Cal Cluster ID (a.k.a. Eflow)

1. Cal Cluster ID(a.k.a. Eflow) Gary R. Bower, SLAC Santa Cruz LCD Workshop June 28, 2002

2. Acknowledgement • Ron Cassell has made many essential contributions to this project. G.R.Bower - Santa Cruz LCD Workshop

3. Outline • This is a work in progress. • (Very preliminary) results first! • Describe test data sets and testing methods. • Efficiencies and fake rates. • Details (as time permits) • Approach to problem • Discriminator tools • Discriminator capabilities • Summary • Next Steps G.R.Bower - Santa Cruz LCD Workshop

4. Test procedure • Three datasets of 1000 single particle events. • piminus, gamma, and K0L • 1-50 Gev momentum • In barrel, within 45o of perpendicular to beam • Make contiguous hit clusters • Ignore clusters with energy < 0.5 GeV • Treat most energetic cluster as primary deposition • Treat second most energetic cluster as fragment. • Test both primary and secondary cluster • Is it a gamma, piminus, K0L, and/or fragment? G.R.Bower - Santa Cruz LCD Workshop

5. ID result:gamma piminus K0L fragment Input: gamma piminus KOL fragment G.R.Bower - Santa Cruz LCD Workshop

6. Multiple ID rates G.R.Bower - Santa Cruz LCD Workshop

7. Philosophy of Technique • The Eflow problem: a common approach: • solve it with a clever cluster builder but still need to identify shower origin. • Assumes showers fragment badly. • Assumes showers overlap each other. • We take a different approach: • work with (simple) clusters of contiguous hits. • distinguish origins based on cluster properties G.R.Bower - Santa Cruz LCD Workshop

8. Fragmentation problem?input piminus G.R.Bower - Santa Cruz LCD Workshop

9. “Secret” to solving fragmentation problem • Combine EM and Had clusters using contiguous hits cluster builder by Ron Cassell. • Caveat: For the occasional neutral hadron there will be significant fragments but we have a promising technique to find and associate them. G.R.Bower - Santa Cruz LCD Workshop

10. Isolation of gammas G.R.Bower - Santa Cruz LCD Workshop

11. Gamma shower characteristics • Compact • Standard cigar shape • Shower initiates in first few EM layers • Shower contained in EM (if deep enough) • Many hits/much energy in first few layers • Accurately point back to IP G.R.Bower - Santa Cruz LCD Workshop

12. Piminus shower characteristics • Diffuse in shape and energy spread. • Some fragmentation. • Min-I track begins in first layer. • Few hits/little energy until first interaction. G.R.Bower - Santa Cruz LCD Workshop

13. KOL shower characteristics • Diffuse in shape and energy • Some fragmentation • First hit layer may be very deep • Generally points back at IP G.R.Bower - Santa Cruz LCD Workshop

14. Fragment shower characteristics • Diffuse in shape and energy • First hit layer may be very deep • Generally do not point back at IP G.R.Bower - Santa Cruz LCD Workshop

15. Measure cluster properties • Form energy tensor • Energy (shape) eigenvalues • Energy axes • Center of Energy • First and last layers with hits • Energy/# of hits in first N layers G.R.Bower - Santa Cruz LCD Workshop

16. Superb gamma location resolution Resolve gamma direction to ~1/6 cell size using center of energy of hits G.R.Bower - Santa Cruz LCD Workshop

17. Separating gammas G.R.Bower - Santa Cruz LCD Workshop

18. Separating piminuses G.R.Bower - Santa Cruz LCD Workshop

19. Separating K0Ls G.R.Bower - Santa Cruz LCD Workshop

20. Summary • Can find gammas with ~100% efficiency and ~few percent fakes. • Can identify most pions without tracking • Can identify majority of K0Ls. • Have only sketched the power of the method. G.R.Bower - Santa Cruz LCD Workshop

21. Next steps (arbitrary order) • Many details to cross-check. • Reconstruct π0s (dE/E~5%, loc res ~same as π±.) • Associate neutral hadron fragments (improve dE/E). • Work out special cases, eg, charge exchange. • Combine clusters between barrel and endcap. • Use neural net to improve results. • Test on signal events. • Test on physics measurement. • Release tools. G.R.Bower - Santa Cruz LCD Workshop