ePixUHR 140k 2x2 Detector

SparkPix-S 500k 2x2 Detector

ePixUHR 140k 2x2 Detector

SparkPix-S 500k 2x2 Detector

ePixUHR 140k 2x2 Detector

SparkPix-S 500k 2x2 Detector

ePixUHR 140k 2x2 Detector

SparkPix-S 500k 2x2 Detector

ePixUHR 140k 2x2 Detector

SparkPix-S 500k 2x2 Detector

1.3 V

1.3V

1.3V

1.3V

1.3V

1.3V

??? Maybe

0.6 V

2.5 V

2.5V

10A

(= 2.5 A* 4 ASIC)

13.4 A

(= 3.35A * 4 ASIC)

- Old digital design:
1.2 A (= 0.3 A * 4 ASIC)
-New digital design

????

- Old digital design
2.0 A (= 0.5 A * 4 ASIC)
-New digital design

????

1.6 A
(= 0.4 * 4 ASIC)

[1RX, 8TX, 8serializer and 2cm clkspine : ~ 317mA]

??? (If existing lower or equal than SparkPixS)

-8 A
(= -2A * 4 ASIC) 

0.4 A

(=0.1 * 4 ASIC) 

+1.3 V @ +17.5 A

(Adding +30% current for PVT variation)

+1.3 V @ +3 A

(Adding +30% current for PVT variation)

[waiting for the new digital design] 

+1.3 V @ +2.5 A

(Adding +30% current for PVT variation)

+0.6 V @ -11 A

!this current is not provided by the LDO. But it passes through it.

(Adding +30% current for PVT variation)

+2.5 V @ +0.5 A

(Adding +30% current for PVT variation)

48 HD, 486 HP

96 HD, 416 HP

52 HD, 364 HP

0 HD, 448 HP

0 HD, 448 HP

- ASIC data:

32 = 8 lanes * 4 ASIC

- Spare outputs :

4

- PGP communication:

12 = 12* 160 Gbps/ 275Gbps

(1 Amphenol Transceiver)

Total:

48 High Speed GTs

- ASIC data:

288 = 8 lanes * 36 ASIC

- Spare outputs :

0

- PGP communication:

72 = 12* 1.44 Tbps/ 275Gbps

(6 Amphenol Transceivers)

Total:

360 High Speed GTs

- ASIC data:

240 = 8 lanes * 30 ASIC

- Spare outputs :

0

- PGP communication:

72 = 12 lanes * 1.19 Tbps/ 275Gbps

(6 Amphenol Transceivers)

Suggested 3 transceivers 1.4x compression in the detector

Total:

312 High Speed GTs

(If considering 5x2 Modules, 104 GTs each)

- ASIC data:

32 = 8 lanes * 4 ASIC

- Spare outputs :

4

- PGP communication:

12 = 12* 160 Gbps/ 275Gbps

(1 Amphenol Transceivers)

Total:

48 High Speed GTs

- ASIC data:

128 = 8 lanes * 16 ASIC

- Spare outputs :

0

- PGP communication:

24* = 12* 495 Gbps/ 275Gbps

(2 Amphenol Transceivers)

Total:

152 High Speed GTs

28
(20 GTH/8 GTY)

56

(32 GTH/24 GTY)

104

(52 GTH/52 GTY)

120

(60 GTH/60 GTY)

128

(0 GTH/128 GTY)

34.6 Mb

34.6 Mb

115.2 Mb

132.9 Mb

94.5 Mb

36 Mb, None

36 Mb, None

None, None

None, None

360 Mb, None

> 10 Gbps

> 10 Gbps

> 10 Gbps

> 10 Gbps

> 10 Gbps

GTH 16.3 Gb/s

GTY 16.3 Gb/s

Transceivers

GTH 16.3 Gb/s

GTY 32.75 Gb/s

Transceivers

GTH 16.3 Gb/s

GTY 30.5 Gb/s

Transceivers

GTH 16.3 Gb/s

GTY 30.5 Gb/s

Transceivers

GTY 32.75 Gb/s

Transceivers

The PCB width is (preferably) 65 mm (2.56’’)

35 x 35 mm

40 x 40 mm

47.5x47.5 mm

52.5 x 52.5 mm

52.5 x 52.5 mm

5-9 k$

 6-10k$

40 k$

50-70 k$

60-110 k$

The number of GTs in this FPGA does not fit any of the cameras we are targetting

This is fine for the 2x2 Systems.

For the larger systems we need more than 3 FPGAs

This is fine for the 2x2 Systems.

This is fine for the 2x2 Systems (assuming we can fit the real estate).

This is fine for the 2x2 Systems.(assuming we can fit the real estate)

Analog

G_AS_0

1.3V @4.4A

← +1.3V

← +1.8V (TBD)

← +6 V

← +24 V

The current drawn by the 0.6V current sink should not be counted twice since its sourced by the G_AS.

The power drawn by the ASIC analog part is 1.3V*4.4A*4= 23W.

If using 1.8V as the LDO input, we are burning also (1.8-1.3)V*4.4A*4 = 9W.

The power drawn by the TPS should be less than 2W.

So the power that the DC/DC converters have to provide is around 23 + 9 + 2 = 34W.

Considering the efficiency curves of the DC/DC converters:

34/85%/93% =

43W Total Analog Power

(if we did the same calculation for ePixUHR would be 32W)

G_AS_1

1.3V @4.4A

← +1.3V

← +1.8V (TBD)

G_AS_2

1.3V @4.4A

← +1.3V

← +1.8V (TBD)

← +6 V

G_AS_3

1.3V @4.4A

← +1.3V

← +1.8V (TBD)

G_VG_0

0.6V @ -2.75A

← +0.6V

← +2.5V

← +3V

← +6 V

G_VG_1

0.6V @ -2.75A

← +0.6V

G_VG_2

0.6V @ -2.75A

← +0.6V

← +6 V

G_VG_3

0.6V @ -2.75A

← +0.6V

G_AS_2V5

2.5V @ <0.5 A

← +2.5V

VDD_3V3

+3.3V @ <1A?

