Circuit Description

Amethyst T190 / T191 L3 Circuit Description
T190 / T191
Level 3
Circuit Description
11 / 08 / 01
V1.0
1
by Toko (toko@gsm-free.org)
Amethyst T190 / T191 L3 Circuit Description
RECEIVE
1. Received GSM 900 frequency enters the unit at the Antenna ANT1
2. L702 / L701 /C711 provide matching
3. The signal then enters mechanical Auxiliary RF port U72. When a load (50&! is
placed into the socket the RF will be diverted into or out of U72). This socket will be
used for phasing, testing purposes.
4. From U72 Pin 6 to RF Switch U75 Pin 8 (ANT), where through control voltages the
Rx path is isolated from the TX path. The following voltages control the RF Switch:
VC1 & VC2, which are all 0V or 3.6V Low or High respectively.
For RX a diplexer is used to separate the GSM and DCS frequencies*
The controlling input signals for U72 are originated from T/R Switch Controller U73,
using the outputs on Pins 6 & 4:
To provide the appropriate switching voltages the following signals are used.
" GSM_T/R this signal puts the phone into GSM Mode when High (originates
from Hercules Digital Processor U1 Pin B10)
" DCS_T/R, this signal puts the phone into DCS Mode when High (originates
from Hercules Digital Processor U1 Pin E9)
" V_BR, is the support voltage, it originates from VBAT through U90. Voltage
range is between 3.3V 3.6V
Below are the states of VC1 & VC2 and the relative states of DCS_T/R and
GSM_T/R for each scenario.
VC1 VC2 DCS_T/R GSM_T/R
GSM RX 0V 0V X X
DCS RX 0V 0V X X
5. The appropriate frequency is then fed from the diplexer of U75 from Pin 10 for GSM
and Pin 1 for DCS
6. The received frequency is then fed into a Dual Band select SAW (Standing Acoustic
Wave) filter U66 for GSM (Loss approximately 4dB), and U67 for DCS.
7. The outputs from the SAW filter is 2 balanced outputs that will be fed into the
Transceiver IC U61 on Pins 4 & 5 for GSM and Pins 9 & 10 for DCS
2
Motorola Proprietary Information
Amethyst T190 / T191 L3 Circuit Description
90o Shift
RXI
For GSM Only
90o Shift
1/2
RXQ
RF
8. U61 is a Dual-Band Transceiver IC; it integrates a direct-conversion receiver vector
modulator. (In basic terms Direct conversion allows us to take our incoming
frequency and convert that frequency directly to Baseband without the need for
expensive IF SAW filters or associated IF components.
9. The signal is firstly passed to an RF Low Noise Amp; this amplifier has 3 variable
gain settings that will be programmed via SPI for AGC (Automatic Gain Control)
purposes.
From there the signal is passed in to a pair of Gilbert Cell Mixers, where the received
frequency will be mixed with a generated RXVCO reference frequency.
10. The RX VCO frequency is generated by the RF Balun U64, which is fed by the RF
Frequency Synthesiser IC, U63, The Charge pump to provide the correct conversion
frequency is fed out of the Transceiver IC on Pin 44, and is operable between
approximately 0.5V and 2.5V dependant on Frequency required. V_RX provides the
switched supply for U64. This is generated from V_BAT through Dual regulator
U90, the output on Pin 1 as V_SYN, will then be switched via Q700-2 by RX_ON_N
to provide V_RX at 2.85V
11. The RF signal will then be passed to U64 at 3.6 3.84Ghz where the signal will be
split into 2 balanced outputs, Pins 3 & 4. These outputs will be fed into the
Transceiver IC on Pins 49 & 50 before being fed to the mixers. (The frequency will
be divided by 2 for EGSM)
12. Now at Baseband frequencies, the signal will go through a 3-stage amplification
process, which has a range of 90dB in 2 dB steps over the 3 amplifiers. The filtering
of the Baseband signal is carried out by a first stage R/C Low-pass filter (The
capacitor in this filter is external to the IC C603 and C604).
This is followed by 2-second stage Butterworth Filters. The IC contains DC offset
circuits to remove any unwanted DC values and the signal is fed out as RXI and
RXQ (Positive and Negative Still Balanced) on Pins25 28. These will be passed
through a High pass Filter R632
3
Motorola Proprietary Information
Amethyst T190 / T191 L3 Circuit Description
13. The Baseband In Phase and Quadrature signals arrive into the Omega IC, U3 on Pins
E7 E10, and into the Baseband Codec.
