Samsung SGH-P400 Service Manual

GSM TELEPHONE

SGH-P400

SERVICE

Manual

GSM TELEPHONE CONTENTS

1. Specification

2. Circuit Description

3. Flow Chart of Troubleshooting

4. Exploded Views and Parts List

5. Electrical Parts List

6. Block Diagrams

7. PCB Diagrams

1. SGH-P400 Specification

1. GSM General Specification

GSM900

Phase 1

Freq. Band[MHz]

Uplink/Downlink

ARFCN range 1~124

Tx/Rx spacing 45MHz 45MHz 95MHz 80MHz

Mod. Bit rate/

Bit Period

Time Slot

Period/Frame Period

Modulation 0.3GMSK 0.3GMSK 0.3GMSK 0.3GMSK

MS Power 33dBm~13dBm 33dBm~5dBm 30dBm~0dBm 30dBm~0dBm

890~915
935~960

270.833kbps

3.692us

576.9us

4.615ms

EGSM 900

Phase 2

880~915
925~960

0~124 &

975~1023

270.833kbps

3.692us

576.9us

4.615ms

DCS1800

Phase 1

1710~1785
1805~1880

512~885 512~810

270.833kbps

3.692us

576.9us

4.615ms

PCS1900

1850~1910
1930~1990

270.833kbps

3.692us

576.9us

4.615ms

Power Class 5pcl ~ 15pcl 5pcl ~ 19pcl 0pcl ~ 15pcl 0pcl ~ 15pcl

Sensitivity -102dBm -102dBm -100dBm -100dBm

TDMA Mux 8 8 8 8

Cell Radius 35Km 35Km 2Km -

1-1

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SGH-P408 Specification

2. GSM TX power class

TX Power

control level

5 33±2 dBm

6 31±2 dBm

7 29±2 dBm

8 27±2 dBm

9 25±2 dBm

10 23±2 dBm

11 21±2 dBm

GSM900

TX Power

control level

0 30±3 dBm

1 28±3 dBm

2 26±3 dBm

3 24±3 dBm

4 22±3 dBm

5 20±3 dBm

6 18±3 dBm

DCS1800

TX Power

PCS1900

control level

0 30±3 dBm

1 28±3 dBm

2 26±3 dBm

3 24±3 dBm

4 22±3 dBm

5 20±3 dBm

6 18±3 dBm

12 19±2 dBm

13 17±2 dBm

14 15±2 dBm

15 13±2 dBm

16 11±3 dBm

17 9±3dBm

18 7±3 dBm

19 5±3 dBm

7 16±3 dBm

8 14±3 dBm

9 12±4 dBm

10 10±4 dBm

11 8±4dBm

12 6±4 dBm

13 4±4 dBm

14 2±5 dBm

7 16±3 dBm

8 14±3 dBm

9 12±4 dBm

10 10±4 dBm

11 8±4dBm

12 6±4 dBm

13 4±4 dBm

14 2±5 dBm

15 0±5 dBm

1-2

15 0±5 dBm

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2. SGH-P400 Circuit Description

1. SGH-P400 RF Circuit Description

1) RX PART

1. ASM(U1005)

ð 510

2. ASM Control Logic (U701, U702, U703)

ð

GSM Tx Mode H L L
DCS /PCS Tx Mode L H L
PCS Rx Mode L L H

Switching Tx, Rx path for GSM900, DCS1800 and PCS1900 by logic

controlling.

Truth Table

VC1 VC2 VC3

GSM / DCS Rx Mode L L L

3. FILTER

To convert Electromagnetic Field Wave to Acoustic Wave and then pass the
specific frequency band.

- GSM FILTER (C1003,C1004,L1001)
For filtering the frequency band between 925 ~ 960 MHz

ð

- DCS FILTER (C1005,C1006,L1002)
For filtering the frequency band 1805 and 1880 MHz.

ð

- PCS SAW FILTER (F1003,C1009,C1010,L1006)
For filtering the frequency band between 1930 and 1990 MHz

ð

4. TC-VCXO (OSC801)

To generate the 13MHz reference clock to drive the logic and RF.
After additional process, the reference clock is applied to the U900 Rx IQ
demodulator and Tx IQ modulator.

The oscillator for RX IQ demodulator and Tx modulator are controlled by
serial data to select channel and use fast lock mode for GPRS high class
operation.

