN– to GSX and AIN+ to SG. During power saving

and power down modes, the GSX output is at AG voltage.

1) Inverting input type

R1 : variable

R2 > 20 kW

C1 > 1/(2 ¥ 3.14 ¥ 30 ¥ R1)

GSX

AIN–

AIN+

–

Analog input

Gain = R2/R1 £ 10

2) Non inverting input type

R3 > 20 kW

AIN+

AIN–

GSX

–

Analog input

R4 > 20 kW

R5 > 50 kW

C2 > 1/ (2 ¥ 3.14 ¥ 30 ¥ R5)

Gain = 1 + R4 / R3 £ 10

Analog signal ground.

VFRO

Receive filter output.

The output signal has an amplitude of 2.0 V above and below the signal ground voltage (SG)

when the digital signal of +3 dBmO is input to PCMIN and can drive a load of 20 kW or more.

For driving a load of 20 kW or less, the output signal of AOUT+ and AOUT– is available.

ToapplytheoutputsignalofAOUT+andAOUT–fordriving, connectaresistorof20kWormore

between the pins VFRO and PWI.

Whenaddingthefrequencycharacteristicstothereceivesignal, refertotheapplicationexample.

During power saving or power down mode, the output of VFRO is at the voltage level of AG.

4/20

¡ Semiconductor

MSM7541/7542

PWI, AOUT+, AOUT–

PWI is connected to the inverting input of the receive driver. The receive driver output is

connected to the AOUT– pin. Therefore, the receive level can be adjusted with the pins VFRO,

PWI, and AOUT–. When the PWI pin is not used, connect the PWI pin to the AOUT– pin, and

leave open the pins AOUT– and AOUT+. The output of AOUT+ is inverted with respect to the

output of AOUT–. Since the signal from which provides differential drives of an impedance of

1.2 kW + 55 nF, these outputs can directly be connected to a receiver of handset using a

piezoelectric earphone. Refer to the application example.

R6 > 20 kW

ZL ≥ 2.4 kW

VFRO

PWI

Receive Filter

–

Gain = VO/VI = 2 ¥ R7/R6 £ 2

AOUT–

–

AOUT+

During power saving and power down modes, the outputs of AOUT+ and AOUT– are in a high

impedance state.

The electrical driving capability of the AOUT– pin and AOUT+ pin is ±1.3 V maximum. The

output load resistor has a minimum value of 1.2 kW.

If an output amplitude less than ±1.3 V is allowed, these outputs can drive a load resistance less

than that described above.

For more details, refer to SINGLE POWER SUPPLY PCM CODEC APPLICATION NOTE.

Power supply for +3.0 V to +3.8 V. (Typically 3.3 V)

PCMIN

PCM signal input.

A serial PCM signal input to this pin is converted to an analog signal in synchronization with the

RSYNC signal and BCLOCK signal.

The data rate of the PCM signal is equal to the frequency of the BCLOCK signal.

The PCM signal is shifted at a falling edge of the BCLOCK signal and latched into the internal

The start of the PCM data (MSD) is identified at the rising edge of RSYNC.

BCLOCK

Shift clock signal input for the PCMIN and PCMOUT signal.

The frequency, equal to the data rate, is 64, 96, 128, 192, 256, 384, 512, 768, 1024, 1536, 1544, 2048,

or 200 kHz. Setting this signal to logic "1" or "0" drives both transmit and receive circuits to the

power saving state.

5/20

¡ Semiconductor

MSM7541/7542

RSYNC

Receive synchronizing signal input.

Eight required bits are selected from serial PCM signals on the PCMIN pin by the receive

synchronizing signal.

Signals in the receive section are synchronized by this synchronizing signal. This signal must be

synchronized in phase with the BCLOCK. The frequency should be 8 kHz ±50 ppm to guarantee

the AC characteristics which are mainly the frequency characteristics of the receive section.

However, if the frequency characteristic of an applied system is not specified exactly, this device

can operate in the range of 8 kHz ±2 kHz, but the electrical characteristics in this specification are

not guaranteed.

XSYNC

Transmit synchronizing signal input.

The PCM output signal from the PCMOUT pin is output in synchronization with this transmit

synchronizing signal. This synchronizing signal triggers the PLL and synchronizes all timing

signals of the transmit section.

This synchronizing signal must be synchronized in phase with BCLOCK.

The frequency should be 8 kHz ±50 ppm to guarantee the AC characteristics which are mainly

the frequency characteristics of the transmit section.