14. The Omega IC when combined with Hercules forms a fully integrated DSP. It forms
the Base band interface for processing of Voice signals and Base Band signals. It also
deals with Supply Voltage Regulation, SIM card, Battery Charging and ON/ Off
functionality.
15. The Baseband Codec comprises of a Baseband Downlink path, which converts the
Baseband Analogue I&Q signals into digital format, where they are filtered through
digital FIR to isolate the desired information from the adjacent channels.
16. Within the Omega IC the path of the base-band RXI & Q data from the Transceiver
IC takes the following route.
Calibration
Offset
Anti-Aliasing Sigma / Delta Digital
RXI
Filter ADC Filter
To Base-
band Serial
Interface
Anti-Aliasing Sigma / Delta Digital
RXQ
Filter ADC Filters
Calibration
Offset
17. The RXI and Q signals from the Transceiver IC enter the Omega IC (BDLIP /
BDLIN / BDLQP / BDLQM) and follow identical paths. The first stage is through a
continuous-time second order anti-aliasing filter, which serves 2 functions: 1) to
interface between RF logic and on-chip circuitry and 2) to prevent aliasing during the
ADC process.
18. The signal is then fed into a Sigma Delta ADC, and is fed out as a 3-bit word. This
is then fed into a set of digital filters, that will decimate, (break the signal into piece
parts), to give us an overall sampling rate of 270.8KHz (�24). This allows a low
enough frequency for adjacent channel rejection, and therefore channel separation.
19. Calibration of the IQ paths is achieved by internally shorting out the 2 input I paths,
and then the same again on the 2 input Q paths the digital value measured will then be
stored in a register. Once the RXI and Q paths are reconnected to the circuitry, again
the calibration process takes place and the offset value is calculated.
4
Motorola Proprietary Information
Amethyst T190 / T191 L3 Circuit Description
20. The digital information is then sent to Hercules via the Baseband serial port on pins
on BDX (Baseband Data Transmit) and BFSR (Baseband Frame Sync Transmit) Pins
G5 & F5 respectively, this information is clocked out at 270Khz.
21. See below for timing diagram for Transmission of the data.
BFSX
A0
A15 A1 BDX
HERCROM200 (Hercules U1) is a chip implementing the digital Base Band processing
of a GSM mobile product.
This chip combines a DSP M16L80 Mega-Module (LEAD2 CPU) with its program and
data memories, a Micro-Controller core with emulation facilities (ARM7TDMIE) and an
internal 2M bit RAM memory, a clock squarer cell, several compiled single-port or 2-
ports RAM.
The chip supports the GSM full-level test approval (FTA) for both Full-Rate, Half-Rate
and Enhanced Full-Rate speech coding when using the appropriate GSM protocol stack
S/W.
Hercules implements dedicated voice features (voice memo, voice recognition).
22. Within Hercules general GSM processing takes place, such as:
" De-Interleaving: Interleaving is a way in which the information that is to be
transmitted is jumbled around before it is sent i.e.
If we wish to send the information They must read this
T H E Y
And we lose the information during the time
M U S T that must is being sent. Then we will lose a
whole word.
R E A D
T H I S
" However if we jumble the bits around that make up the words, i.e. transmit in a
different order.
T H E Y
If now during the same time frame we lose the same
M U S T
amount of information, and then we will only lose a small
R E A D
part of each word
T H I S
5
Motorola Proprietary Information
Amethyst T190 / T191 L3 Circuit Description
" Channel De-Multiplexing this is where we decode the signal that was transmitted;
encryption at the transmitter ends is usually done by X-ORing the information.
" Forward Error Correction Decoding This is where the redundant bits of data that
were added in the transmitter are removed, and the information that is received can be
processed. The redundant bits are added in various quantities dependent upon the
signal quality. This means if some data is lost whilst travelling OTA then, for
example, instead of 8 bits of speech data being lost, only 4 bits of speech and 4 bits of
redundant data.
" De-Segmentation and CRC Attachment analysis. During the transmission
process the data is broken into packets of various lengths (No of bits). These packets
are then processed to give a checksum of what should be expected at the receiver.
Once in the Hercules the information received is processed, and the two checksums
compared. From the analysis, the correct algorithm for repairing any data corruption
can be implemented.
23. The processed digital audio from the Hercules is then returned to the Omega IC on
the Voice-band serial interface VDR (Hercules H12 to Omega K7) clock, VCLKRX
and Frame synchronisation signal, VFSRX.