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2-1

SGH-P400 Circuit Description

5. Si 4200 (U901)

This chip integrates three differential-input LNAs.
The GSM input supports the E-GSM, DCS input supports the DCS1800, PCS
input supports the PCS1900. The LNA inputs are matched to the 200 ohm
differential output SAW filters through eternal LC matching network.
Image-reject mixer downconverts the RF signal to a 100 KHz intermediate
frequency(IF) with the RFLO from SI4133T frequency synthesizer.
The RFLO frequency is between 1737.8 ~ 1989.9 MHz.
The Mixer output is amplified with an analog programmable gain

amplifier(PGA), which is controlled by AGAIN.

The quadrature IF signal is digitized with high resolution A/D converts (ADC).

6. Si 4201 (U900)

The SI4201 down-converts the ADC output to baseband with a digital

100 KHz quadrature LO signal.

Digital decimation and IIR filters perform channel selection to remove blocking
and reference interface signals. After channel selection, the digital output is
scaled with a digital PGA, which is controlled with the DGAIN. DACs drive a
differential analog signal onto the RXIP, RXIN, RXQP, RXQN pins to interface
to standard analog-input baseband IC.

2) TX PART

Baseband IQ signal fed into offset PLL, this function is included inside
of U902 chip.
SI4200 chip generates modulator signal which power level is about 1.5dBm
and fed into Power Amplifier(U1001).
The PA output power and power ramping are well controlled by Auto
Power Control circuit. We use offset PLL below,

GSM -35dBc

DCS -35dBc
PCS -35dBc

GSM -66dBc

DCS -65dBc
PCS -66dBc

GSM -75dBc

DCS -68dBc
PCS -75dBc

Modulation

Spectrum

200kHz offset
30 kHz bandwidth

400kHz offset
30 kHz bandwidth

600kHz ~ 1.8MHz offset
30 kHz bandwidth

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2. Baseband Circuit description of SGH-P400

1) PSC2106 & LTC 1734

1. Power Management

Seven low-dropout regulators designed specifically for GSM applications
power the terminal and help ensure optimal system performance and long

battery life.
A programmable boost converter provides support for 1.8V, and 3.0V SIMs,
while a self-resetting, electronically fused switch supplies power to external
accessories. Ancillary support functions, such as an LED driver and two
call-alert drivers, aid in reducing both board area and system complexity.

A three-wire serial interface unit(SIU) provides access to control and

configuration registers. This interface gives a microprocessor full control of

the PSC2106 and enables system designers to maximize both standby and
talk times.
Supervisory functions. including a reset generator, an input voltage monitor,
and a thermal monitor, support reliable system design. These functions
work together to ensure proper system behavior during start-up or in the
event of a fault condition(low microprocessor voltage, insufficient battery
energy, or excessive die temperature).

SGH-P400 Circuit Description

2. Battery Charge Management

A battery charge management block provides fast, efficient charging of a
single-cell Li-ion battery. Used in conjunction with a current-limited voltage
source and an external PMOS pass transistor, this block safely conditions
near-dead cells and provides the option of having fast-charge and top-off
controlled internally or by the system's microprocessor.

3. Backlight LED Driver

The backlight LED drivers are low-side, programmable current source
designed to control the brightness the keyboard and LCD illumination.
LED1_DRV is controlled via LED1_[0:2] and can be programmed to sink
from mA to 60mA in 7.5mA steps. LED2_DRV is controlled via LED2_[0:2]
and can be programmed to sink from 5 to 40mA in 5mA steps. Both LED
drivers are capable of sinking their maximum output current at a worst
worst case maximum output voltage of 0.6V. For efficient use, the LEDs
should be forward connected between the ma battery and their
corresponding LED driver output.

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SGH-P400 Circuit Description

2) Connector

1. LCD Connector

LCD is consisted of main LCD(color 65K TFD LCD). Chip select signals of
EMI part in the trident, CAM_CLCD_EN,
can enable main LCD. LED_EN signal enables white LED of main LCD.
This signal is from IO part of the DSP in the trident. RST signal from 2106
initiates the initial process of the LCD.
16-bit data lines(D(0)~D(15)) transfers data and commands to LCD through
emi_filter. Data and commands use A(2) signal. If this signal is high, Inputs
to LCD are commands. If it is low, Inputs to LCD are data. The signal
which informs the input or output state to LCD, is required. But this system
is not necessary this signal. So CP_WEN signal is used to write data or
commands to LCD.
Power signals for LCD are V_bat and V_ccd.
SPK1P and SPK1N from CSP1093 are used for audio speaker. And VIB_EN
from enables the motor.