However, if the frequency characteristic of an applied system is not specified exactly, this device

can operate in the range of 8 kHz ±2 kHz, but the electrical characteristics in this specification are

not guaranteed.

Setting this signal to logic "1" or "0" drives both transmit and receive circuits to the power saving

state.

TMC

Control signal input for mode selection.

This pin select the normal operating mode or the analog loop-back mode.

In the analog loop-back mode, the receive filter output is connected to the transmit filter input

and the digital signal input to the PCMIN pin is converted from a digital to an analog signal (D/

A conversion). Next, the analog signal is converted to a digital signal (A/D conversion) through

the receive filter and transmit filter. The result is output to the PCMOUT pin.

When in the analog loop-back mode, the VFRO pin outputs the SG level. (signal ground)

TMC Input

< 0.16 ¥ V_DD

> 0.45 ¥ V_DD

Mode

Normal operation

Analog loop-back

6/20

¡ Semiconductor

MSM7541/7542

Ground for the digital signal circuits.

This ground is separate from the analog signal ground. The DG pin must be connected to the AG

pin on the printed circuit board to make a common analog ground.

PDN

Power down control signal.

A logic "0" level drives both transmit and receive circuits to a power down state.

PCMOUT

PCM signal output.

The PCM output signal is output from MSD in a sequential order, synchronizing with the rising

edge of the BCLOCK signal.

MSD may be output at the rising edge of the XSYNC signal, based on the timing between

BCLOCK and XSYNC.

This pin is in a high impedance state except during 8-bit PCM output. It is also in a high

impedance state during power saving or power down modes.

Apull-upresistormustbeconnectedtothispinbecauseitsoutputisconfiguredasanopendrain.

This device is compatible with the ITU-T recommendation on coding law and output coding

format.

The MSM7542(A-law) outputs the character signal, inverting the even bits.

PCMIN/PCMOUT

Input/Output Level

MSM7541 (m-law)

MSM7542 (A-law)

MSD

+Full scale

–0

–Full scale

7/20

¡ Semiconductor

MSM7541/7542

Signal ground voltage output.

The output voltage is 1/2 of the power supply voltage.

The output drive current capability is ±200 mA.

This pin provides the SG level for CODEC peripherals.

This output voltage level is undefined during power saving or power down modes.

SGC

Used to generate the signal ground voltage level by connecting a bypass capacitor.

Connect a 0.1 mF capacitor with excellent high frequency characteristics between the AG pin and

the SGC pin.

8/20

¡ Semiconductor

MSM7541/7542

ABSOLUTE MAXIMUM RATINGS

Parameter

Power Supply Voltage

Analog Input Voltage

Digital Input Voltage

Storage Temperature

Symbol

V_DD

Condition

Rating

Unit

—

0 to 7

V_AIN

–0.3 to V_DD+ 0.3

–55 to +150

V_DIN

T_STG

°C

RECOMMENDED OPERATING CONDITIONS

Parameter

Power Supply Voltage

Operating Temperature

Analog Input Voltage

Symbol

V_DDVoltage must be fixed

Condition

Min.

Typ.

3.3

Max.