24. The processed digital audio is received from the Hercules and fed into the Voice
Band Codec of the Omega IC, from here the signal is interpolated within a speech-
digital infinite duration impulse response filter (IIR) (i.e. that is, for the data coming
in, the adjacent bits of the data being looked at are all synchronised and an average
taken. From this a prediction of events can be calculated) also the sampling rate is
increased, and the speech bandwidth is limited by high and Low pass responses.
25. The signal is then fed into a D/A converter and will be output to the appropriate
analogue audio devices. Other functions performed by the Voice band Codec are:
" Programmable Gain for setting Audio Output Levels (Internally set)
" Volume Controls (Externally set gain)
" Side Tone production
26. The converted speech can then take 1 of 2 paths.
27. Path 1 to the Internal speaker LS1, the audio is fed out of the Omega on Pins H8 &
H9, and fed directly to the speaker, voltage suppressers T3 and T4 are responsible for
ESD protection. The speaker is situated in the front housing of the unit and is
connected to the main PCB through an elastomeric contact.
28. Path 2 to the Headset Connector, the audio is fed out from the Omega IC on Pin J9
AUXOP, from here the audio will be passed to the Headset Socket J3.
J3 is also used as a serial data entry port for Test / Flashing and Flexing,
therefore data switches are required to correctly route the data.
6
Motorola Proprietary Information
Amethyst T190 / T191 L3 Circuit Description
29. The analogue Audio is routed from Omega to an Analogue Switch U8, where a
decision will be made to see if Audio or Data (TXD0) needs to be selected. This is
done using the signal I03DATA_HP_SEL. This signal originates from Hercules Pin
M5. This signal will be a Positive pulse for Data Cable download, that is active Low
and will be active high for Earpiece.
For Data Cable For Earpiece
30. However to originate these control signals, the unit needs to know what is connected,
i.e. either Headset or Data cable. This is achieved by using the EARPHONE_IN
signal to detect the type of accessory. This will provide a voltage of between 2.8V
2.6V for the Data Cable and 2.4V 0V for the headset. The signal is fed to the ADC
input of the Omega IC Pin C6. The signal I013ACCIN will detect when an accessory
has been plugged into the headset socket and provide a wakeup signal.
31. Once the Processor knows what that an earpiece is connected, the Audio will be
passed through U8, (supported by VR2B_SW, this is VR2B passed through a 0O
Resistor). Then passed through a Noise Suppressor U9 and into the Headset Socket J3
TRANSMIT
32. There are 2 sources of input audio:
33. Auxiliary Microphone is fed from the Headset Connector J3 on Pin 4, through Noise
Suppressor U9 and into Analogue Switch U10, which will decide if the output will be
for RXD0 (Data Cable) or Analogue Audio. See Points 30 & 31 for operation. The
audio will then be routed to the Omega IC, Pin H7 as AUXI
34. The Internal Microphone X2, uses the signal MICBIAS to provide correct
microphone biasing conditions, the biasing support voltage being fed from the Omega
IC, Pin K9. Voltage suppressers U14 provides ESD protection to the circuit. The
signal is then passed as MICIP & MICIN
35. If both inputs are active then, output signal from the internal microphone will be used.
36. The input analogue audio is then routed to the Voice Band Codec of the Omega IC
Pins K8 & J8. Within the Omega IC the analogue signal will be driven through a
PGA (Programmable Gain Amplifier), and the information will be passed through an
A/D converter.
7
Motorola Proprietary Information
Amethyst T190 / T191 L3 Circuit Description
37. Once again, as in RECEIVE, the loop between the Omega IC and the Hercules IC is
put in place for standard data processing.
38. The transmitted signal is sent to the Hercules IC over the Voice-band VDX Line
Omega Pin G6 and is clocked by VCLKRX Pin H6. The signal is then received by
the Hercules IC on Pins H13 & G11 respectively. Synchronisation is achieved using
the frame synch signal VFSRX (Omega Pin G7 / Hercules Pin H11.
39. After processing, the Base-band signal information is transferred back to the Omega
IC using the base-band lines, BFSR / BDR / (Omega Pins J5, K5and Hercules Pins
F12, F13 respectively)
40. Within the Omega IC, the received information will now be passed to the Base Band
Codec, where the signals from the DSP will be modulated in accordance with GSM
Specifications and will output the analogue TXI and TXQ signals to the Transceiver
IC (Omega Pins C9 / C10 / D8 / D9) then through a low pass filter R624/ C621 /
C622, entering U61 on Pins 19 - 22
1/2
DCS
1/2
1/2
DCS
EGSM
1/2
TX O/P
0
F-back 90
EGSM
1/2
TXI
I & Q
Charge
PFD
Mod
Pump
TXQ
8
Motorola Proprietary Information
Amethyst T190 / T191 L3 Circuit Description
41. The Transceiver IC U61 generates a modulated signal using a Quadrature Modulator
and then converts to the final frequency using an OPLL (Offset Phase Locked Loop.