2. JTAG Connector

Trident has two JTAG ports which are for ARM core and DSP
core(DSP16000). So this system has two port connector for these ports.
Pins' initials for ARM core are 'CP_' and pins' initials for DSP core are
'DSP_'.
CP_TDI and DSP_TDI signal are used for input of data. CP_TDO and
DSP_TDO signals are used for the output of the data. CP_TCK and
DSP_TCK signals are used for clock because JTAG communication is a
synchronous. CP_TMS and DSP_TMS signals are test mode signals. The
difference between these is the RESET_INT signal which is for ARM core
RESET.

3. IRDA

This system uses IRDA module, HSDL_3201, HP's. This has signals,
IRDA_EN(enable signal), IRDA_RX(input data) and IRDA_TX(output data).
These signals are connected to PPI of trident. It uses two power signals.
V_ccd is used for circuit and V_bat is used for LED.

3) IF connetor

It is 18-pin connector. They are designed to use SDS, DEBUG, DLC-DETECT,
JIG_ON, VEXT, VTEST, VF, CF, VBAT and GND. They connected to power
supply IC, microprocessor and signal processor IC.

2-4

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SGH-P400 Circuit Description

4) Audio

AOUTAP from CSP1093 is connected to the main speaker. AOUTAN is
connected to the speaker via audio-amp. AOUTBN and AOUTBP are connected
to the ear-mic speaker via ear-jack. MICIN and MICOUT are connected to the
main MIC. And AUXIN and AUXOUT are connected to the Ear-mic.

YMU762MA3 is a LSI for portable telephone that is capable of playing high
quality music by utilizing FM synthesizer and ADPCM decorder that are
included in this device.
As a synthesis, YMU762MA3 is equipped 16 voices with differenttones. Since
the device is capable of simultaneously generating up to synchronous with the
play of the FM synthesizer, various sampled voices can be used as sound
effects.
Since the play data of YMU762MA3 are interpreted at anytime through FIFO,
the length of the data(playing period) is not limited, so the device can
flexiblysupport application such as incoming call melody music distribution
service. The hardware sequencer built in this device allows playing of the
complex music without giving excessive load to the CPU of the portable
telephones. Moreover, the registers of the FM synthesizer can be operated
directly for real time sound generation, allowing, for example, utilization of
various sound effects when using the game software installed in the portable
telephone.
YMU759 includes a speaker amplifier with high ripple removal rate whose
maximum output is 550mW (SPVDD=3.6V). The device is also equipped with
conventional function including a vibartor and a circuit for controlling LEDs
synchornous with music.
For the headphone, it is provided with a stereophonic output terminal.
For the purpose of enabling YMU762MA3 to demonstarte its full capablities,
Yamaha purpose to use "SMAF:Synthetic music Mobile Application Format" as a
data distribution format that is compatible wiht multimedia. Since the SMAF
takes a structure that sets importance on the synchronization between sound
and images, various contents can be written into it including incoming call
melody with words that can be used for traning karaoke, and commercial
channel that combines texts, images and sounds, and others. The hardware
sequencer of YMU762MA3 directly interprets and plays blocks relevant to
systhesis (playing music and reproducing ADPCM with FM synthesizer) that are
included in data distributed in SMAF.

The vibrator motor driver is a low-side, programmable voltage source designed
to drive a small dc motor that silently alerts the user of an incoming call. The
driver is enabled by EN_VIB, and its voltage setting is determined by VIB[0:2].
Provided EN_VIB is a logic 1, the driver can be programmed to maintain a

2-5

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SGH-P400 Circuit Description

motor voltage of 1.1V to 2.5V in 20mV steps and while sinking up to 100mA.
For efficient use, the vibrator motor should be connected between the main
battery and the VIB_DRV output.

5) Memory

This system uses SHARP's memory, LRS1828A.
It is consisted of 128M bits flash memory and32M bits psuedo SRAM. It has
16 bit data line, D[0~15] which is connected to trident, LCD or CSP1093. It
has 22 bit address lines, A[1~22]. They are connected too. CP_CSROMEN and
CO_CSROM2EN signals, chip select signals in the trident enable two memories.
They use 3 volt supply voltage, V_ccd and 1.8 volt supply voltage, Vcc_1.8a in
the PSC2106. During wrting process, CP_WEN is low and it enables writing
process to flash memory and pseudo SRAM. During reading process, CP_OEN
is low and it output information which is located at the address from the
trident in the flash memory or SRAM to data lines. Each chip select signals in
the trident select memory among 2 flash memory and 2 SRAM. Reading or
writing procedure is processed after CP_WEN or CP_OEN is enabled. Memories
use FLASH_RESET, which is buffered signal of RESET from PSC2106, for ESD
protection. A[0] signal enables lower byte of pseudo SRAM and UPPER_BYTE
signal enables higher byte of pseudo SRAM.