Unit

3.0

–30

—

3.8

+85

1.4

—

+25

—

°C

V_AINConnect AIN– and GSX

V_PP

Digital Input High Voltage

Digital Input Low Voltage

V_IH

0.45 ¥ V_DD

—

V_DD

XSYNC, RSYNC, BCLOCK,

PCMIN, PDN, TMC

V_IL

0.16 ¥ V_DD

64, 128, 256, 512, 1024,

2048, 96, 192, 384, 768,

1536, 1544, 200

Clock Frequency

F_C

BCLOCK

kHz

Sync Pulse Frequency

Clock Duty Ratio

F_S

D_C

t_Ir

XSYNC, RSYNC

6.0

8.0

—

10.0

kHz

BCLOCK

Digital Input Rise Time

Digital Input Fall Time

XSYNC, RSYNC, BCLOCK,

PCMIN, PDN, TMC

—

t_If

—

t_XS

t_SX

t_RS

t_SR

BCLOCKÆXSYNC, See Timing Diagram

XSYNCÆBCLOCK, See Timing Diagram

BCLOCKÆRSYNC, See Timing Diagram

RSYNCÆBCLOCK, See Timing Diagram

100

1 BCLK

100

0.5

—

Transmit Sync Pulse Setting Time

Receive Sync Pulse Setting Time

—

Sync Pulse Width

PCMIN Set-up Time

PCMIN Hold Time

t_WSXSYNC, RSYNC

100

—

t_DS

t_DH

—

R_DLPull-up resistor

—

Digital Output Load

C_DL

V_off

—

100

+100

+10

500

Transmit gain stage, Gain = 1

Transmit gain stage, Gain = 10

XSYNC, RSYNC, BCLOCK

–100

–10

—

Analog Input Allowable DC Offset

Allowable Jitter Width

9/20

¡ Semiconductor

MSM7541/7542

ELECTRICAL CHARACTERISTICS

DC and Digital Interface Characteristics

(V_DD= 3.0 V to 3.8 V, Ta = –30°C to +85°C)

Parameter

Symbol

I_DD1

Condition

Min.

—

Typ.

10.0

7.0

Max.

12.0

9.0

Unit

_DD= 3.8 V

Operating mode

I_DD4

V_DD= 3.3 V

—

Power-save mode, PDN = 1,

Power Supply Current

I_DD2XSYNC or BCLOCK Æ OFF

—

0.3

1.0

I_DD3Power-down mode, PDN = 0

—

0.45 ¥

V_DD

Input High Voltage

Input Low Voltage

V_IH

V_IL

—

V_DD

0.16 ¥

V_DD

2.0

0.0

—

High Level Input Leakage Current

Low Level Input Leakage Current

Digital Output Low Voltage

Digital Output Leakage Current

Input Capacitance

I_IH

I_IL

—

0.0

—

0.2

—

0.5

V_OLPull-up resistance > 500 W

0.4

I_O

—

C_IN

—

10/20

¡ Semiconductor

MSM7541/7542

Transmit Analog Interface Characteristics

(V_DD= 3.0 V to 3.8 V, Ta = –30°C to +85°C)

Parameter

Input Resistance

Symbol

Condition

Min.

Typ.

—

Max.

—

Unit

R_INXAIN+, AIN–

Output Load Resistance

Output Load Capacitance

Output Amplitude

R_LGXGSX with respect to SG

—

C_LGX

V_OGX

—

–0.7

–20

—

+0.7

+20

Offset Voltage

V_OSGX

Gain = 1

—

Receive Analog Interface Characteristics

(V_DD= 3.0 V to 3.8 V, Ta = –30°C to +85°C)

Parameter

Input Resistance

Symbol

Condition

Min.

Typ.

—

Max.

—

Unit

R_INPWPWI

R_LVFVFRO with respect to SG

—

Output Load Resistance

Output Load Capacitance

AOUT+, AOUT– (each) with

R_LAO

1.2

—

respect to SG

C_LVFVFRO

—

100

C_LAOAOUT+, AOUT–

VFRO, R_L= 20 kW with

V_OVF

–1.0

—

+1.0

respect to SG

Output Amplitude

Offset Voltage

AOUT+, AOUT–, R_L= 1.2 kW

V_OAO

–1.3

–100

—

+1.3

+100

with respect to SG

V_OSVFVFRO with respect to SG

AOUT+, AOUT–, Gain = 1 with

V_OSAO

respect to SG

11/20

¡ Semiconductor

AC Characteristics

Parameter

MSM7541/7542

(V_DD= 3.0 V to 3.8 V, Ta = –30°C to +85°C)

Freq.

(Hz)

Level

(dBm0)

Symbol

Condition Min.

Typ.

Max.

Unit

Loss T1

Loss T2

Loss T3

Loss T4

Loss T5

Loss T6

LossR1

LossR2

LossR3

LossR4

LossR5

SD T1

SD T2

300

+0.1

Reference

—

–0.15

+0.20

1020

2020

3000

3400

300

Transmit Frequency Response

Receive Frequency Response

–0.15

+0.20

0.80

—

–0.15

—

+0.20

1020

2020

3000

3400

Reference

—

–0.15

0.0

+0.20

0.80

—

Transmit Signal to Distortion Ratio SD T3

1020

–30

–40

–45

—

SD T4

SD T5

SD R1

SD R2

30.5

—

Receive Signal to Distortion Ratio SD R3 1020

–30

–40

–45

—

SD R4

SD R5

GT T1

GT T2

—

–0.2

+0.2

–10

–40

–50

–55

Reference

–0.02

+0.2

+0.4

Transmit Gain Tracking

GT T3

GT T4

GT T5

GT R1

GT R2

GT R3

GT R4

GT R5

1020

–0.2

–0.5

–1.2

–0.2

+0.2

+0.5

+1.2

+0.2

–10

–40

–50

–55

Reference

–0.06

–0.10

–0.20

Receive Gain Tracking

–0.2

–1.0

–1.5

+0.2

+1.0

+1.5

*1 Psophometric filter is used

12/20

¡ Semiconductor

MSM7541/7542

AC Characteristics (Continued)

(V_DD= 3.0 V to 3.8 V, Ta = –30°C to +85°C)

Freq.