42. OPLL is basically a normal PLL, however it incorporates a down converter mixer,
which has the advantage of having a different comparison frequency to that of the
transmitted frequency and therefore broadband noise created in the modulator will be
outside the spectrum.
43. Once generated the modulated word will be superimposed upon the TX IF frequency
created by the internal synthesiser. This runs at between 376Mhz and 384Mhz. The
signal will then be divided down (by 4 for DCS and 8 for EGSM). This generates
signals at 90Mhz for DCS and 45Mhz for EGSM
44. The phase-modulated carrier is now forwarded through an amplifier and into the
OPLL, the OPLL consists of a Gilbert Cell Down Converter, phase detector, off chip
passive loop filter and VCO.
45. Within the OPLL, the Feedback from the TX VCO will be fed back into Omega on
Pin 14 and will be mixed (Down Converted) with the RF VCO, which will be divided
down by 2 for DCS and 4 for EGSM. This will then be phase compared with the
modulated signal to give a difference error signal that when fed into the Charge Pump
will create an error voltage that will drive the TX VCO to the correct frequency.
Worked Example.
" Internal TX IF VCO for EGSM = 360Mhz
" Divide / 8 = 45Mhz
" TX Feedback for EGSM = 880.2Mhz
" RF VCO for EGSM = 3700.8Mhz
" Divide / 4 = 925.2
" RF VCO TX F/Back = 925.2 880.2 = 45Mhz
46. The analogue VCO drive information, is now sent from OMEGA Pins 17 to the
Passive Loop Filter, consisting of C614 / C615 / C617 & R619 / R621. The charge
pump voltage is approximately 0.5V 2.5V.
47. The charge pump voltage enters the TX VCO on Pins 10 for GSM and Pin 6 for
DCS. U65 is supported by 2.85V V_TX which is generated by Q700 1
(Combination of V_BR (U90) and TX_ON_N. (VBAT switched through U86 by
TX_ON)
48. The control signals BS1 and BS2 are used to provide the band switching controls, and
are originated from Hercules Pins B13 & D11 respectively
49. The appropriate Transmit frequency will now be generated according to channel
selection and Band, with the EGSM outputting from U65 Pin 1 and DCS from Pin 5.
9
Motorola Proprietary Information
Amethyst T190 / T191 L3 Circuit Description
50. At the output of the TX VCO is a 30dB attenuator to take a sample of the transmitted
frequency for use in the Transceiver IC within the OPLL.
51. The transmit frequency signal is then pushed to the PA U71 for amplification.
U71 is a Dual Band Power Amplifier containing 2 Bipolar Transistor blocks for each
band.
DCS_IN
DCS_OUT
APC
BS
CMOS
EGSM_IN
EGSM_OUT
52. The inputted frequency in inputted into the Transistor stage amplifiers with the signal
BS1 controlling the band select. The signal APC (Analogue Power Control) fed in on
Pin 6 & 8 (VCC) will allow more or less amplification by providing more or less
current to the IC.
RSense
VBAT
R1
8
1 2
4 Buffer
+
V to I
7
Converter
+
Error
Amp
3
PA
5
6
RF In
10
Motorola Proprietary Information
Amethyst T190 / T191 L3 Circuit Description
53. APC is provide by Power Control IC U74
The PAC IC uses a closed Loop bias control voltage system to control the output
power of the PA. In normal operation the current driving the PA from VBAT will
flow through the current sense resistor. When stable the voltage drop across R1
should be = to that across the current sense resistor. The larger the voltage drop over
R1, the greater the current delivered to the PA.
When the transmitter needs to deliver more power, the signal RAMP from Omega
Pin F9 goes higher. This is fed directly to the U74 Pin 4 and into the buffer amp;
within here the signal is divided by 4 in a ratio of 3:1. The scaled down voltage is
now fed to the V to I converter. This switches on the FET allowing a current flow
between Pins 1 and Pins 6, therefore setting the R1 Voltage level, and as mentioned
previously, the Error Amplifier will output a voltage signal to the PA to drive harder,
until R1 and I Sense PD s are the same.