6) Trident

Trident is consisted of ARM core and DSP core. It has 20K*16bits RAM
144K*16bits ROM in the DSP. It has 4K*32bits ROM and 2K*32bits RAM in the
ARM core. DSP is consisted of timer, one bit input/output unit(BIO), JTAG, EMI
and HDS(Hardware Development System). ARM core is consisted of EMI,
PIC(Programmable Interrupt Controller), reset/power/clock unit, DMA controller,
TIC(Test Interface Controller), peripheral bridge, PPI, SSI(Synchronous Serial
Interface), ACC(Asynchronous communications controllers), timer, ADC,
RTC(Real-Time Clock) and keyboard interface.
DSP_AB[0~8], address lines of DSP core and DSP_DB[0~15], data lines of
DSP core are connected to CSP1093. A[0~20], address lines of ARM core and
D[0~15], data lines of ARM core are connected to memory, LCD and YMU759.
ICP(Interprocessor Communication Port) controls the communication between
ARM core and DSP core.
CSROMEN, CSRAMEN and CS1N to CS4N in the ARM core are connected to
each memory. WEN and OEN control the process of memory. External
IRQ(Interrupt ReQuest) signals from each units, such as, YMU, Ear-jack,
Ear-mic and CSP1093, need the compatible process.

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SGH-P400 Circuit Description

Some PPI pins has many special functions. CP_KB[0~9] receive the status

from key FPCB and are used for the communicatios using
IRDA(IRDA_RX/TX/EN) and data link
cable(DEBUG_DTR/RTS/TXD/RXD/CTS/DSR). And UP_CS/SCLK/SDI, control
signals for PSC2006 are outputted through PPI pins. It has signal port for
charging(CHG_DET, CHG_STAT0), SIM_RESET and FLIP_SNS with which we
knows open.closed status of folder. It has JTAG control pins(TDI/TDO/TCK)
for ARM core and DSP core. It recieves 13MHz clock in CKI pin from external
TCXO and receives 32.768KHz clock from X1RTC. ADC(Analog to Digital
Convertor) part receives the status of temperature, battery type and battery
voltage. And control signals(DSP_INT, DSP_IO and DSP_RWN) for DSP core are
used. It enables main LCD and small LCD with DSP IP pins.

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SGH-P400 Circuit Description

7) CSP1093

CSP1093 integrates the timing and control functions for GSM 2+ mobile
application with the ADC and DAC functions. The CSP1093 interfaces to the
trident, via a 16-bit parallel interface. It serves as the interface that connects
a DSP to the RF circuitry in a GSM 2+ mobile telephone. DSP can load 148
bits of burst data into CSP1093’s internal register, and program CSP1093’s
event timing and control register with the exact time to send the burst. When
the timing portion of the event timing and control register matches the internal
quarter-bit counter and internal frame counter, the 148 bits in the internal
register are GMSK modulated according to GSM 2+ standards. The resulting
phase information is translated into I and Q differential output voltages that can
be connected directly to an RF modulator at the TXOP and TXON pins. The
DSP is notified when the transmission is completed. For receiving baseband
data, a DSP can program CSP1093’s event timing and control register with the
exact time to start receiving I and Q samples through TXIP and TXIN pins.
When that time is reached, the control portion of the event timing and control
register will start the baseband receive section converting I and Q sample
pairs. The samples are stored in a double-buffered register until the register
contains 32 sample pairs. CSP1093 then notifies the DSP which has ample time
to read the information out before the next 32 sample pairs are stored. The
voice band ADC converter issues an interrupt to the DSP whenever it finishes
converting a 16-bit PCM word. The DSP then reads the new input sample and
simultaneously loads the voice band output DAC converter with a new PCM
output word. The voice band output can be connected directly to a speaker via
AOUTAN and AOUTAP pins and be connected to a Ear-mic speaker via
AOUTBN and AOUTBP pins.

8) X-TAL(13MHz)

This system uses the 13MHz TCXO, TCO-9141B, Toyocom. AFC control signal
form CSP1093 controls frequency from 13MHz x-tal. It generates the clock
frequency. This clock is fed to CSP1093,Trident,YMU759 and Silab solution.