(Hz)

Level

(dBm0)

Parameter

Symbol

Condition Min.

Typ.

Max.

Unit

AIN = SG

—

Nidle T

—

–70

–68

Idle Channel Noise

dBmOp

Nidle R

AV T

*1 *2

V_DD= 3.3 V

Ta = 25°C

—

–76

–74

0.338

0.35

0.362

Absolute Level (Initial Difference)

Vrms

AV R

AV Tt

0.483

–0.2

0.50

—

0.518

+0.2

1020

V_DD= +3 to

Absolute Level

3.8 V

(Deviation of Temperature and Power)

Ta = –30

AV Rt

–0.2

—

+0.2

0.60

to +85°C

A to A

Absolute Delay

BCLOCK

= 64 kHz

tgd T1

tgd T2

tgd T3

tgd T4

tgd T5

tgdR1

tgdR2

tgdR3

tgdR4

tgdR5

CR T

500

600

—

0.19

0.11

0.02

0.05

0.07

0.00

0.09

0.12

0.75

0.35

0.125

0.75

0.35

0.125

0.75

—

Transmit Group Delay

1000

2600

2800

500

600

Receive Group Delay

Crosstalk Attenuation

1000

2600

2800

TRANS Æ RECV

RECV Æ TRANS

1020

CR R

—

*1 Psophometric filter is used

*2 Input "0" code to PCMIN

*3 AVR is defined at VFRO output

*4 Minimum value of the group delay distortion

13/20

¡ Semiconductor

MSM7541/7542

AC Characteristics (Continued)

(V_DD= 3.0 V to 3.8 V, Ta = –30°C to +85°C)

Freq.

(Hz)

4.6 kHz to

72 kHz

300 to

Level

(dBm0)

Parameter

Discrimination

Symbol

Condition Min.

Typ.

Max.

—

Unit

0 to

DIS

4000 Hz

4.6 kHz to

—

Out-of-band Spurious

–37.5

–52

–35

dBmO

3400

100 kHz

fa = 470

fb = 320

Intermodulation Distortion

IMD

–4

2fa – fb

—

–1.0

—

TMC = 1

PCMIN to

PCMOUT

D-to-D Mode Gain

—

1020

0 to

—

+1.0

PSR T

Power Supply Noise Rejection Ratio

50 mV_PP

—

PSR R 50 kHz

—

200

XD1

XD2

XD3

Digital Output Delay Time

C_L= 100 pF + 1 LSTTL

*1 The measurement under idle channel noise

14/20

¡ Semiconductor

MSM7541/7542

TIMING DIAGRAM

PCM Data Input/Output Timing

Transmit Timing

BCLOCK

XSYNC

t_XS

t_SX

t_WS

t_XD1

t_SD

MSD

t_XD2

t_XD3

PCMOUT

When t_XS£ 1/2 • Fc, the Delay of the MSD bit is defined as t_XD1

When t_SX£ 1/2 • Fc, the Delay of the MSD bit is defined as t_SD

Receive Timing

BCLOCK

t_RS

t_SR

t_WS

RSYNC

t_DS

t_DH

PCMIN

MSD

15/20

¡ Semiconductor

MSM7541/7542

APPLICATION CIRCUIT

Analog interface

Digital interface

+3.3 V

MSM7541/7542

0.1 mF

AIN–

PCMOUT

XSYNC

RSYNC

BCLOCK

PCMIN

PDN

PCM signal output

Analog input

51 kW

8 kHz SYNC signal input

GSX

AIN+

BCLOCK input

PCM data input

AOUT–

PWI

Power Down control input

Analog output

TMC

Analog loop-back

control input

VFRO

SGC

51 kW

0.1 mF

0 V

10 mF

0 to 10 W

1 mF

+3.3 V

V_DD

FREQUENCY CHARACTERISTICS ADJUSTMENT CIRCUIT

Microphone amp

Transmit frequency

characteristic

Adjustment determined with

C1, C2, R1, R2.