The signal PC, from Omega Pin B12, acts as an enable.
VBAT is switched by TX_ON through U86, as a safety feature to remove VBAT
during receive to ensure no transmission
54. The RAMP signal is controlled via SPI programming, however a Thermister, TR1
connected to Omega Pin D6 which is supported by VR3 feeds temperature
information back to the Omega IC, which in turn back down the PA via the RAMP
signal if the unit is getting too hot.
55. Once the transmit power is achieved, the PA will transmit in accordance with the
GSM Burst specifications. The burst will then be fed through the T/R switch U75,
through the mechanical switch U72 and out of the Antenna, ANT 1
Power up Sequence
56. There are 3 methods by which the product can be switched on, these are:
" On button depressed On pressing the Power Key (S19) for + 2 seconds, this
signal will then be sent to Omega Pin B10
" Software wake up If the user has programmed his unit to wake up at a certain
time and Power on, the signal RTCINT, will be originated from Hercules Pin B6
and will be sent to Omega Pin D7
" Charger is plugged in When the charger is plugged in at the Power Jack J1,
Power will be sourced from Pin 1, through Fuse F1, through U17, and output to
Omega Pin E4, at a time when VCHG > than VBAT, Omega Pin E5, constitutes
the conditions for Power on.
57. Once one of the scenarios has taken place, the unit will then begin to power up, the
Power up sequence is as follows: (For On/off key pressed)
" Battery power made available from Battery Connector JP1 as VBAT, and also a
signal is sent to Omega Pin F1, as VBATBB.
11
Motorola Proprietary Information
Amethyst T190 / T191 L3 Circuit Description
" Power Key, S19 is depressed, which creates an interrupt within the Omega.
" NRESET is pulled low, Omega Pin F6
" VREF and IBIAS, set up a reference voltage Band-gap within Omega, using the
capacitor and resistor C24 and R23 Pins F4 and G1 respectively
" This will start the internal 100Khz Internal Clock.
" Regulators now begin to output necessary Voltages, these are:
o VR1 Pin H1 1.8V @ 120mA Supplies Hercules and RTC Battery.
o VR2 Pin E1 2.85V @ 120mA Supplies Hercules 13Mhz Clock
Output and Flash and Ext RAM
o VR2B Pin D1 2.85V @ 50mA - Support Omega / Hercules
communication and also 3V peripheral devices
o VR1B Pin C1 2.0V @ 50mA Supplies Omega Internal circuits
o VR3 Pin H10 2.85V @ 80mA Supplies Analogue Voltages
58. Once all the necessary voltage have been produced, Hercules will supply the signal
TCXOEN along with Omega originated VR3, this will be fed into RF side U84 and
will be used in conjunction with U85 to create the 26Mhz Clock, which is fed into the
Transceiver IC Pin 40. This is then used as internal system clock within the
Transceiver IC, but will also be divided by 2 to create the 13Mhz system clock,
Omega Pin 37, Into Hercules G14, out on Pin L14 to Omega Pin A4.
59. Once all the Power supplies and clock are running, the signal ON_OFF from Omega
is output to Hercules Pins D10 / D6
VBATT > 2.6V
Internal Reset
OFF ON
Mode
Power Key Pressed
OSCAS 100Khz and
System 13Mhz Clock
DISABLED Regulators
ENABLED
ON_OFF
12
Motorola Proprietary Information
Amethyst T190 / T191 L3 Circuit Description
Memory
60. The memory consists of a 32Mbit Flash part U5, and a 1Mbit SRAM U6; both are
supported by VR2. The chip select for the Flash is provided by the signal
NROMCS1 from Hercules Pin P6 and from P7 for the SRAM
61. Contrast control is achieved by the variation in voltages, which are stored in C40
through C44 and DC / DC LCD driving voltages provided by C45 through C48.
62. Data to and from the LCD is though the data bus D0 D7, U24 Pins 16 24
63. Chip select is sent from Hercules Pin 48 to LCD Connector Pin 28, with the Reset on
connector on Pin 27.
LCD
64. The LCD Connector J2 is a 98 X 64 Graphic, Black and White COG (Chip on Glass)
type. It uses Serial Data input instead of Parallel data input as Topaz. The LCD
Module is supported, with the voltages VR2 on Pins 8 & 7, with 8V being provided
by C34. The LCD uses the reset signal from Hercules, Pin K11. The data to the
display is provided by the SPI bus I2C_SDA (data) and I2C_SCL (Clock). These are
originated from Hercules Pins C4 and F4 respectively; these are both supported by
VR2B.