3.3 W

← +3.3V?

HS ADC: ~350mA

Slow ADC: few mA

DACs: ~250 mA

Total 0.7A

Worst case scenario starting from 5V,

3.5W/85%/93% =4.4W

VDD_2V5

+3.3V @ <1A?

3.3 W

← +3.3V?

VDD_1V8

+1.8V @ <1A?

1.8 W

← +1.8V?

G_DS_0

1.3V @3A

← +1.3V

← +1.8V (TBD)

← +6 V

← +24 V

For the digital consumption of the ASIC we do not have precise numbers regarding the new logic.

Let's use the old numbers.

1.3V*3A = 4W

While for the I/O voltage we have an expected 1.3V*2.5A = 3.25 W.

LDO losses = 0.5*5.5 = 2.75 W

10W / 85% / 93% = 13W (ASIC Digital and I/O)

(if we did the same calculation for ePixUHR would be 9.5W)

G_DS_X

1.3V @???A (CML simulations?)

← +1.3V

← +1.8V (TBD)

G_IO_0

1.3V @???A(CML simulations?)

← +1.3V

← +1.8V (TBD)

← +6 V

G_IO_X

1.3V @???A(CML simulations?)

← +1.3V

← +1.8V (TBD)

VCC_INT

0.85V @7.05 A

6 W

← +0.85V

← +5 V

Max ~90 W

← +24 V

Regarding the FPGA considering a worst case efficiency of the DC/DC:
17.1W /85%/93% =21.5W (FPGA)

VCC_AUX + VCC_1.8V +VCC_ADC + MGTV_CCAUX+ MGTYV_CCAUX

1.8V @0.7A 

1.3 W

← +1.8V

MGTAV_CC +MGTYAV_CC

0.9V @3.7A

3.3 W

← +0.9V

VCC_1.2V + MGTA_VTT + MGTYA_VTT 

1.2V @5.5A

6.6 W

← +1.2V

P3V3

+3.3V @ <4A

13 W

← +3.3V

← +5V

Max ~31.5W

3.7A * 5V = 18.5W

18.5/93% = 20W

P2V5

+2.5V @ <1A

2.5 W

← +2.5V

P1V3

+1.3V @ <10mA

<0.1 W

← +1.3V

Product number

Type

Input Voltage

Output Voltage

Max Current

Comment

Alternative to LT1764

. Low Output Noise: 40μVRMS (10Hz to 100kHz)

Negative Linear Regulator

. Low Output Noise: 18µVRMS (10Hz to 100kHz)

Component

Product number

Board

Voltage

Power consumption

Comments

Quad SPI Configuration Memory

MT25QU01GBBB8E12

Digital

1.8V

Max 50mA

EEPROM

???

Digital

???

???

JTAG

Digital

1.8/V

Analog Monitor (SlowADC) ADC

ADS1217

Both (key at the analog board, optional at the digital board)

AVDD=3.3V

DVDD=1.8V

< 1mA

Maybe. The datasheet guarantees operation for digital down to 2.7V,  in HR250 was put at 1.8. Check if it is fine!

Analog Monitor MUX (x5)

MAX4734

may be needed depending on the number of channels we decide to monitor (all voltages and currents to the ASIC, humidity,...)

AVDD=3.3V

< 1uA

They are controlled by the ADC

Humidity sensor

HIH_5031_001

Analog

3.3V

No

Thermistor

NTC_NHQM103B375T10

No

Oscillators

•371 MHz XLL726371.428571I

•156 MHz 536FB156M250DG

•48 MHz CX3225SB48000D0FPJC1

Digital

2.5V

Both 1.8V and 2.5V solutions can be found depending on the voltage we want to use

Clock Fanout

SI53340-B-GM

Digital

3.3V

Clock Jitter cleaner

SI5345_64QFN

Digital

VDD=3.3V

DVDD=1.8V

Programmable Oscillator

LMK61E2

Digital

3.3V

Used?

High Speed ADC

AD9249

Analog

1.8V

Max 58mW/channel:

58*12 = 700mW

No

ADC_MON_VCM Buffer

AD8607_MSO8

Analog

1.8V

Bias DAC (HV Ring)

MAX5443 (DAC) +

MAX14611 (Level Shifter) +

REF192GS  (Voltage reference)

Analog

3.0 V (VCCA)

Needed? Will the sensors have an HV ring?

ASIC clk fanout

SI53340-B-GM

Probably not needed

HS DAC (Vcalib_p)

AD5541A (DAC)

+OPA2626(Buffer)

+ADR360B(Vref)

VDD = 3/3.3V

VLogic = 1.8V

Vref = 2V

Level shifters for ASCI SACI interfacing

MAX3378EEUD+

Digital

1.3V -> 1.8V

Level Shifter for Power controllers

MAX3378EETD (x2)

MAX3373E_SOT23_8 (x1)

to be defined

???

Serial number

DS2411R

Carrier, analog and digital boards

All at 2.5V provided from the digital board

Line Equalizer

(check the one used for cryo)

Analog

The photo below shows the current cooling block designs (straight and angled), which is for a 30x6 SEAM/SEAF connector between analog and digital board.

The screenshot below shows that a 40x8 SEAM/SEAF connector can fit by extending the cutout in the cooling block without interfering with the pipe. Orange lines are the outline of the cooling block and the pipes in it.

The new connector is 10*1.27 = 12.7 mm longer.