AIN–

GSX

AIN+

Receive frequency

characteristic

Adjustment determined with

C3, C4, R3, R4.

AOUT+

AOUT–

PWI

Receiver impedance to

1.2 kW + 55 nF

VFRO

R3 C3

16/20

¡ Semiconductor

MSM7541/7542

RECOMMENDATIONS FOR ACTUAL DESIGN

• Toassureproperelectricalcharacteristics,usebypasscapacitorswithexcellenthighfrequency

characteristics for the power supply and keep them as close as possible to the device pins.

• Connect the AG pin and the DG pin each other as close as possible. Connect to the system

ground with low impedance.

• Mount the device directly on the board when mounted on PCBs. Do not use IC sockets. If an

IC socket is unavoidable, use the short lead type socket.

• When mounted on a frame, use electro-magnetic shielding, if any electro-magnetic wave

source such as power supply transformers surround the device.

• Keep the voltage on the V pin not lower than –0.3 V even instantaneously to avoid latch-

up phenomenon when turning the power on.

• Use a low noise (particularly, low level type of high frequency spike noise or pulse noise)

powersupplytoavoiderroneousoperationandthedegradationofthecharacteristicsofthese

devices.

17/20

¡ Semiconductor

PACKAGE DIMENSIONS

DIP20-P-300-2.54-S1

MSM7541/7542

(Unit : mm)

Package material

Lead frame material

Pin treatment

Solder plate thickness

Package weight (g)

Epoxy resin

42 alloy

Solder plating

5 mm or more

1.49 TYP.

18/20

¡ Semiconductor

MSM7541/7542

(Unit : mm)

SOP24-P-430-1.27-K

Mirror finish

Package material

Lead frame material

Pin treatment

Solder plate thickness

Package weight (g)

Epoxy resin

42 alloy

Solder plating

5 mm or more

0.58 TYP.

Notes for Mounting the Surface Mount Type Package

The SOP, QFP, TSOP, SOJ, QFJ (PLCC), SHP and BGA are surface mount type packages, which

are very susceptible to heat in reflow mounting and humidity absorbed in storage.

Therefore, before you perform reflow mounting, contact Oki’s responsible sales person for the

product name, package name, pin number, package code and desired mounting conditions

(reflow method, temperature and times).

19/20

¡ Semiconductor

MSM7541/7542

(Unit : mm)

TSOPII26/20-P-300-1.27-K

Mirror finish

Package material

Lead frame material

Pin treatment

Solder plate thickness

Package weight (g)

Epoxy resin

42 alloy

Solder plating

5 mm or more

0.38 TYP.

Notes for Mounting the Surface Mount Type Package

The SOP, QFP, TSOP, SOJ, QFJ (PLCC), SHP and BGA are surface mount type packages, which

are very susceptible to heat in reflow mounting and humidity absorbed in storage.

Therefore, before you perform reflow mounting, contact Oki’s responsible sales person for the

product name, package name, pin number, package code and desired mounting conditions

(reflow method, temperature and times).

20/20

MSM7541GS-K 相关器件

型号	制造商	描述	价格	文档
MSM7541GS-VK	OKI	PCM Codec, MU-Law, 1-Func, PDSO24, 0.430 INCH, PLASTIC, SOP-24	获取价格
MSM7542	OKI	Single Rail CODEC	获取价格
MSM7542GS	OKI	PCM Codec, A-Law, 1-Func, PDSO24, 0.430 INCH, PLASTIC, SOP-24	获取价格
MSM7542GS-VK	OKI	PCM Codec, A-Law, 1-Func, PDSO24, 0.430 INCH, PLASTIC, SOP-24	获取价格
MSM7542RS	OKI	暂无描述	获取价格
MSM7543	OKI	Single Rail CODEC	获取价格
MSM7543GS-K	OKI	PCM Codec, MU-Law, 1-Func, CMOS, PDSO24, 0.430 INCH, 1.27 MM PITCH, PLASTIC, SOP-24	获取价格
MSM7543TS-K	OKI	PCM Codec, MU-Law, 1-Func, CMOS, PDSO20, 0.300 INCH, 1.27 MM PITCH, PLASTIC, TSOP2-26/20	获取价格
MSM7544	OKI	Single Rail CODEC	获取价格
MSM7544GS	OKI	PCM Codec, A-Law, 1-Func, PDSO24, 0.430 INCH, PLASTIC, SOP-24	获取价格