Alert
10
9 1
LCD Connector J2 Layout
Vibrator and Alert
65. The vibrator is driven by the signal IO0VIBRATOR which originates from Hercules
Pin J1, this signal is applied to the base of Transistor BQ4, this then gives the
vibrator support voltage VBAT a path to earth through Vibrator Motor M1. D14
allows a discharge path for remnant energy after the vibrator has switched off
66. The buzzer / alert is operated, using the signal BU from Hercules Pin C2, this signal
can be programmed to variable frequencies. It forces BQ3 to conduct creating the
current path for the Buzzer U13 support voltage VBAT to earth.
13
Motorola Proprietary Information
Amethyst T190 / T191 L3 Circuit Description
Keypad and Back lights
67. The backlights are split into 2 for the LCD (D4 / D3 / D13) and the keypad
backlights of which there are 8 (D5 D12). The backlights are switched on using the
signal BL This is generated from Hercules Pin B1. When BL goes high, U7 Pin 6
goes low, which in turn, forces BQ2 to conduct. This allows VBATBB to supply the
backlights. Approximately 1.9V will be made available for each set of LED s with
approximately 36mA being drawn through R40 and 60mA being drawn through R35
68. The keypad is made up of a 4 column x 4 Row matrix, with the signals KBR3
KBR0 being generated from Hercules Pins B2 / D4 / B4 / A4 respectively. The
column signals, KBC4 KBC1 Hercules Pin E5 / D5 / B5 / A5. Each key has its
own unique combination of Column and Row
69. The keypad matrix is as follows
Function Key COL COL COL COL COL ROW ROW ROW ROW
0 1 2 3 4 0 1 2 3
1 S3 X X
2 S2 X X
3 S1 X X
4 S7 X X
5 S6 X X
6 S5 X X
7 S10 X X
8 S9 X X
9 S12 X X
0 S13 X X
Down S4 X X
SEL S8 X X
Up S11 X X
# S16 X X
* S15 X X
Menu S15 X X
Send S17 X X
Quit S18 X X
Charger Function
70. There are 3 modes of operation for the T191 charge these are:
" Normal charge
14
Motorola Proprietary Information
Amethyst T190 / T191 L3 Circuit Description
" Trigger of Full rate Charge
" Over Voltage Protection
71. Normal Charge During normal operation, once the charger has been plugged into
the Power Jack J1, power will be distributed from Pin 1 and will be passed through
Fuse F1.
The signal ACCID is not used, instead a resistor is placed on the ACCID line to
make a potential divider with R75 and this will be used for the Product ID to
establish if the unit is from EMEA or ASIA.
Once through the fuse the charging voltage will be fed into Source 1 of U17, the left
side of this dual FET is biased on by the Over Voltage FET U16. The voltage is then
fed through to the Drain. It will then be fed back into Source 2 of U17 before being
fed out as VBAT and VBATBB.
During this time the right side of U17 is biased on by the signal ICTL, from Omega
Pin E3, this signal controls the charging profile.
72. Trigger or Full Rate Charge When the battery is completely flat, a quick charge at
full current is required, to do this we initially have U18 right side grounded, i.e
ON.(this has the effect of fully opening the charge gate of U17)
The right side of U18 is initially OFF as the charging current begins to flow, a
biasing voltage will be formed at G2 of U18 ensuring it stays on, at the same time
C48 will begin to charge. After 2 seconds, the potential on C47 will be sufficient to
switch on U18 left side, this will put a ground onto the Gate of U18 Right side, which
will turn this side off, thus allowing the controlling signal ICTL to take control of the
charging current.
73. Over Voltage Mode The Over Voltage Mode is set at a threshold of 7.8V, if the
voltage on the Charge input line should exceed this then the voltage between R62 &
R65 will go above 0.73V and will switch the left side of OVIC U16 ON the will
provide a path to Earth, grounding the inputted Charger Voltage.
SIM Circuit
74. Both 3 and 5V SIM cards are supported by the Omega. The 5V is achieved by using a
charge pump circuit, consisting of C5 and C6, along with the 2.85V SVDD (Omega
Pin A2). This will be fed onto the SIM Block U2 on Pins 4 and 5.
75. Other signals are:
" Reset, Omega Pin D5, U2 Pin 3
" Clock, Omega Pin B4, U2 Pin 1
" I/O (data to and from the SIM Card) Omega Pin D4, U2 Pin 2, again this can be
transposed from 3V to 5V if necessary)
15
Motorola Proprietary Information

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