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3. SGH-P400 Flow Chart of Troubleshooting

1. Power On

' Power On ' does not work

Check the current

consumption

Current consumption

>=100mA

Yes

Check the V bat. Voltage

Voltage >= 3.3V

Yes

Check the pin of U100

pin#11 >= 2.8V

Yes

pin#39 and pin#42 =

2.8V

Yes

No

No

No

No

pin#9 = 1.8V

Download again

Charge the Battery

Check U100 and C117

No

Check U100 and C116

Check the clock signal at pin#3 of

OSC801

Freq = 13MHz ,

Vrms ≥ 300mV

and

Vpp=900mVpp

Yes

Check the initial operation

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Yes

No

3-1

Check the clock generation

circuit

(related to OSC801)

SGH-P400 Flow Chart of Troubleshooting

KEY_COL(2)

KEY_ROW(0)

RTCALARM
PWR_KEEP

Q100

3

2

CN100

6

6

11

5

5

22

VBAT

3344

54

UP_RST

53

UP_CLK

52

UP_IO

44

ADC_AUX1

45

ADC_AUX2

56

ADC_TRIG

3

VACC

2

VBAT

1

VEXT

43

BTEMP

46

PWR_SW1N

47

PWR_SW2

13

RTC_ALMN

21

PWR_KEEP

20

PSW1_BUF

14

INTRQ

15

SDI

16

SDO

17

SCLK

18

CSN

22

EN_3

23

EN_4[0]

24

EN_4[1]

25

EN_5

26

EN_5A

27

EN_5B

55

RING_PWM

57

GND

58

GND

59

GND

60

GNDG

7GG89GG10

49

50 51

K

SIM_CL

SIM_RST

5

C101
33PF

48

29

M
VSI

SIM_IO

U100

VIB_DRV

RING_DRV

4

7

C106
100NF

30

VREF

CREF

LED1_DRV

LED2_DRV

8

628

GNDQ

VRTC

R102
330K

C100
100NF

SIMRST
SIMCLK

SIMDATA

TA_VEXT

PWR_ON

JIG_ON

UP_SDI

UP_SCLK

UP_CS

EN_VRF

EN_VPAC

XOENA

C104
33PF

C103
33PF

R1130

C102

2.2UF

R101

NC

1

VLDO_7

GNDD1

VDD67

VLDO_6

VL5S_A
VL5S_B

VLDO_5

VDD5

VL4S_A
VL4S_B

VLDO_4

VDD34

VLDO_3

VRTC

VLDO_2

RESETN

VLDO_1

VDD12

VBAT

C105
1UF

VREF

VCCA

VBAT

1UF

C114

2.2UF

VCCB

C109C108
1UF

VRF VPAC

C111 C112
1UF

R105
10

C115
10NF

470NF

RST

C113
100PF

VRTC

R103

1.2K,1%

1

POS

NEG
2

M1

VOSC

40

41
42

32
31

33

VCC_1.8A

1UF

C110
1UF

VCCD

C117C116
1UF

34

36
35

37

38
39

12

11

19

9

10

TA_VEXT

CHG_DET

VCCD

R110
NC

3

2

R112
0

BACKLIGHT_1
BACKLIGHT_2

4

U101

ISENSE

6

5

4

GND

VCC

DRIVE

VSENSE

PROG

R107

47K,1%

6
5
4

Q102

1
2
3

R111
10K,1%

1

CHG_ON

C119
10UF
10V

U102

1

2

3

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Q101

3

TA_VEXT

6
5
2
1

R109
3K

R108
10K,1%

C118
10UF

6.3V

VBAT

ICHRG

2. Initial

SGH-P400 Flow Chart of Troubleshooting

Initialization Failure

Yes

The pin #9 of U100 =

the pin #11 of U100

wave forms at the C614

The pin #25 of U100 is

1.8V and

=

2.825V ?

Yes

Is the pin #19 of

U100

"Low -> High"?

Yes

There is 32.768kHz

and C616

Yes

"High"

No

No

No

No

(If it has some problem, it has to be

Check the U100

replaced.)

Check the U100

(If it has some problem, it has to be

replaced.)

Check the U601

Check the U700

Yes

The Voltage is "High"

at the C110, C111,

C112

Yes

LCD display is O.K

Yes

Sound is O.K

Yes

END

3-3

No

No

No

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Check the U100

Check the LCD Part

Check the Audio Part